WO2006046522A1 - Optical device packing case and packing method - Google Patents

Abstract

An optical device case which can store an optical device regardless of its thickness and is easily reused. The optical device case is composed of a frame member which stores the optical devices in parallel at intervals by permitting only the both end parts in the width direction of the optical devices to make contact with the frame member; a bottom member for adhering one end of the optical device in the longitudinal direction to an adhesive sheet adhered on an upper plane; and a recessed case which adheres the other end of the optical device in the longitudinal direction to the adhesive sheet adhered on the upper plane on the inner side and integrally combines with the frame member and the bottom member.

Description

 Optical device packing case and packing method

 Technical field

 TECHNICAL FIELD [0001] The present invention relates to an optical device packaging case and a packaging method improved so as to accommodate optical devices having various thicknesses.

 The present invention also relates to a packaging case for an optical device that realizes low cost with a structure that does not contaminate an optical surface when an optical device is delivered to a customer.

 The present invention also relates to an improvement of a packaging case that accommodates a flat optical device in a flat state, and in particular, an optical device having a size different from that of an adhesive for fixing the optical device to the optical surface. The present invention relates to a packaging case for optical devices that is capable of accommodating a highly positionable optical device.

 The present invention also relates to an optical device packaging case in which a plate-like optical device is mainly aligned and held in a good direction while ensuring sufficient buffering properties and can be provided to the next process or assembly manufacturer. .

 Background art

 [0002] [First Conventional Example]

 Optical devices are used in a wide range of communication equipment such as optical transmission equipment as well as consumer equipment such as video cameras and electronic still cameras. The use of optical devices will expand with the spread of new optical devices such as blue laser diodes in the future. Seem.

 Regarding the invention of a packaging case that accommodates optical elements such as an optical low-pass filter, a wave plate, and a birefringent plate, which are types of optical devices, the means is disclosed in Japanese Patent Laid-Open No. 2001-2167, Japanese Patent Laid-Open No. 2002-370780, and the like. It is disclosed. Further, regarding the invention of a translucent member case that accommodates a translucent member made of glass, resin, silicon, or the like used for protection of a semiconductor laser element or the like, it is disclosed in JP-A-2002-59989. Yes.

If dust, dust, or the like adheres to the main surface of an optical device, its performance is greatly degraded, so manufacturing and packaging are generally performed in a clean room. It is necessary to use materials that do not generate dust, dust, etc. in the packaging case for optical devices. Also recently, recycling Therefore, a packaging case for optical devices that can be used repeatedly simply by replacing some parts is desired.

 FIG. 35 and FIG. 36 are a cross-sectional view of a translucent member case disclosed in Japanese Patent Application Laid-Open No. 2002-59989 and a plan view of a frame member used therefor. The translucent member case includes a frame member 11, a bottom member 12, a lid member 13 and an adhesive sheet 14, as shown in the cross-sectional view of FIG. As shown in the plan view of FIG. 36, the frame member 11 has through-holes 17 for accommodating the translucent member 15 arranged vertically and horizontally, and faces the one opening of the through-hole 17 so that the bottom member 12 As a result of combining these together, a large number of recesses for accommodating the translucent member 15 are formed. When the translucent member 15 is inserted into the concave portion, it is bonded and fixed to the adhesive sheet 14 attached to the upper surface of the bottom member 12. A case 16 for translucent member is configured by integrally combining the lid member 13 with the frame member 11.

 The frame member 11, the bottom member 12, and the lid member 13 are made of resin such as polyvinyl chloride resin, polystyrene resin, polyester resin, polyethylene resin, and are formed by sheet molding or injection molding. The

 However, in the optical device packaging case (translucent member case) disclosed in Japanese Patent Application Laid-Open No. 2002-59989, the size of the optical device (translucent member) is different. Depending on the size, frame members etc. must be manufactured, and there is a problem that a space for accommodating various frame members etc. is necessary, and the cost of the packaging case is high because various frame members etc. are manufactured. There was a problem of becoming.

 In addition, the optical device packaging case disclosed in Japanese Patent Application Laid-Open No. 2001-2167 or Japanese Patent Application Laid-Open No. 2002-370780 is also provided with a storage portion that stores the optical device according to the size of the optical device. It was necessary to make a case, and I was able to solve the same problem as above.

[0004] [Second Conventional Example]

Conventionally, as a means for packing an optical device, a packing case having a structure in which an optical device is accommodated in a plurality of concave portions having a predetermined shape provided inside a box-shaped case and covered with a lid has been used. When such a packing case is used, for example, if the packing case vibrates during transportation of the packing case, the optical device housed inside the concave inner wall of the packing case Repeating contact with the surface, the sharp end surface of the optical device is scraped on the inner wall of the tray, so that debris such as device debris and tray pieces are generated, and the debris adheres to the optical surface of the optical device and the optical surface is There was a problem of fouling.

 Therefore, as a means for solving such a problem, as disclosed in Japanese Patent Laid-Open No. 2001-2167 and Japanese Patent Laid-Open No. 2002-370780, an adhesive fixing tape is attached to the bottom surface of the packaging case. Thus, it has been proposed that the optical device be bonded and held by the fixing tape.

 FIG. 37 is a structural example showing a configuration of an example of a conventional packaging case for an optical device. The packaging case 21 has a plurality of concave portions 23 having a predetermined shape formed in a band shape on a packaging case main body 22, and a fixing tape 24 is attached to the bottom surface of the concave portion 23. Therefore, when the optical device 25 is stored in the packing case 21, one side of the optical device is adhered to the fixing tape attached to the bottom surface of the recess 23, and the optical device 25 is placed vertically to be self-supporting. After that, cover the lid 26 and ship. Thus, by providing the recess 23 in the packing case body 22, even if the vertically placed optical device 25 falls down due to an impact on the packing case 21, the optical device 25 stored next to it There is no contact with the optical device 25 and the optical surface of the optical device 25 is not soiled.

 However, in the packaging case according to the second conventional example, the optical device is placed vertically, and when the optical device falls down, a recess is formed in the packaging case body so that it does not come into contact with the adjacent optical device. Alternatively, it is necessary to provide a guide for preventing overturning between the optical devices, resulting in a problem that the structure of the packaging case is complicated and the cost is increased.

 In addition, the shape of the recess provided in the packing case body and the shape of the guide must be different according to the shape of the optical device, and there are many types of packing cases, so the work can be performed in the packing process. It was complicated and problematic.

[0006] [Third conventional example]

Optical devices (optical components) used in optical pickups and other optical devices, regardless of size, are handled to prevent damage from impacts and defective products due to foreign matter such as dust. The maximum consideration is necessary. For this reason, packaging cases that take into account the impact resistance and impact prevention of dust when transported with impacts or vibrations are conventionally used. Various proposals have been made.

 On the other hand, optical devices are rapidly changing models, and the product life cycle is short. Therefore, types of optical devices that are different in size and shape are developed and commercialized one after another. For this reason, there are a wide variety of packaging cases when optical device manufacturers deliver optical devices to customers, which increases costs.

 [0007] By the way, in a flat optical device such as a beam splitter, a wavelength plate, and a mirror, two opposing flat plate surface portions are optical surfaces, for example, an optical film on one of the optical surfaces. If this is formed, it is not permissible to make a mistake in the direction of assembly with the actual machine. Therefore, the orientation of the optical surfaces of the optical devices arranged in the packing case is set in one direction in advance so that the directionality can be recognized at the time of removal. Conventionally, when an optical device is packed, it is arranged and accommodated in a container in a vertically placed state, or is laid flat with either one of the optical surfaces facing upward.

 In the case of a vertically placed packaging case, for example, as disclosed in JP-A-9-30593, JP-A-2001 2167, and JP-A-2002-370780, the surface on which the optical film is formed is oriented in one direction. A plurality of optical devices are fitted and disposed in the groove in a vertical posture. Furthermore, in order to clarify the directionality, a marker indicating the direction of the optical film is formed at an appropriate position of the container. However, in the case of vertical installation, when performing the work of actually taking out the individual optical devices from the container and incorporating them into the actual machine, the operator does not look closely at the marker or intends the direction of the container. If the optical device is taken out in the opposite direction, the surface on which the optical film is formed may be mistaken or cannot be discriminated.

 [0008] Next, a flat packaging case is disclosed in, for example, Japanese Patent Application Laid-Open No. 10-29679, and the optical surface is removed regardless of which direction the packaging case is oriented as compared with the vertical placement. When taking out an optical device housed in a container that is less likely to be different, the direction of the optical surface can be definitely recognized. In this conventional example, the lower peripheral edge of a flat optical device is supported by a pedestal, so the outer peripheral edge of the lower optical surface is more likely to be damaged or dust is attached, but the directionality Can definitely be recognized.

However, even in the case of flat placement, if the model of optical equipment is changed frequently In response to the new model, optical devices of different sizes will appear, so a new container will be created according to the change in the optical device size, but this is disadvantageous in terms of labor and cost. is there. Therefore, as shown in FIGS. 38 (a) and (b), a recess 301 for holding a component larger than the size of the optical device 305 is provided on the upper surface of the lower case 300, and an adhesive tape 302 is provided on the periphery thereof. By configuring the adhesive tape 302 so that both lower edges of the lower surface of the optical device 305 are attached and supported, optical devices of different sizes can be accommodated in the same container simply by changing the width dimension of the adhesive tape. I have to. Further, by closing the upper lid 310 after holding the optical device 305, the outer peripheral edge of the upper surface of the optical device may be pressed and held by the pressing convex portion 311 provided on the ceiling surface of the upper lid. In this example, the optical film 305a is coated on the upper surface of the optical device 305. However, in this case, the peripheral portion of the optical device is placed on the adhesive tape 302 as shown in FIG. However, if a slight misalignment occurs that is difficult to position, the adhesive material from the adhesive tape 302 adheres to a region important as an optical surface. Further, the position of the convex portion 311 of the upper lid 310 needs to be changed according to the size of the optical device, which is disadvantageous in terms of cost. Furthermore, in the case shown in FIG. 38 (c), the peripheral edge of the optical device can be held only on one side.

[Fourth conventional example]

 Polyhedrons such as beam splitters and prisms as optical devices used in optical pickups and other optical devices are configured to have a small dimension of several mm square in response to the demand for miniaturization. First, optical devices must be handled with the utmost care in order to prevent damage caused by impacts and defective products caused by foreign objects such as dust. For this reason, various packaging cases have been proposed in consideration of impact resistance in the case of impact or vibration during transportation and prevention of adhesion of dust and the like.

For example, in Japanese Patent Laid-Open No. 2001-2167, an adhesive sheet is stretched on the bottom surface of a through hole of a case body having a through hole for accommodating an optical device, and one surface of the optical device is adhered and held by the adhesive surface of the adhesive sheet. An optical device packaging designed to do so is disclosed. In this conventional example, when an impact is applied to the bottom side force of the case body, the impact is applied. Since it is transmitted directly to the optical device, the optical device collides with the inner surface of the case main body, and damage such as damage occurs due to scraping of the inner wall of the case main body. In addition, since the structure is such that only one surface of the optical device is bonded and supported, the holding force against impact was sufficient.

 [0010] Japanese Patent Application Laid-Open No. 9-30593 discloses a configuration in which an adhesive sheet is disposed on the bottom surface of the lower case via a thin cushion member, and the optical device surface is bonded and supported via the cushion member. Has been. However, this conventional example only supports one surface of the optical device through a thin cushion member in a state where the bottom surface force of the lower case is also buoyant. Therefore, depending on the applied impact and the shape of the optical device, May collide with the bottom of the case and damage it, or scraping the case to generate dust. Next, in Japanese Patent Laid-Open No. 2002-370780, the center portion of the bottom surface (non-optical surface) of the optical device is bonded and supported via a cushion by a protruding adhesive member provided on the bottom surface of the lower case, and the upper case. An air cushion provided on the ceiling surface supports the entire top surface (non-optical surface) of the optical device, and the bottom surface of the lower case made of PET supports the entire bottom surface of the optical device and the center of the top surface of the optical device. Is supported by a protrusion provided on the upper case made of PET, and the entire bottom surface of the optical device is directly adhered and supported by the bottom surface of the lower case made of PET, and an air cushion placed on the ceiling surface of the upper case. A configuration for supporting the entire top surface of the optical device is disclosed.

 However, since all of the above conventional examples have a configuration in which the cushion member is arranged at a position corresponding to the side surface (optical surface) of the optical device, the lateral volume of the lower case increases, and the waste that is discarded. The problem is that the amount increases. This cushion member comes into contact with the optical surface, causing problems such as damage to the optical surface and dust adhesion. In addition, since the lower case or upper case made of PET is in direct contact with the optical device, there is an increased possibility that the PET part will be scraped and generate dust.

[0011] [Fifth conventional example]

Polyhedrons such as beam splitters and prisms as optical devices used in optical pickups and other optical devices are configured to have small dimensions of several mm square in response to the demand for miniaturization. However, regardless of the size, optical devices must be handled with the utmost care in order to prevent damage caused by impacts and defective products caused by foreign objects such as dust. For this reason, various packaging cases have been proposed in consideration of impact resistance in the case of impact or vibration during transportation and prevention of adhesion of dust and the like.

 For example, in Japanese Patent Laid-Open No. 2001-2167, an adhesive sheet is stretched on the bottom surface of a through hole of a case body having a through hole for accommodating an optical device, and one surface of the optical device is adhered and held by the adhesive surface of the adhesive sheet. An optical device packaging designed to do so is disclosed. In this conventional example, when an impact is applied to the lower surface side force of the case body, the impact is directly transmitted to the optical device. Defects such as the dust generated by scraping the body wall sticking to the optical device occur. In addition, since the structure is such that only one surface of the optical device is bonded and supported, the holding force against impact was sufficient. In addition, since the case body with a through hole is made of a resin material such as PET or PS, a mold is required to manufacture the container, and the force depends on the type, shape, and size of the optical device. Therefore, there is a limit to cost reduction.

 Next, Japanese Patent Laid-Open No. 9-30593 discloses a configuration in which an adhesive sheet is disposed on the bottom surface of the lower case via a thin cushion member, and the optical device surface is bonded and supported via the cushion member. Has been. However, since this conventional example only supports one surface of the optical device in a state where the bottom surface of the lower case is buoyant through a thin cushion member, depending on the applied impact and the shape of the optical device, the optical device However, there are problems such as damage caused by collision with the bottom surface of the case or scraping of the case to generate dust. In addition, since the case is made of a resin material such as PET or PS, a mold is required to manufacture the container, and the force must be manufactured individually according to the type, shape, and size of the optical device. Therefore, there was a limit to cost reduction.

Next, in Japanese Patent Laid-Open No. 2002-370780, the center portion of the bottom surface (non-optical surface) of the optical device is bonded and supported via a cushion by a protruding adhesive member provided on the bottom surface of the lower case, and the upper case. The optical device is supported by a structure that supports the entire top surface (non-optical surface) of the optical device with an air cushion provided on the ceiling, and the bottom surface of the lower case made of PET. Supports the entire bottom surface of the optical device and supports only the central part of the top surface of the optical device with a projection provided on the upper case made of PET, and also directly adheres the entire bottom surface of the optical device with the bottom surface of the lower case made of PET. A configuration is disclosed in which the entire upper surface of the optical device is supported by an air cushion disposed on the ceiling surface of the upper case while being supported.

 However, since all of the above conventional examples have a configuration in which the cushion member is arranged at a position corresponding to the side surface (optical surface) of the optical device, the lateral volume of the lower case increases, and the waste that is discarded. The problem is that the amount increases. This cushion member comes into contact with the optical surface, causing problems such as damage to the optical surface and dust adhesion. In addition, since the lower case or upper case made of PET is in direct contact with the optical device, there is an increased possibility that the PET part will be scraped and generate dust. In addition, since the case is made of a resin material such as PET, a metal mold is required for manufacturing the container, and the shika also needs to be manufactured individually according to the type, shape, and size of the optical device. Therefore, there was a limit to cost reduction.

[Sixth conventional example]

 Optical devices (optical elements) are used in various optical devices, and various packing methods and packing materials are used to transport optical devices from optical device manufacturers to optical device manufacturers.

 For example, in the case of an optical device using a plate-like quartz crystal plate, it is easy to damage dust due to vibrations and shocks because it dislikes adhesion of dust and dirt, etc. Things are desired.

 As a means for packing the optical device, there is a structure in which the optical device is accommodated in a plurality of slits of a predetermined shape provided in the box-shaped case and covered, or disclosed in JP-A-10-230975. As described above, a cushioning material in which a plurality of slits are formed in foaming resin is used to fit the four corners of a rectangular optical device into each slit, and bundle the optical devices in a state of being stacked at a predetermined interval. was there.

However, in such packaging, the optical device manufacturer has to take out the optical devices one by one from the packaging material and set them again on the assembly line of the optical device. Therefore, in recent years, it has become common to store and transport optical devices horizontally in a tray-shaped packing material so as to save the trouble of remounting the optical devices one by one on the assembly line of the optical apparatus.

 For example, as disclosed in Japanese Patent Application Laid-Open No. 9-328180, there is a package that holds and holds an optical device between two flat trays.

FIG. 39 is a cross-sectional view showing the configuration of the tray-type packaging material disclosed in the above publication, and the optical device 353 is held and held between the upper tray 351 and the lower tray 352. It has been.

 The upper tray 351 includes an upper tray body 354 and an upper elastic body 355, and the lower tray 352 includes a lower tray body 356 and a lower elastic body 357.

 The upper and lower trays 351 and 352 are each formed with a recess at a position facing each other, and the optical device is accommodated in the recess. A step is formed in each recess, and this step contacts and holds the peripheral edge of the optical device. Each tray body 354, 356 has a material force such as PET in order to maintain a predetermined rigidity, and each elastic body 355, 357 serves as a buffer material for the optical device that comes into contact with each tray body 354, 356. It is placed between the optical device and material strength such as molten rubber is formed.

 With this configuration, the optical equipment manufacturer that received this can remove the upper tray 351 and put it in the production line with the optical device mounted on the lower tray 352. There is an advantage that the complicated process of taking out the optical device and replacing it on the production line can be omitted.

[0015] Further, since the sealing property is high, the optical device is surrounded by the buffer material so that there is no possibility that the optical device is contaminated by dust during transportation, so that damage due to impact is small.

 However, in the conventional packing system as shown in Fig. 39, the structure of the upper and lower trays must be changed according to the shape of the optical device.

For example, when the planar shape of the optical device is the same but only the thickness is different, specifically, an optical fiber such as an OLPF placed in front of the image sensor of a digital camera. Even if the image sensor size is the same as a filter, if the thickness must be changed according to the difference in the number of pixels, the upper tray 351 or lower tray 3 52 Therefore, it is necessary to change the uneven shape of the surface. It is necessary to redesign the mold even when changing the V and deviation tray.

 In other words, if the optical device has the same planar shape but various variations in thickness, a separate tray must be prepared for each thickness of the optical device, leading to high costs. there were.

[0016] [Seventh conventional example]

 Conventionally, as a means for packing an optical device, a packing case having a structure in which an optical device is accommodated in a plurality of concave portions having a predetermined shape provided inside a box-shaped case and covered with a lid has been used. When such a packaging case is used, if the packaging case vibrates while the packaging case is being transported, etc., the optical device housed inside repeatedly contacts the inner wall surface of the recess of the packaging case, and the optical device There was a problem that the optical surface of the optical device was soiled due to generation of dust due to the sharp end face being cut off.

 Therefore, as a means for solving such a problem, as disclosed in Japanese Patent Laid-Open No. 2001-2167 and Japanese Patent Laid-Open No. 2002-370780, an adhesive fixing tape is attached to the bottom surface of the packaging case. Thus, it has been proposed that the optical device be bonded and held by the fixing tape. When the optical device is bonded and held with the fixing tape, the optical device is fixed and the generation of dust is prevented, but there is a problem that the adhesive of the fixing tape adheres to the optical device.

 On the other hand, in manufacturing an optical device, a tray that accommodates an optical member is used to move the optical member to a post-process force as well as a pre-process force. In the optical device manufacturing process, a force that requires careful attention to prevent the optical member from being soiled. The tray is applied with a gel on the bottom surface of the tray without using an adhesive tape. The gel has a fixing force, can fix the optical member, and does not use an adhesive, so that the adhesive of the fixing tape does not adhere to the optical member. The

Specific examples of trays that use gel include Wisdom Opto-Electronic Technology, commonly known as Sticky Carrier, which moves optical components between processes. In addition, after the optical member is processed in a subsequent process, the gel sticky carrier can be returned to the previous process and used repeatedly.

 However, in recent years, there has been a demand for delivery of optical devices, which are the final product, to the above-mentioned gel's state carrier and to customers, and there is an increasing demand for packing cases using gel. .

 Therefore, an example of a packaging case for an optical device using a conventional gel sticky carrier is shown below.

 FIG. 40 is an external view showing a configuration of a first example of a conventional optical device packaging case. Fig. 40 shows a state in which the lid of the packing case is removed. Gel 372 is applied to the entire bottom surface of the packing case main body 375, and the prism 373 is fixed on the gel 372, and the packing case main body 371 is attached to the lid 374. It is a closed structure. The gel 372 has a fixing force but does not use an adhesive, and the prism 373 is fixed without fouling the prism 373, thereby providing a packaging method having excellent vibration resistance.

 FIG. 41 is an external view showing a configuration of a second case of a conventional optical device packaging case. Fig. 41 shows a state in which the lid of the packing case has been removed. The packing case body 375 is closed with a lid 377. In this example, the OLPF 375 can be mounted vertically when the OLPF 376 is mounted flat on the packing case 375 in order to increase the capacity.

 FIG. 42 is an external view showing a configuration of a third example of a conventional optical device packaging case. Fig. 42 shows the packaging case with the lid removed. The entire bottom surface of the packing case body 378 is filled with [Genore 372, and the top of Genore 372 with [01 ^ PF376 fixed vertically]. Lid 379 [Structure of the packing case body 378 is closed. In this external appearance example, the vibration resistance is improved by pressing the upper part of the OLP F376 with the lid 379.

However, the conventional optical device packing case using gel sticky carrier uses an expensive gel, so the packing case is expensive, and it is used repeatedly for transportation between processes on the production line. If the packaging case is shipped with the product to the customer, the packaging case cannot be recycled and the cost of the packaging case Has been added to the product, resulting in a high manufacturing unit price.

 Patent Document 1: JP 2001-2167

 Patent Document 2: JP 2002-59989

 Patent Document 3: Japanese Patent Laid-Open No. 2002-370780

 Patent Document 4: JP-A-9-30593

 Patent Document 5: JP-A-10-29679

 Patent Document 6: Japanese Patent Laid-Open No. 10-230975

 Patent Document 7: JP-A-9 328180

 Disclosure of the invention

 Problems to be solved by the invention

[0019] [Problems of the first conventional example]

 As described above, in the conventional example, if the size of the optical device (translucent member) is different, a frame member or the like must be manufactured according to the size, and various frame members or the like can be manufactured. There was a problem that a space for housing was necessary and a problem that the cost of the packaging case was high because various frame members were manufactured.

 The first aspect of the present invention has been made in view of the above, and provides a low-cost packaging case for optical devices and a packaging method improved so as to accommodate optical devices having various thicknesses. The purpose is.

[0020] [Problem of the second conventional example]

 In the packaging case according to the second conventional example, the optical device is placed vertically, and when the optical device falls down, a recess is formed in the packaging case main body so that it does not come into contact with the adjacent optical device, or between the optical devices. It is necessary to provide a guide to prevent the product from overturning. If the structure of the packaging case is complicated and the cost increases, a problem arises!

 In addition, the shape of the recess provided in the packing case body and the shape of the guide must be different according to the shape of the optical device, and there are many types of packing cases, so the work can be performed in the packing process. It was complicated and problematic.

The second aspect of the present invention has been made to solve the above-described problems, and can be used for various types of optical devices for general purposes, and has a simple shape and an inexpensive packaging case. The second purpose is to provide services.

[0021] [Problem of the third conventional example]

 In the third conventional example, if a slight misalignment occurs that is difficult to position when the peripheral edge of the optical device is placed on the adhesive tape, an adhesive material such as an adhesive tape is applied to an important area as an optical surface. There was a problem of sticking. Moreover, the position of the convex part of the upper lid needs to be changed according to the size of the optical device, which is disadvantageous in terms of cost. In addition, Figure 3

In the case of 8 (c), there was a problem that the peripheral edge of the optical device could not be held on one side.

 The third aspect of the present invention has been made in view of the above, and is an optical device packaging case for holding and storing an optical device having two opposed optical surfaces in a flat state! In addition, optical device packaging cases that can accommodate optical devices with different sizes and outer peripheral contours can be accommodated with good positioning without causing damage by applying adhesive or applying pressure to the optical surface. The third purpose is to do.

[0022] [Problem of Fourth Conventional Example]

 In the fourth conventional example, the cushion member is arranged at a position corresponding to the side surface (optical surface) of the optical device, so that the lateral volume of the lower case increases and the amount of waste to be discarded increases. Problem occurs. This cushion member also comes into contact with the optical surface, causing problems such as damage to the optical surface and dust adhesion. In addition, since the lower case or upper case made of PET comes into direct contact with the optical device, there is an increased possibility that the PET part will be scraped and generate dust.

 The fourth aspect of the present invention was made in view of the above, and supported two non-optical surfaces facing each other of a cube, a rectangular parallelepiped, and other polyhedral power optical devices using a minimum buffer material. The fourth object of the present invention is to provide an optical device packaging case that can resolve optical device damage due to vibration and shock, and generation of dust and defects caused by scraping of the inner wall of the container.

[0023] [Problems of the fifth and sixth conventional examples]

In the fifth conventional example, the cushion member is arranged at a position corresponding to the side surface (optical surface) of the optical device, so that the lateral volume of the lower case increases and is discarded. The problem is that the amount of garbage increases. This cushion member also comes into contact with the optical surface, causing problems such as damage to the optical surface and dust adhesion. In addition, since the lower case or upper case made of PET comes into direct contact with the optical device, there is an increased possibility that the PET part will be scraped and generate dust. In addition, since the case is made of a resin material such as PET, a mold is required for manufacturing the container, and the force must be manufactured individually according to the type, shape, and size of the optical device. Therefore, there was a limit to cost reduction.

 In the sixth conventional example, although the planar shape of the optical device is the same, but there are various variations in thickness, a separate tray must be prepared for each thickness of the optical device, which increases the cost. There was a problem of being connected to.

 The fifth and sixth aspects of the present invention have been made in view of the above, and damage the optical device due to vibration shock by packing while holding the optical device using an array means having a buffer function. Another object of the present invention is to provide an optical device packaging case that can solve the problem of dust generation due to the optical device scraping the inner wall of the container.

 [0024] [Problem of the seventh conventional example]

 The packing case for optical devices using the gel-state key carrier according to the seventh conventional example uses an expensive gel, so the packing case is expensive, and it is used repeatedly for transportation between production lines. However, if the packaging case is shipped together with the product to the customer, the packaging case cannot be recycled, and the cost of the packaging case is added to the product, resulting in a high manufacturing unit price. If this happens, a problem will arise! The seventh aspect of the present invention has been made in view of the above, and provides a packaging case for an optical device that is easy to use at low cost without contaminating the optical device while using gel as the optical device holding means. Is the sixth purpose.

 Means for solving the problem

[0025] [First invention to achieve the first object]

In order to achieve the first object, the first aspect of the present invention comprises the following arrangement. The invention of claim 1 includes a bottom plate member having an adhesive sheet disposed on the upper surface, an annular frame member placed on the upper surface of the bottom plate member, a recessed portion having an opened lower surface, and a ceiling of the recessed portion. A packaging case for an optical device, comprising: a cap member having a configuration in which another adhesive sheet is attached to a surface, and a cap-shaped lid member that covers the bottom plate member in a state of surrounding the frame member. The dimension of the member in the frame is set so that when the optical device is accommodated in the frame, both end surfaces in the width direction of the optical device can be supported by both wall surfaces in the frame. When the cap-shaped lid member is covered with the optical device placed on the adhesive sheet disposed on the top surface of the bottom plate member exposed inside, the upper end portion of the optical device is located inside the cap-shaped lid member. A packaging case for an optical device, wherein the packaging case is configured to abut on the other pressure-sensitive adhesive sheet disposed on an upper surface.

 The invention according to claim 2 is configured so that a peripheral edge portion of the bottom plate member is fitted to an opening end portion of the cap-shaped lid member. It is a case.

 [0026] The invention of claim 3 is characterized in that the peripheral edge portion of the bottom plate member and the peripheral edge portion of the frame member are configured to be fitted to the opening end portion of the cap-shaped lid member. This is the optical device packaging case described in Item 1.

 The invention of claim 4 is a method of accommodating an optical device in the packaging case for optical devices according to any one of claims 1 to 3, wherein the penetration corresponds to the optical device accommodated above the frame member. A step of placing a jig having a hole, a step of inserting the optical device into the through hole of the jig and bonding the lower end of the optical device to the adhesive sheet on the upper surface of the bottom plate member, and a step of removing the jig Then, the cap-shaped member is covered from above, and the bottom plate member or the frame member is fitted with the lower end portion of the cap-shaped lid member to the other adhesive sheet on the ceiling surface (inner upper surface) of the cap-shaped lid member. And a step of bonding the upper end of the optical device.

[0027] [Second invention for achieving the second object]

In order to achieve the second object, the second aspect of the present invention comprises the following arrangement. An optical device package comprising: a tray member having a hollow portion for housing an optical device; a bottom plate that covers a lower surface side opening of the tray member; and an upper lid that covers an upper surface side opening of the tray member. In the case, the hollow portion is a through-hole penetrating the central portion of the tray member from the upper surface to the lower surface, and the tray portion so that the adhesive surface is exposed in the hollow portion. It is characterized in that at least two adhesive tapes are attached to the lower surface of the material at a predetermined interval.

 The invention of claim 6 is characterized in that, in claim 5, the interval between the adhesive tapes is set larger than the effective diameter of the optical surface of the optical device and narrower than the outer dimension of the optical device. .

 The invention of claim 7 is the structure according to claim 5 or 6, wherein the tray member is stacked in a plurality of stages, and the bottom surface opening of the bottom tray member is covered with a bottom plate in the stacked state, and the top tray member The upper surface opening is covered with an upper lid.

[Third invention to achieve the third object]

 In order to achieve the third object, the third aspect of the present invention comprises the following arrangement. Claim 8 is a packaging case for an optical device, comprising: a lower case provided with a recess for holding a flat optical device in a flat state on an upper surface; and an upper case covering the upper surface of the lower case. The inner wall is a concave curved surface including an arc shape or an elliptical arc shape in the longitudinal section, and is configured such that the interval between the facing inner walls gradually decreases as the force is applied downward. .

 The invention of claim 9 is characterized in that, in claim 8, an adhesive layer is provided on the opposing inner wall surfaces of the recess.

 The invention of claim 10 is characterized in that, in claim 8 or 9, the planar shape of the recess is a rectangle.

[Fourth Invention to Achieve the Fourth Object]

In order to achieve the fourth object, the fourth aspect of the present invention comprises the following arrangement. The invention of claim 11 is a packaging case for an optical device that houses a plurality of optical devices as polyhedrons in which at least two non-optical surfaces face each other in parallel, and a tray on which the optical devices are placed on the upper surface. And a lid member enclosing a space including the optical device on the tray, wherein a plurality of the optical devices are arranged in a row on the upper surface of the tray. At least one long lower convex portion that supports the lower convex portion, and a lower elastic adhesive member that adheres to the bottom surface of each optical device is provided on the upper surface of the lower convex portion. For each optical device It has at least one long upper convex part that supports the center of the upper surface, and an upper elastic adhesive member that adheres to the upper surface of each optical device is provided on the lower surface of the upper convex part, and the adhesive force of the lower elastic adhesive member Is set to be stronger than the adhesive force of the upper elastic adhesive member.

 [0029] The invention of claim 12 is characterized in that, in claim 11, the lower elastic adhesive member is formed by making a total adhesion area of the lower elastic adhesive member larger than a total adhesion area of the upper elastic adhesive member. The adhesive force is set to be stronger than the adhesive force of the upper elastic adhesive member.

 The invention of claim 13 provides the adhesive force of the lower elastic adhesive member in the upper elastic adhesive member according to claim 11, by making the number of the lower convex parts larger than the number of the upper convex parts. It is characterized in that it is set stronger than the adhesive strength of.

 The invention of claim 14 is an optical device packaging case for storing a plurality of optical devices as polyhedrons in which at least two non-optical surfaces face each other in parallel, and a tray on which the optical devices are placed on the upper surface. And a lid member surrounding the space including the optical device on the tray, and the bottom surface of each optical device is supported on the upper surface of the tray in a state where the plurality of optical devices are arranged in a row. The ceiling surface of the lid member includes at least one elongated lower convex portion, and a lower elastic adhesive member that is disposed on the upper surface of the lower convex portion and adheres to the lower surface of each optical device. The optical device further includes at least one long upper convex portion that supports the central portion of the upper surface of each optical device.

[0030] [Fifth aspect of the present invention and sixth aspect of the present invention to achieve the fifth object]

 In order to achieve the fifth object, the fifth aspect of the present invention comprises the following arrangement. In order to achieve the fifth object, the invention of claim 15 according to the fifth invention comprises an arrangement means for arranging a plurality of optical devices in series in parallel at a predetermined pitch, and a case holding the arrangement means. In the packaging case of the optical device provided with a plurality of bellows sheets erected in parallel on the bottom surface in the case with a predetermined interval in the width direction as the arrangement means, the inside of the open portion of each bellows sheet is used. Further, the optical device is configured such that both end edges of the optical device are inserted and held.

The invention of claim 16 is the invention according to claim 15, wherein the bellows sheet has both longitudinal ends. The portions are respectively supported by the inner walls facing each other of the case. The invention of claim 17 is characterized in that, in claim 15 or 16, the bellows sheet has its bottom side bonded to the inner bottom surface of the case.

 The invention of claim 18 is characterized in that, in claim 15, 16 or 17, the edge of the optical device is adhered and held by the adhesive layer provided on the inner wall of the open portion of the bellows sheet.

 In order to achieve the fifth object, the sixth aspect of the present invention comprises the following arrangement.

 The invention according to claim 19 is an optical device packaging case comprising: an arraying means for arranging a plurality of optical devices in series at a predetermined pitch; and a case holding the arraying means. Using two coil springs arranged in parallel with an interval in the width direction, both end edges of the optical device are inserted and elastically held in a gap formed between the pitches of the coil springs. It is characterized by comprising. The invention of claim 20 is characterized in that, in claim 19, the end surface of the coil spring has a circular shape, a circular arc shape, an elliptical shape, or a polygonal shape.

 A twenty-first aspect of the invention is characterized in that, in the nineteenth or twentieth aspect, the case is provided with pitch adjusting means for setting a pitch width of the coil spring to an arbitrary interval.

 The invention of claim 22 is characterized in that, in claim 21, the pitch adjusting means is means for widening the pitch width by supporting both ends of the coil spring.

 The invention of claim 23 is characterized in that, in claim 21, the pitch adjusting means is a winding means for winding up a longitudinal end of the coil spring.

 The invention of claim 24 is characterized in that, in claim 19 or 20, the plurality of coil springs and the plurality of optical devices held by the coil springs are vacuum-sealed in a bag.

[Seventh aspect of the present invention for achieving the sixth object]

In order to achieve the sixth object, the seventh aspect of the present invention comprises the following arrangement. The invention according to claim 25 includes a lower tray having a first recess for accommodating an optical device on the upper surface, and a second recess on the lower surface at a position corresponding to the first recess. Upper side provided A packaging case for an optical device for storing the optical device between the first and second layers,

The elastic member and the lid member are arranged in a gap between the inner bottom surface of the recess 2 and the upper surface of the optical device.

[0033] The invention according to claim 26 is a position corresponding to the lower tray having stepped portions for holding the four corners of the rectangular optical device on the upper surface and the rectangular optical device held by the first stepped portion. A packaging case for an optical device that houses an optical device between an upper tray provided with a recess in the lower surface of the recess, and an elastic member between the inner bottom surface of the recess and the upper surface of the rectangular optical device. A lid member is arranged.

 The invention according to claim 27 is characterized in that protrusions that contact the four corners of the optical device are formed on the surface of the lid member on the optical device side.

 The invention according to claim 28 is characterized in that the elastic member is a double-sided adhesive member.

 The invention according to claim 29 is characterized in that the thickness of the elastic member can be selected according to the thickness of the optical device.

 The invention according to claim 30 is characterized in that the thickness of the lid member can be selected according to the thickness of the optical device.

[0034] [Eighth aspect of the present invention to achieve the seventh object]

 In order to achieve the seventh object, the eighth aspect of the present invention comprises the following arrangement. The packaging case for an optical device according to claim 31 is a packaging case for storing an optical device, and a plurality of dot-shaped gels are arranged at predetermined intervals on an inner bottom surface of a box-shaped packaging case body. Then, the optical device is vertically placed on the surface of each gel to be fixed and self-supported, and a lid having a holding material at a position corresponding to the plurality of optical devices fixed and self-supported is put on the packaging case main body, and The optical device is configured to be held by the holding material.

The packaging case for an optical device according to claim 32 is a packaging case for storing an optical device, and a plurality of dot-shaped gels are arranged at predetermined intervals on an inner bottom surface of a box-shaped packaging case body. A partition having a holding material provided at a position corresponding to the plurality of optical devices fixed and self-supported by vertically placing the optical device on the surface of each gel. A plate is put on the optical device, the optical device is held by the holding material, and a plurality of dotted gels are arranged on the upper surface of the partition plate at predetermined intervals, and the optical device is vertically arranged on the surface of each gel. Place the lid having a holding material provided at a position corresponding to the plurality of optical devices fixed and self-supported on the packing case body, and hold the plurality of optical devices by the holding material. Configure as follows.

 [0035] An optical device packaging case according to Claim 33 is a packaging case for storing an optical device, and each of the gels on the lower plate in which a plurality of dotted gels are arranged at a predetermined interval. A plurality of optical devices placed vertically and fixed and self-supported, and a plurality of optical devices sandwiched and held by an upper plate provided with a holding material at a position corresponding to the optical device fixed and self-supported And is configured to be covered with a lid.

 35. The optical device packaging case according to claim 34, wherein the optical device extends in parallel with the optical surface of the optical device from the inside of the wall surface of the packaging case, between the optical surfaces of the plurality of optical devices that are vertically fixed and fixed independently. It is configured to provide a guide for preventing the device from falling down.

 The packaging case for an optical device according to claim 35 is configured such that in the packaging case, the gel is arranged in a strip shape with a predetermined width, and a plurality of optical devices are fixedly supported on the gel at a predetermined interval.

 [0036] The packing case for optical devices according to claim 36 is a packing case for storing an optical device, and a plurality of recesses having a predetermined shape are formed on an inner bottom surface of a box-shaped packing case body. Provided in a band shape, a dot-like gel is arranged in the concave portion, and an optical device is vertically placed on the surface of the gel so as to be fixed and self-supporting, and a holding material provided at a position corresponding to the plurality of optical devices that are fixed and self-supported. A lid having the cover is placed on the packing case body, and the plurality of optical devices are held by the holding material.

The packaging case for an optical device according to claim 37 is a packaging case for storing an optical device, and is provided on a bottom surface of the optical device to be self-supported at a predetermined position on the bottom surface inside the box-shaped packaging case body. A plurality of point-like gels at two locations are arranged at intervals corresponding to both corners, and the optical device is fixed and self-supported on the surface of each pair of gels, and is held at a position corresponding to the optical device that is fixed and self-supported. A lid having a material is placed on the packing case body, and the plurality of optical devices are held by the holding material. The packaging case for optical devices according to claim 38 is a packaging case for storing optical devices, and the four corners of a plurality of optical devices placed flat on the inner bottom surface of a box-shaped packaging case main body. Four gels are placed in a dot-like position at the position corresponding to, and an optical device is fixed on the surface of each gel and covered with a lid.

 The packaging case for an optical device according to claim 39 is a packaging case for storing an optical device, and a plurality of triangular tapered portions are provided at predetermined intervals on an inner bottom surface of a box-shaped packaging case body. 4 gels are arranged in a dotted manner at positions corresponding to the four corners of the optical device when placed flat across the two tapered portions, and a plurality of optical devices are placed flat on the surface of the gel. The packaging case body is covered with a lid. The invention's effect

 [0037] In the optical device case and the packing method according to claims 1 to 4 of the first aspect of the present invention, the optical device is inserted using a jig having a plurality of parallel through holes. In addition, there is an advantage that the optical device packing case can be simplified, the cost can be greatly reduced, and at the same time, the reuse is easy.

 The inventions described in claims 5 and 6 according to the second aspect of the present invention provide a variety of trays by changing the position where the adhesive tape is attached to the tray substrate or changing the width of the adhesive tape. Because it is a general-purpose tray that can handle optical devices of the shape, it can realize an inexpensive packaging case with a simple structure, which is very effective in delivering optical devices to customers. The invention according to claim 7 is capable of stacking general-purpose trays in multiple stages, and can determine the number of stages according to the quantity of optical devices delivered to the customer. Realizing a packaging case and exerting a great effect on delivering optical devices to customers.

[0038] In the inventions according to claims 8 to 10 according to the third aspect of the present invention, the upper surface (inner bottom surface) of the lower case is a recess having a curved concave section (the inner wall is curved symmetrically toward the outside). Since the adhesive layer is provided on the curved inner wall, when the optical device is fitted horizontally in the recess, the outer peripheral edge of the optical device having a different size and shape depending on the adhesive layer on the inner wall is provided. Can be adhered and held. For this reason, optical devices of various sizes can be held in a desired horizontal posture without rubbing or pressing the optical surface or adhering an adhesive. Even if the attitude of the optical device in the recess deviates from the horizontal attitude force, the inner wall is provided on the outside and curved in a concave shape, so that there is no wrinkle on the optical surface to which an adhesive adheres.

 According to the inventions of claims 11 to 14 according to the fourth aspect of the present invention, the upper and lower central portions of the optical device are clamped and held by the upper and lower convex portions, and the adhesive force of the lower elastic adhesive member Is set to be stronger than the adhesive force of the upper elastic adhesive member, so that the optical device will not deviate from or fall between the two convex portions even if impact or vibration is applied. In addition, the direction in which the optical device vibrates due to impact or the like is limited to the left-right direction. By securing a sufficient distance between the inner wall of the lid member and the tray, the optical device collides with the inner wall. This eliminates problems such as damaging the optical device and the material constituting the inner wall becoming dust and flying into the container and adhering to the optical surface of the optical device. Further, when the lid member is opened, the optical device can maintain the state held by the elastic adhesive member on the lower convex portion. According to the invention of claim 15 according to the fifth aspect of the present invention, both end edges of the optical device are formed in the open portion formed between the pitches of the plurality of bellows sheets arranged in parallel with a predetermined interval in the width direction. The optical device is protected even when vibration or impact is applied. As a holding method, holding by the elasticity of the bellows sheet itself or holding by an adhesive surface formed on the inner wall of the open portion is possible. Case inner wall force By supporting optical components in a non-contact state, the inner wall of the case is scraped by the optical components, and dust is generated. Since the open width (pitch width) of the bellows sheet can be adjusted, it is possible to use the bellows sheet with the same structure to hold optical parts of different thicknesses and dimensions.

 In the invention described in claim 16, since both ends in the longitudinal direction of the bellows sheet are supported by the inner walls facing each other, the bellows sheet can be easily set and used in the case. By changing the size of the case used (distance between both inner walls), the opening pitch of the bellows sheet with the same configuration can be changed, so it is commonly used to hold optical devices of different sizes and thicknesses. be able to.

In the invention described in claim 17, the bellows sheet has its bottom side on the inner bottom surface of the case. Since it is bonded, the opening pitch of the bellows sheet to be used can be arbitrarily changed.

 In the invention described in claim 18, since the edge of the optical device is adhered and held by the adhesive layer provided on the inner wall of the open portion of the bellows sheet, the edge of the edge of the optical device is held in line contact by the adhesive layer. As a result, the optical device can be easily removed while it can be securely held.

According to the nineteenth aspect of the present invention related to the sixth aspect of the present invention, an optical device is formed in a gap formed between the pitches of two coil springs arranged in parallel with a predetermined interval in the width direction. The optical device is protected even when vibrations or shocks are applied, because both end edges of the lens are inserted and elastically held. Further, by supporting the optical device such as the inner wall of the case in a non-contact state, the inner wall of the case is not scraped by the optical device and no dust is generated. Since the coil spring gap width (pitch width) can be adjusted, the same coil spring can be used to hold optical devices of different thicknesses and dimensions.

 The invention according to claim 20 can select not only a circular shape but also an arc shape, an elliptical shape, or a polygonal shape as the end face shape of the coil spring, so that a coil sling having an optimum shape according to the shape of the optical device, etc. Can be selected.

 The inventions according to claims 21, 22 and 23 are provided with pitch adjusting means for setting the pitch width of the coil spring to an arbitrary interval, and thus have different thicknesses and shapes using one packing case. Various optical devices can be held.

 In the invention described in claim 24, since the plurality of coil springs and the plurality of optical devices held by the coil springs are vacuum-sealed in the bag, in addition to the effects of the above-mentioned claims, the optical device is connected to dust. It can be protected.

[0041] According to the inventions of claims 25 to 30 according to the seventh aspect of the present invention, the thickness of the elastic member and the lid member is set to the thickness of the optical device without changing the design of the upper tray and the lower tray. Therefore, there is an advantage that even optical devices having different thicknesses can be packed in a common tray.

According to the inventions described in claims 31 to 37 according to the eighth invention, The optical device is fixed and self-supported on the surface of the dotted gel arrayed on the inner bottom surface, and the optical device is held using the holding material provided on the lid by covering the lid, so the optical device is not contaminated at low cost. It is possible to provide an easy-to-use packaging case, which is very effective in transporting optical devices.

 The invention described in claim 32 has the features described in claim 31 and can have two stages of optical devices, and exhibits a great effect when a large number of optical devices are stored in a packing case.

 The invention described in claim 33 is effective because the optical device is shipped with a plurality of optical devices not directly fixed to the packaging case, and the degree of freedom in handling is increased at the time of shipment of the optical device, and the optical device is not contaminated. It is possible to provide a low-cost and easy-to-use packaging case, which is very effective for transporting optical devices.

 The invention described in claims 34 to 36 is characterized in that, in addition to the features described in claim 1, a guide is provided in parallel to the optical surface of the optical device that is standing alone, and when the packing case is opened.

If the optical device falls down, it will prevent the optical devices from coming into contact with each other, and will have a great effect on preventing damage to the optical device.

 The invention described in claims 38 and 39 is effective when the optical device is desired to be placed flat, can provide an easy-to-use packaging case at low cost without fouling the optical device, and transports the optical device. This is a great effect.

BEST MODE FOR CARRYING OUT THE INVENTION

 Hereinafter, the first to eighth aspects of the present invention will be described in detail.

[First invention]

FIG. 1 is a schematic cross-sectional view showing an embodiment of an optical device packaging case according to the first aspect of the present invention, in which plate-like optical devices 1 are installed in parallel (parallel) at a predetermined interval. And a hollow (annular) frame that is dimensioned and shaped so that only both ends in the width direction of the optical device 1 (direction perpendicular to the arrangement direction of the optical device) are in contact with the inner wall surface of the frame. Adhesive sheet 3 is attached to member 2 and the upper surface, bottom plate member 4 to which the lower end of the optical device adheres to adhesive sheet 3, and another adhesive sheet 5 is attached to the inner upper surface (ceiling surface), and The upper end of the optical device 1 is bonded to the pressure-sensitive adhesive sheet 5, and the frame member 2 and the bottom plate member 4 A cap-shaped lid member 6 combined so as to cover the case, and an optical device case configured to have a force.

 As shown in FIG. 1, the lower end surface force of the optical device 1 is attached to the adhesive sheet 3 on the bottom plate member 4, and both ends of the outer periphery are fixed by the frame member 2, and the upper end surface is the inner surface of the cap-shaped lid member 6. The adhesive sheet 5 is adhered to the adhesive sheet 5, and the adhesive sheets 3 and 5 and the frame member 2 are adhered and fixed in the packaging case. The optical devices 1 are arranged in parallel across the space 7. The assembly of the optical device packaging case of the present invention will be described in more detail with reference to exploded views.

 As shown in the perspective view of FIG. 2, the double-sided adhesive sheet 3 is attached to the upper surface of the bottom plate member 4, and the frame inner dimension Y of the annular frame-shaped member is matched to the width dimension of the optical device 1. The member 2 is bonded to the adhesive sheet 3. A step portion is formed on the outer peripheral portion of the frame member 2. Then, as shown in FIGS. 3 (a) and 3 (b), a plan view and a cross-sectional view taken along the line AA, many through-holes 8 are provided in parallel so that the optical device 1 can be inserted perpendicularly to the bottom plate member. The jig 9 thus placed is placed on the frame member 2 and brought into a state as shown in FIG. At this time, by forming a stepped portion corresponding to the stepped portion of the frame member 2 on the lower peripheral edge of the jig 9, both can be fitted together to prevent displacement.

 The optical device 1 is inserted from the through-hole 8 of the jig 9 shown in the cross-sectional view of FIG. 3 (c) and adhered to the adhesive sheet 3 on the bottom plate member 4. At the same time, the frame member 2 moves the optical device in the width direction. Can be suppressed. Next, by removing the jig 9, the optical device 1 is bonded and fixed to the adhesive sheet 3 and the frame member 2 as shown in the sectional view of FIG. It will be in the state. Then, as shown in FIG. 3 (e), this upper force is also applied to the cap-shaped lid member 6 to form a stepped portion corresponding to the stepped portion of the frame member 2 on the lower peripheral edge of the cap-shaped lid member 6. Both can be fitted to each other to prevent displacement. At this time, since the double-sided pressure-sensitive adhesive sheet 5 is attached to the flat portion of the inner surface (ceiling surface) of the cap-shaped lid member 6, the pressure-sensitive adhesive sheet 5 is bonded to the other end in the longitudinal direction of the optical device 1. As a result, the bonding and fixing of the optical device becomes stronger.

In order to facilitate unpacking and reuse, the adhesive sheets 3 and 5 have different adhesive strengths, and the adhesive sheet 3 on the bottom plate member side increases the adhesive strength of the cap-like lid member side (a) adhesive sheet It is desirable to weaken it of 5. With this configuration, when the cap-shaped lid member 6 is opened, the optical device 1 is not opened while adhering to the lid member 6 side. When the lid member is opened, the optical device 1 is always placed on the bottom plate member. It can be left.

The feature of the present invention is that the thickness of the through hole 8 of the jig 9 is changed, and the optical device 1 having various thicknesses is formed into the shape of the bottom plate member 4, the frame member 2, the cap-shaped lid member 6, and the like. This is a packaging case for optical devices that can be accommodated without changing. In addition, unpacking is easy, and it is easy to reuse the packaging case for optical devices.

 The material of the frame member 2, the bottom plate member 4, the cap-shaped lid member 6 and the like may be a resin such as polyvinyl chloride resin, polystyrene resin, polyester resin, polyethylene resin, and sheet molding. Alternatively, it may be formed by injection molding. However, it is desirable that the frame member 2 be made of a material that can be elastically deformed to some extent so as to allow variations in the width direction of the optical device.

 In FIGS. 2 and 3, the force indicating the stepped portion formed on the frame member 2 and the cap-shaped lid member 6 so that the frame member 2, the bottom plate member 4 and the cap-shaped lid member 6 are fitted to each other. However, it is not necessary. Even if the length of the optical device is different if the step is not provided, the same optical device can be obtained by covering the adhesive sheet 5 of the cap-shaped lid member 6 deeply until it contacts the other end of the optical device 1 in the longitudinal direction. It is possible to accommodate optical devices with different longitudinal dimensions in the case.

[0045] [Second Invention]

 Next, the second aspect of the present invention will be described in detail based on the illustrated embodiment. The second aspect of the present invention is characterized in that a tray that can be used universally for various types of optical devices is provided. The tray is plate-shaped and has a window (through-hole) of a predetermined size in the center. ) Was applied to the window, and an adhesive tape with a tape width matching the shape of the optical device was attached to the window, and the optical device was placed flat and adhered from the front side of the tray. In addition, when sticking adhesive tape to optical devices, the adhesive tape is attached to the optical device so that it does not affect the effective diameter of the optical surface of the optical device (wider than the effective diameter and from the outer dimensions). Narrow).

FIG. 4 is a structural diagram showing a first embodiment of the packaging case according to the second aspect of the present invention, and FIG. a) shows an exploded perspective view, and FIG. 4 (b) shows a stacked view. As shown in FIG. 4, the packaging case 27 includes a general-purpose tray 29 that accommodates the optical device 28, an upper lid 30, and a bottom plate 31. The back surface of the general-purpose tray 29 is adhered to the back surface with a predetermined width. Two adhesive tapes 33 are attached so that the surface extends from the window 32 provided in the general-purpose tray 29, and the optical device 28 exerts a force on the effective diameter of the optical surface of the optical device 28 on the adhesive surface of the adhesive tape 33. Glue like so.

 Therefore, by configuring the packing case 27 as in the first embodiment, even if the packing case 27 vibrates, the optical device 28 and the general-purpose tray 29 do not come into contact with each other to generate dust. In addition, since the optical device 28 is placed flat, a guide for preventing the optical device 28 from falling down is also unnecessary.

FIG. 5 shows an exploded view of the general-purpose tray in the packaging case according to the present invention, FIG. 5 (a) shows only the tray substrate, and FIG. 5 (b) shows the back of the tray substrate. Fig. 5 (c) is a view of the state where two adhesive tapes are pasted as seen from the back, and Fig. 5 (c) is a view of the state where the optical device is bonded to a general-purpose tray as viewed from the front. As shown in FIG. 5, the general-purpose tray includes a tray substrate 34 and two adhesive tapes 33, and the tray substrate 34 has a window 32 having a predetermined size.

 The window 32 is set to be larger than the outer dimension of the optical device 28 of the maximum dimension accommodated in the general-purpose tray, and the position where the two adhesive tapes 33 are pasted is adjusted according to the outer dimension of the optical device 28. That is, when the optical device 28 is bonded to the adhesive tape 33 with the distance between the two adhesive tapes 33 pasted along the long side of the window 32 provided on the tray substrate 34, the optical surface of the optical device 28 to be bonded. The effective diameter is set so as not to apply force. In this embodiment, as shown in FIG. 5, there is an ineffective area of 0.5 mm on the optical surface of the optical device 28, and the optical device 28 is arranged so that the adhesive surface of the adhesive tape 33 contacts this portion.

FIG. 6 is a structural diagram of a general-purpose tray showing a modification of the first embodiment of the packaging case according to the present invention. The modification shown in FIG. 6 (a) shows a case where a small-sized optical device is stored in a general-purpose tray as compared with the optical device shown in the first embodiment. Two adhesive tapes 36 are affixed to the back surface of the general-purpose tray 35 so that the adhesive surface has a predetermined width and extends from the window 32 provided on the tray substrate 34, and the optical device 37 includes the two adhesive tapes. Tape 3 Adhere to the adhesive surface of 6 so that the effective diameter of the optical surface of the optical device 37 does not require force. In this modification, the optical device 37 that is smaller than the optical device 28 shown in the first embodiment is stored along the long side of the window 32 provided on the tray substrate 34. The two adhesive tapes 36 to be pasted are made wider in width and the tape interval is made narrower according to the size of the small optical device 37. In this way, by adjusting the distance between the two adhesive tapes 36 applied along the long side of the window 32 provided on the tray substrate 34, or by changing the width of the adhesive tape, various optical shapes can be obtained. The device can be stored in this packing case.

 Next, for example, when storing a smaller optical device 39 as in the general-purpose tray 38 shown in FIG. 6 (b), the three adhesive tapes 36 are fixed to the tray substrate 34 to improve the storage capacity. It is also possible. However, when multiple adhesive tapes are used, the center adhesive tape is only fixed at both ends, so attention should be paid to vibration and impact resistance.

FIG. 7 is a structural view showing a second embodiment of the packaging case according to the present invention, FIG. 7 (a) shows an exploded perspective view, and FIG. 7 (b) shows a stacked view. Show. In the second embodiment, the number of optical devices is increased by stacking general-purpose trays in multiple stages. The general-purpose tray 29 has a structure that can be overlapped, and the packing case 40 is a multi-stage stack of the general-purpose trays 29 for storing the optical devices 28, and the upper lid 30 and the bottom plate 31 are attached.

 As described above, the general-purpose tray 29 has two adhesive tapes 33 attached to the back surface of the general-purpose tray 29 so that the adhesive surface faces the window 32 having a predetermined width and the adhesive surface provided on the general-purpose tray 29. The effective diameter of the optical surface of the optical device 28 is firmly attached to the adhesive surface 33 so as not to force. Thus, an optimal packing case 20 can be realized by arbitrarily increasing or decreasing the number of general-purpose trays 29 according to the number of optical devices 28 accommodated.

 In the above embodiments, one tray substrate is provided with one window, but a single tray substrate may be provided with a plurality of windows.

[0049] [Third invention]

Next, the third aspect of the present invention will be described in detail with reference to the embodiment shown in the drawings. FIG. 8 is a front longitudinal sectional view showing the configuration of the packaging case for an optical device according to an embodiment of the third invention, FIG. 9 (a) is an external perspective view showing an example of the lower tray, and FIG. b) FIG. 9C is a front longitudinal sectional view showing a state in which the vise is held, and is an explanatory view showing a state in which the optical device is tilted.

 The optical device packaging case 51 is composed of a lower case 52 and an upper case 60 that forms a space for accommodating an optical device between the lower case 52 and the upper case upper surface by being closed on the lower case 52. On the upper surface of the lower case 52, there is a recess 53 for accommodating the optical device 70 in a substantially horizontal posture (flat state). The inner wall 54 of the recess 53 is a concave curved surface whose longitudinal cross-sectional shape includes an arc shape or an elliptical arc shape. That is, the inner wall 54 has two inner wall surfaces 54a facing each other and a bottom wall 54b constituting the bottom surface curved in a concave shape toward the outer side (left and right outer sides and lower side), respectively. It has a symmetrical shape. The distance between the two inner walls 54a facing each other in the recess 53 is configured to gradually decrease in the downward direction.

 The inner wall 54 is a curved surface having an arc shape, an elliptical arc shape, or any other curvature and shape, and is a surface curved concavely toward the outside of the recess 53 (concave curved surface). While protecting the optical surface, it is possible to keep the optical surface stably regardless of the size of the optical device.

 The planar shape of the recess 53 is long so that a plurality of optical devices can be arranged in a line at a predetermined pitch as shown in FIG. An adhesive layer 55 is formed on at least a part (the entire surface in this embodiment) of the inner wall of the recess 53.

 The optical device 70 has a rectangular flat plate shape in which at least two optical surfaces 70a and 70b face each other. For example, an optical film 70a ′ is formed on one optical surface 70a.

With the adhesive layer 55 on the inner wall of the recess 53, with the optical surface 70a facing upward, only the outer peripheral edge (the lower corner in this example) of the optical device 70 is in line contact with the adhesive layer 55, or It is configured to adhere and hold by point contact. Therefore, the adhesive does not adhere to the optical surfaces 70a and 70b, and each optical surface is not rubbed and pressed to be damaged. In particular, since the inner wall 54 has a curved surface that is concavely curved outward, the posture of the optical device 70 that is adhered and held in a line contact state or a point contact state in the recess is in a horizontal state. Even if tilted, the optical surface will not touch the adhesive layer 55 (Fig. 9 (c)). Further, since the optical device 70 is configured to be prevented from being displaced or dropped due to vibration shock by being held by the adhesive layer 55, the optical device 70 may be optically coupled by other means. I don't have to hold down the device. Since it is not necessary to use the upper case 60 as a means for holding the optical device as in the prior art, there is no problem that a part of the upper case 60 is in contact with the optical surface of the optical device.

 The buffer layer can be improved by using an elastic material having cushioning properties as the adhesive layer 55 or by applying a pressure-sensitive adhesive on the cushion layer. Particularly in the present invention, as shown in FIG. 8, the distance between the inner walls 54a of the recess 53 becomes narrower as it goes downward, so that a small-sized optical device can be accommodated on the bottom side in the recess 53. As the size increases, it can be accommodated above the recess. Therefore, it becomes possible to accommodate optical devices of different sizes and shapes using this container, and the versatility is enhanced. Therefore, it is possible to eliminate the disadvantages and disadvantages of the conventional example of manufacturing and preparing a special container having a different shape and structure for each type of optical device.

[Fourth Invention]

 Hereinafter, the fourth aspect of the present invention will be described in detail with reference to embodiments shown in the drawings.

 FIG. 10 (a) is a front longitudinal sectional view showing the configuration of an optical device packaging case according to an embodiment of the fourth invention, FIG. 10 (b) is an external perspective view showing an example of a tray, and FIG. (c) is a perspective sectional view of a main part in a state where an optical device is held.

 As shown in FIG. 10 (c), this optical device packing case 81 is configured to accommodate a plurality of optical devices 100 as polyhedrons in which at least two non-optical surfaces 100a and 100b face each other in parallel. It has. The illustrated optical device 100 has a rectangular flat plate shape, and its front and rear surfaces 100c are optical surfaces.

 The optical device packing case 81 includes a tray (lower case) 82 on which the upper surface is opened and the optical device 100 is placed on the upper surface (inner bottom surface) 82a, and a lid member 90 surrounding the space on the tray 82. Yes. The shape of the tray 82 may be a flat plate as illustrated, or may be a box shape.

The upper surface 82a of the tray 82 is provided with at least one long lower convex portion 83 that supports the central portion of the bottom surface in a state where the plurality of optical devices 100 are arranged in a line, and the lower convex portion 83 is flat. A cushion member 84 and a lower adhesive layer 85 that adheres to the bottom surface of each optical device are provided on the upper surface. In this example, the cushion member 84 is fixed to the upper surface of the lower convex portion 83. An adhesive layer 86 is provided for setting.

[0052] The cushion member 84 and the adhesive layers 85 and 86 constitute a lower elastic adhesive member (double-sided tape). The lower elastic adhesive member may be a member made of a single material having adhesiveness and cushioning properties.

 The ceiling surface 90a of the lid member 90 is provided with at least one long upper convex portion 91 that supports the center of the upper surface of each optical device 100, and a cushion member 92 is provided on the flat lower surface of the upper convex portion 91. An upper adhesive layer 93 that adheres to the bottom surface of each optical device is provided. In this example, an adhesive layer 94 for fixing the cushion member 92 is provided on the lower surface of the upper convex portion 91.

 The cushion member 92 and the adhesive layers 93 and 94 constitute an upper elastic adhesive member (double-sided tape). The upper elastic adhesive member may be a member made of a single material having adhesiveness and cushioning properties.

 The tray 82 and the lid member 90 are made of a resin material such as ABS, PP, PS, or poly force. The tray 82 is not limited to a flat plate shape as illustrated, and may be a box shape having an outer wall. Further, the lid member 90 is not limited to the box shape as illustrated, and may be a flat plate shape.

 As the lower and upper elastic adhesive materials, for example, an adhesive material is applied to both front and back surfaces of an elastic member made of polyurethane sheet, polyolefin, acrylic, or silicon-based resin to form a double-sided tape-like elastic adhesive material. But ヽ. A gel-like material may be used as the adhesive material.

 The lower convex portion 83 and the upper convex portion 91 are set so as to face each other when the lid member 90 is closed on the tray 82. The area of the upper surface of the lower convex portion 83 and the area of the lower surface of the upper convex portion 91 are not necessarily the same.

The characteristic configuration of this embodiment is that the adhesive force of the lower adhesive layer 85 (lower elastic adhesive member) is set stronger than the adhesive force of the upper adhesive layer 93 (upper elastic adhesive member). is there.

With this configuration, when the optical device is packed, in order to arrange the optical devices 100 at a predetermined pitch on the lower adhesive layer 85 of the tray 82, the center of the bottom surface of each optical device 100 is placed on the lower side. After placing on the adhesive layer 85 and adhering and holding it, the lid member 90 is put on the tray 82 and closed while being aligned, so that the upper adhesive on the lower surface of the upper convex portion is closed. The upper and lower surfaces of each optical device can be clamped and held via the cushion members 84 and 92 while the layer 93 is bonded to the center of the upper surface of each optical device. For this reason, in the state where the lid member is closed, the optical device is held between the convex portions while being held between the convex portions, and is in a state where the optical device is held between the convex portions, so that impact and vibration are applied. However, the optical parts will not be displaced or fall between the two convex parts. In addition, since the optical component is supported at the upper and lower central portions by the upper and lower convex portions, the direction in which the optical component vibrates due to impact or the like is limited to the left-right direction, and between the inner wall of the lid member and the tray. By securing a sufficient distance between them, it collides with the inner wall or the like to damage the optical component, or the material constituting the inner wall or the like becomes dust and scatters in the container, so that the optical surface of the optical component There are no problems such as sticking to the surface.

 In addition, since the adhesive force of the lower adhesive layer 85 (lower elastic adhesive member) is set stronger than the adhesive force of the upper adhesive layer 93 (upper elastic adhesive member), the optical device 100 is removed when the lid member 90 is removed. Is always held by the lower adhesive layer 85, and there is no problem that the optical device is stuck to the upper adhesive layer 93 side of the lid member and taken out.

 Next, FIGS. 11 (a) and 11 (b) are front longitudinal sectional views showing the configuration of an optical device packaging case according to another embodiment of the present invention. It is explained with a mark. The characteristic configuration of the optical device packaging case according to this embodiment is that the lower protrusion 83 is composed of a plurality of small protrusions 83a, and the upper protrusion 91 is one. In the embodiment of FIG. 11 (a), the lower surface of the optical device 100 is supported by two small projections 83a at two points, and in the embodiment of FIG. 11 (b), the lower surface of the optical device 100 is supported by three small projections. Three points are supported by 83a. The elastic adhesive member composed of the adhesive layers 85 and 86 and the cushion member 84 is disposed at the tip of each small protrusion 83a as in the embodiment of FIG.

In this way, the upper side of the optical device 100 is elastically bonded and held by the lower surface of the upper protrusion 91, while the tray 82 side is elastically bonded and held by the upper surfaces of the plurality of small protrusions 83a. The holding force in the closed state of the member is increased to prevent displacement and dropout, while preventing shaking of the optical device due to vibration and impact. Furthermore, the total area of the lower adhesive layer exceeds the upper side while using materials having the same adhesive force as the lower adhesive layer (lower elastic adhesive member) and the upper adhesive layer (upper elastic adhesive member). , Inevitably, the adhesive force of the lower adhesive layer is increased, and there is no problem that the optical device is stuck to the upper adhesive layer 93 side of the lid member and taken out.

Next, FIG. 12 is a front longitudinal sectional view of an optical device packaging case according to another embodiment of the present invention. The same parts as those of the embodiment of FIG. . The optical device packaging case 81 according to this embodiment has at least one long lower convex portion that supports the center of the bottom surface of each optical device in a state where a plurality of optical devices 100 are arranged in a row on the top surface of the tray. 83 and lower elastic adhesive members 84, 85, 86 disposed on the upper surface of the lower convex portion 83 and bonded to the lower surface of each optical device, and further on the ceiling surface 90a of the lid member 90, There is provided at least one elongated upper convex portion 91 that supports the central portion of the upper surface. A cushion member is provided on the lower surface of the upper convex portion as necessary.

 In this embodiment, the elastic adhesive members 84, 85, 86 are provided on the upper surface of the lower protrusion 83, while the upper convex portion 91 is configured to contact the optical device upper surface directly or via a cushion member.

 According to this embodiment, since the central portion of each of the upper and lower surfaces of the optical device is supported at two points, the optical device is not only held between the convex portions with the lid member 90 closed, Since the pressure is held while being bonded to the lower convex portion 83, the optical device does not shift or drop even if an impact or vibration is applied. In addition, since the optical device is supported by the upper and lower convex portions at the upper and lower central portions, the direction in which the optical device vibrates due to impact or the like is limited to the left and right directions, and between the inner wall of the lid member and the tray. By securing a sufficient distance between the optical device and the inner wall, the optical device may collide with the inner wall, or the optical device may be damaged. Eliminates problems such as adhesion to optical surfaces. Further, since the upper convex portion 91 and the upper surface of the optical device are not bonded, the optical device can maintain the state held by the elastic adhesive member on the lower convex portion 83 when the lid member is opened.

[0056] [Fifth Invention]

The fifth aspect of the present invention will be described below in detail with reference to the embodiments shown in the drawings. FIGS. 13 (a) and (b) are a partial cross-sectional perspective view of the packaging case of the fifth aspect of the present invention, and a plan view of the state holding the optical device. FIGS. 14 (a) and (b) In one embodiment of the present invention It is the front view and end view which show the basic shape of the arrangement | sequence means which comprises the packing case for optical devices which concerns.

 The packaging case 101 includes a lower case 103, a case 102 including an upper case 104 that closes an upper surface opening of the lower case 103, and an arrangement unit 111 that is supported by the lower case 103. Note that the arrangement means 111 may be supported by the upper case 104.

 The arrangement means 111 is composed of at least two (four in this example) bellows sheets (bellows-like panel panels) 112 arranged in parallel with a predetermined widthwise interval w, and each bellows sheet 112 is A flexible belt-shaped sheet material of the same material and the same shape is bent into a bellows shape with a predetermined pitch (so that a sharply bent portion is repeatedly formed). And have the same longitudinal length.

 As described above, in the present embodiment, a plurality of bellows erected in parallel on the bottom surface of the case with a predetermined interval w in the width direction as the array unit 111 that serially arranges the plurality of optical devices D in parallel at a predetermined pitch. The sheet 112 is used, and both end edges of the optical device D are inserted into the opening 112A formed between the pitches of the respective bellows sheets and held elastically, or are held using an adhesive. RU

 As shown in FIG. 14 (b), in this example, the end face shape is a rectangular force. As will be described later, the shape of the sheet material may be selected so as to have an end face shape other than a rectangle. The sheet material constituting the bellows sheet 112 may be a metal thin plate, a resin sheet such as PET or PS, or paper. In the case of metal, a grease coating is applied. In short, as the material of the sheet material, in the state where it is formed into a bellows shape, it has sufficient shape retention so that it does not fall down, bend, or expand due to the weight of the optical device held, Select an optical device that can exhibit elasticity (panelism) that can hold the edge of the optical device with a certain amount of force.

 As the shape of the sheet material, various forms can be considered as described later.

Further, depending on the usage method of the bellows sheet 112 in each embodiment to be described later, an adhesive layer may be formed in advance on the optical device holding surface of the glass sheet 112 or formed. You do n’t have to.

 [0058] The lower case 103 in the case 102 shown in Fig. 13 has a configuration in which a frame body 106 is erected and fixed to the outer peripheral edge of the bottom plate 105, and two opposing wall portions 106a of the frame body 106 are provided. 106 b are formed with a plurality of cut-like locking portions 7 for inserting and supporting the locked portions 12 a protruding from both ends in the longitudinal direction of the bellows sheet 112.

 The width interval w of each bellows sheet 112 is determined by the engagement of the bellows sheet to an arbitrary locking portion 7 selected from among the locking portions 7 arranged along the longitudinal direction of each wall portion 106a, 106b. Adjustment is made by locking the portion 112a. In short, the width direction interval w between the bellows sheets and the width direction position of the pair of bellows sheets 112 can be arbitrarily changed and adjusted. Another advantage is that the Jaraba sheet 112 can be easily attached and detached.

 In addition, by changing the size of the case used (distance between both inner walls), the opening pitch of the bellows sheet with the same configuration can be changed, so it is commonly used to hold optical devices of different sizes and thicknesses. can do.

[0059] Also, as shown in FIGS. 13 (a) and 13 (b), the opening portions (holding portions) 112A of the two adjacent bellows sheets 112 face each other, so that the opening portions 112A facing each other The optical device D is configured so that the edges of the optical device D are fitted and held respectively.

 The edge of the optical member D is protected by a sheet material of a bellows sheet constituting the opening 112A, so that it is protected even when vibration or impact is applied. Also, the case inner wall force By supporting the optical device D in a non-contact state, the optical device prevents the case inner wall from being scraped and generating dust.

 By providing an adhesive layer on the inner wall surface of the opening 112A where the bellows sheet 112 holds the optical device D, the edge line of the edge of the optical device D may be held by line contact, or the bottom plate 105 By forming the adhesive layer 110 on the upper surface of the optical device D, the bottom surface of the optical device D held between the bellows sheets may be adhered and held. At this time, the adhesive layer may be formed by using a double-sided tape, or by applying a spray paste.

FIG. 15 is an end view showing a modification of the bellows sheet, FIG. 15 (a) is a substantially trapezoidal shape, and FIG. 15 (b) is a shape having a tapered portion where the width of the tip gradually decreases. is there. In short, bellows The shape of the sheet can be variously modified according to the shape and size of the optical device to be held. FIG. 16 is a main part perspective view showing another embodiment of the packaging case 101 of the present invention. In this example, an adhesive layer 115 is formed in a strip shape along both end edges of the upper surface of the bottom plate 105 of the lower case 103. Both adhesive layers 115 adhere and hold the lower sides (bottom sides) of both ends of each bellows sheet 112. In addition, if necessary, the bellows sheet 112 may be positioned by forming an adhesive layer 110 on portions other than both end edges of the upper surface of the bottom plate.

 In this embodiment, the bent portion of the bellows sheet positioned on the upper surface of the bottom plate 105 is adjusted by adjusting the length (number of bent portions) of both ends of the bellows sheet 112 that is adhered and held by the adhesive layer 115 (110). The opening angle of the opening 112A can be adjusted to obtain an opening angle suitable for the optical device to be held. In other words, according to the present invention, by changing the position of the bellows sheet held by the adhesive layer 115 (110), optical devices having different sizes and thicknesses can be held using the same configuration of the bellows sheet.

 Next, FIGS. 17 (a), (b) and (c) are plan views showing the packing procedure of the optical device by the packing case according to another embodiment of the present invention, on the upper surface of the bottom plate 105 of the lower case 103. The adhesive layers 110a, 110b, and 110c that also have a double-sided tape equal force are formed in a band shape along the position where each bellows sheet 112 is arranged with a predetermined width direction interval Wl. The adhesive layers 110a, 110b, and 110c are selected in width and adhesive force so that the bottom surfaces of both ends of the optical device D can be adhered and held. Each bellows sheet 112 used in this embodiment has an adhesive layer formed in advance on the inner walls of the opening portions 112A and 112B that hold the optical device D.

 First, in the state of FIG. 17 (a), a bellows sheet 112 is erected on a first pitch with a predetermined pitch on the first adhesive layer 11Oa. One end of the optical device D is inserted into the opening 112A of the bellows sheet 112, and the other end of the optical component D is adhered and positioned on the second adhesive layer 110b as shown in FIG. Then, another bellows sheet 112 is erected and bonded on the second adhesive layer 110b.

Next, as shown in FIG. 17 (b), each optical device is inserted while inserting one end portion of the new optical device D into each open portion 112B on the other surface side of the bellows sheet 112 on the second adhesive layer 110B. The bottom surface of the chair is adhered and held on the second adhesive layer 110b, and the other end of the optical device D is adhered and positioned on the third adhesive layer 110c. The other end of the optical device D is inserted into the opening 112A of another bellows sheet 112 standing on the third adhesive layer 110c, and the other end of the optical device is formed by the adhesive layer formed on the inner wall of the opening 112A. Adhere and hold the ridgeline of the wire by line contact.

In FIG. 17, each bellows sheet 112 is erected and fixed in advance at a predetermined opening portion pitch on all the adhesive layers 110a, 110b, 110c in advance, and each bellows sheet is opposed to each other. The end portions of the optical device may be fitted into the portions 112A and 112B, and may be attached and held by each adhesive layer.

 Alternatively, no adhesive layer is provided on the inner wall of the open part of the bellows sheet, and the optical device is erected and held only by the adhesive force of the adhesive layers 11 Oa, 110b, 110c on the top surface of the bottom plate and the elastic holding force of the open part of the bellows sheet. Even if you do it.

 Also in this embodiment, since the adhesive layers 110a, 110b, 110c can arbitrarily set the opening angles of the opening portions 112A, 112B when the bellows sheet 112 is held, opticals having different sizes and thicknesses can be set. The device can be held using the bellows sheet with the same configuration.

 Note that the bellows sheet used in the present invention may be widened in the axial direction by expanding what is normally compressed, or in a state where it is normally expanded. The pitch width may be narrowed by compressing the object.

[0063] [Sixth present invention]

 The sixth aspect of the present invention will be described below in detail with reference to the embodiments shown in the drawings. 18 (a), (b) and (c) are a perspective view, a plan view and a longitudinal sectional view showing a state where the optical device is held in the packaging case according to the sixth aspect of the present invention, and FIG. (B) and (B) are a front view and an end view (viewed from the arrow A) showing the basic shape of the arrangement means constituting the optical device packaging case according to the embodiment of the present invention.

The packing case 121 includes a lower case 123, a case 122 including an upper case 124 that closes an upper surface opening of the lower case 123, an arrangement unit 131 supported by the lower case 123, It is configured with. Note that the arrangement means 131 may be supported by the upper case 124.

 The arranging means 131 is composed of at least two coil springs 132 arranged in parallel with a predetermined width direction interval w, and each coil spring 132 is made of a wire material having the same pitch, the same size, and the same material. Configure to the same length. In this example, the end face shape is circular, but any end face shape may be used as described later. Further, the wire constituting the coil spring may be a metal or a resin. In the case of metal, apply a grease coating. As the cross-sectional shape of the wire, all shapes such as a circle, an ellipse, and a polygon (corner chamfered in an R shape) can be assumed.

 The lower case 123 in the case 122 shown in FIG. 18 has a configuration in which a frame body 126 is erected and fixed to the outer peripheral edge of the bottom plate 125, and two opposing wall portions 126a and 126b of the frame body 126 are provided. A plurality of locking members (in this example, locking pins) 127 are provided on the upper surface of the respective plates in a predetermined arrangement. At both ends in the longitudinal direction of the coil spring 132 applied to the case 122, there are provided locked portions 132a that protrude in the longitudinal direction by a predetermined length and whose tips are configured in a hook shape or an annular shape. Is configured to be locked by the locking member 127. The interval w between the coil springs 132 in the width direction is set to any locking member 127 selected from a plurality of locking members 127 arranged along the longitudinal direction of the walls 126a and 126b. Adjust by locking the part 132a. Alternatively, it may be configured such that the position of the locking member 127 can be finely adjusted by moving in the width direction. In short, the interval in the width direction between the coil springs and the position in the width direction of the pair of coil springs 132 can be arbitrarily changed and adjusted.

 Further, as shown in FIGS. 18 (a) and 18 (b), when each open portion (holding portion) 12A of two adjacent coil springs 132 is opposed to each other, one optical device is provided in each open portion 132A facing each other. Each end edge of D is configured to be fitted and held.

The edge of the optical member D is elastically pinched and held by the wire material of the coil spring that constitutes the opening 132A, so that it is protected even when vibration or impact is applied. In addition, by supporting the case inner wall force optical device D in a non-contact state, the inner wall of the case is not scraped by the optical device, and dust is not generated. FIGS. 20 (a) to 20 (h) are end views showing modifications of the coil spring, FIG. 20 (a) is a horizontally long oval, and FIG. 20 (b) is a horizontally long oval. Yes, these may be arranged vertically. In this way, by using a horizontally long or vertically long ellipse or ellipse, it is possible to realize an optimal holding form according to individual circumstances such as the shape and size of the optical device D as a holding object. In particular, when three or more coil springs 132 are arranged in parallel as shown in FIG. 21 and the optical device is held in a two-row configuration using a central coil spring, the horizontally long coil is used. Using a spring makes it easier to hold two rows of optical devices at the same time.

 Next, in each of the embodiments shown in FIGS. 20 (c) to 20 (h), the bottom is configured to be flat so as to improve the installation stability of the lower case 123 with respect to the upper surface of the bottom plate. Fig. 20 (c) shows a semicircular shape, Fig. 20 (d) shows a shape obtained by cutting out a part of a circle in a straight line, and Fig. 20 (e) shows a vertically long oval (or oval). Figure 20 (f) shows a shape with a part of a horizontally long ellipse cut into a straight line. FIG. 20 (g) shows an arc shape with a center angle 0 of 90 degrees, and FIG. 20 (h) shows a shape obtained by cutting an ellipse or an oval shape so that the center angle is 90 degrees. By making the bottom side straight (flat) in this way, the position of the coil spring open portion (gap) 132A in contact with the edge of the optical device is specified, and stable holding can be realized. In addition, by appropriately selecting the shape of the portion other than the bottom, it is possible to realize holding suitable for each optical device.

 Next, FIGS. 22 (a) and 22 (b) show the width (pitch width) p of the open portion 132A so that optical components having different thicknesses and shapes can be held using the coil spring having the same configuration. An example is shown that is configured to change this.

In this example, one of the wall portions 126a and 126b of the lower case 123, for example, the locked portion 132a provided at one end of the coil spring 132 is locked by the locking member 127 provided on the wall 126a side, while the coil A wire member 133 such as a string or a flexible wire is fixed to the other end of the spring 132 for a required length, and a pitch adjusting means (winding means) provided on the other wall portion 126b. = Screws, pins, rollers, bobbins, etc. that are supported in a freely rotatable manner) The length of the coil spring in the axial direction can be expanded and contracted by winding or unwinding with 135. For this reason, as the axial length of the coil spring expands and contracts, the optical The holding part 132A can change the width p (pitch width) of the 132A to adjust the elastic clamping force, and hold optical devices with different thickness and shape by the coil spring with the same configuration. Is possible.

Next, based on FIG. 23, a configuration example in which the optical device held by the coil spring as the arrangement means of the present invention is vacuum packed will be described.

 First, as shown in FIG. 23 (a), both end edges of the optical device D are inserted and held in pressure contact with each open part 132A facing each other of two coil springs 132 arranged in parallel on a flat base 140. When the holding of all the optical devices D is completed, cover the unit U consisting of the two coil springs 132 excluding the base 140 and the optical device group U with a plastic bag 141, not shown! After the air in the bag 141 is removed, the opening of the bag 141 is sealed (FIG. 23 (b)).

 In addition, the unit U may be vacuum-sealed in the pedestal bags 141 with the unit U mounted on the pedestal 140 in FIG.

 [0068] In any case, the unit U consisting of the coil spring and the optical device cover is vacuum-sealed, so that the dust 141 is prevented from adhering to the air, and the bag 141 made of vinyl isotherm functions as a shock-absorbing material. Prevent damage to optical device D. In addition, since the bag 141 is in close contact with the optical device and the coil spring, the optical device and the coil spring are in a fixed state, so that there is no problem such as damage to the optical device due to rubbing of both.

 Further, the work of forming the unit U by inserting the optical device D into the opening 132A in a state where the coil spring 132 set on the pedestal 140 is held in a predetermined expanded state has good workability. When holding optical devices having different thicknesses and width-direction dimensions, the optical devices may be set after finely adjusting the pitch of the open portions 132A and the spacing between the coil springs.

 In addition, the coil spring used in the present invention may be configured such that the pitch width is widened by expanding in the axial direction the one that is in a compressed state at all times, or the one that is in a state in which the coil spring is in a normally expanded state. The pitch width may be narrowed by compressing.

[0069] [Seventh Invention] Hereinafter, the seventh aspect of the present invention will be described in detail based on an embodiment. However, the components, types, combinations, shapes, relative arrangements, and the like described in this embodiment are merely illustrative examples rather than the main point of limiting the scope of the present invention unless otherwise specified. Absent.

 FIG. 24 shows a first embodiment of an optical device packaging case according to the seventh aspect of the present invention. FIG. 24 (a) is a sectional view, and FIG. 24 (b) is an exploded view. It is sectional drawing. In FIG. 24, a part of the case is drawn, and in reality, a plurality of such cases are formed in a matrix shape or a tray shape connected and integrated in a strip shape.

 As shown in FIG. 24, the basic configuration for housing the optical device 153 between the upper tray 151 and the lower tray 152 is the same as the conventional one.

A characteristic configuration of the present invention is that a relatively large recess is formed on the lower surface of the upper tray 151, and an elastic member 158 and a lid member are formed in the gap between the inner bottom surface of the recess and the upper surface of the optical device 153. 15 9 is located.

 Actually, as shown in FIG. 24 (b), first, the optical device 153 is disposed in the stepped portion 160 provided in the recess on the upper surface of the lower tray 152.

 The step portion 160 is formed to support the periphery of the optical device 153. This is because light is transmitted through the central part of the optical device, so that this part is not damaged.

 On the other hand, a large recess 161 is formed on the lower surface of the upper tray 151. An elastic member 158 is disposed on the inner bottom surface of the recess 161, and a lid member 159 is disposed on the lower surface of the elastic member 158.

 At this time, it is desirable that the elastic member 158 is provided with an adsorbing property such that the lid member 159 does not fall due to gravity and can be easily peeled off when the lid member 159 or the elastic member 158 is replaced. For example, polyurethane sheet polyolefin resin, acrylic resin, silicone resin, etc. can be used as the elastic member, and ABS, PP, PS, poly resin, etc. can be used as the material for each tray and lid member. Will.

Next, the upper tray 151 that has been prepared as described above is placed on the lower tray 152 on which the optical device 153 is placed, so that the accommodation state as shown in FIG. . A recess 162 and a stepped portion 163 are formed on the lower surface of the lid member 159, that is, the surface on the optical device 153 side, and supports the peripheral portion of the optical device 153 in the same manner as the structure of the upper surface of the lower tray 152. To function.

 Note that the upper tray 151 and the lower tray 152 shown in FIG. 24 have exactly the same configuration. Therefore, the optical device can be accommodated so that a plurality of trays are stacked. Since it is configured as described above, the optical device 153 is cut off from the outside when packed and transported, so that it is possible to suppress the adhesion of dust and dust, and the elastic member 158 is disposed as a cushioning material. The thickness of the elastic member 158 according to the thickness of the optical device 153 while maintaining the same effect as the conventional tray-type packaging material that can prevent the optical device 153 from being damaged by an impact during transportation. Or, it is possible to perform packaging without changing the upper and lower trays by changing the thickness of the lid member as appropriate.

 FIG. 25 is a perspective view showing an example of the upper surface structure of the lower tray 152. A plurality of protrusions are formed on the upper surface of the lower tray 152, and the corners of the optical device are formed on the step portions formed on the protrusions. By inserting, the four corners of the optical device are held.

 By holding the four corners of the optical device in this way, it is possible to minimize the situation in which the optical device rotates in the plane direction during conveyance.

[0072] [Eighth Present Invention]

 The eighth aspect of the present invention will be described below in detail based on the illustrated embodiments.

 The present invention is characterized in that it is arranged in a dot-like manner only at points necessary for fixing an optical device that does not spread expensive gel over the entire inner bottom surface of the packing case body. Therefore, according to the present invention, it is possible to use a gel that does not contain an adhesive and has an adhesive force and store it in a low-cost packaging case without fouling the optical device and deliver it to the customer.

 Note that the dot shape means that a predetermined area, a predetermined amount of gel is formed into a non-wide area, partially (non-continuous), regardless of whether the planar shape of the gel is circular, polygonal, linear or other shapes. Mean).

FIG. 26 is a structural diagram showing a first embodiment of the packaging case according to the eighth aspect of the present invention. Figure Fig. 26 (a) shows a top view of the packing case body with the lid removed with the optical device placed vertically, Fig. 26 (b) shows a side view of the lid, and Fig. 26 (c) shows The cross-sectional view at A-A 'shows a state with a lid. In the first embodiment, a plurality of dotted gels 181 are arranged at predetermined intervals on the inner bottom surface of the packing case main body 180, and the optical device 182 is fixed to the surface of each gel 181. In order to increase the number of 182 accommodated, the optical device 182 is placed vertically. Therefore, by placing the optical device 182 vertically, the optical surface of the optical device 182 is not soiled.

 On the other hand, the holding force 184 for holding the optical device 182 using the lid 183 is provided on the lid 183 so that the optical device 182 is self-supporting due to the adhesive force of the gel 181 and the vibration resistance is further increased. The optical device is held by covering the packaging case main body 180 with a lid 183. As the holding material 184, gel, or synthetic rubber, acrylic, polyurethane, vinyl, Teflon (registered trademark), silicon, silicon rubber, or the like can be used as an elastic member. Also, to prevent the optical device 182 from sticking to the lid 183 when the packaging case is opened, the contact area of the gel 181 is made larger than the contact area of the holding material 184 provided on the lid 183. The fixing force of 181 is set to be higher than the holding force of the holding material 184.

 The relationship between the contact area between the gel and the retention agent described above is the same in other examples described below. Therefore, by using such a packaging case structure, it is possible to provide a packaging case that can be used at low cost without sacrificing the optical device.

FIG. 27 is a structural diagram showing a second embodiment of the packaging case according to the present invention. Figure 27 (a) shows a top view of the packing case body with the lid removed with the optical device placed vertically, and Figure 27 (b) is a cross-sectional view taken along the line AA '. Indicates the covered state. The second embodiment shows an example in which two optical devices are stacked and stored in a packing case. The second embodiment has the same structure as the first embodiment and is a structure for increasing the number of optical devices accommodated. A plurality of dot-like gels 181 are arranged at predetermined intervals on the inner bottom surface of the packing case body 185, and the optical device 182a is vertically placed and fixed on the surface of each gel 181. A partition plate 186 having a holding member 184a provided at a position corresponding to 182a is placed on the optical device 182a to hold the optical device 182a by the holding member 184a. Further, a plurality of dot-like gels 181 are arranged at predetermined intervals on the other surface (upper surface) of the partition plate 186, and the optical device 182b is vertically placed on the surface of each gel 181 so as to be fixed and self-supported. A lid 187 having a holding member 184b provided at a position corresponding to the plurality of self-supporting optical devices 182b is put on the packing case main body 185, and the optical device 182b is held by the holding member 184b.

 In the second embodiment, the force shown in the case of two-stage stacking, three-stage stacking, or a multi-stage stack of more than that can be configured using the same structure. Therefore, in this embodiment, an arbitrary structure can be adopted in accordance with the storage quantity of the optical device, and it is possible to use the optical device at a low cost without fouling the optical device, and to provide a packaging case.

FIG. 28 is a structural diagram showing a third embodiment of the packaging case according to the present invention, FIG. 28 (a) shows the internal structure, and FIG. 28 (b) is a sectional view of the packaging case. Indicates. In the third embodiment, the packing case has a double structure, and the optical device 182 is vertically fixed to each of the gels 181 of the lower plate 188a in which a plurality of dot-like gels 181 are arranged at predetermined intervals. The optical device 182 is held by being self-supported and sandwiched by an upper plate 188b provided with a holding material 184 at a position corresponding to the optical device 182. The optical device 182 is stored in a box-shaped packing case body 189 and covered with a lid 190. is there.

 Since this structure does not have a plurality of optical devices 182 directly fixed to the packaging case, the optical device 182 is effective in increasing the degree of freedom in handling at the time of shipment, and at a low cost without contaminating the optical device. Can provide easy-to-use packaging cases. In the third embodiment, the optical devices 182 can be stacked in multiple stages as shown in the second embodiment.

FIG. 29 is a structural diagram showing a fourth embodiment of the packaging case according to the present invention. Fig. 29 (a) shows a top view of the packing case body with the lid removed with the optical device placed vertically, and Fig. 29 (b) is a cross-sectional view taken along line AA '. Indicates the covered state. In the fourth embodiment, a guide 192 is provided in parallel to the optical surface of a self-supporting optical device and laterally toward the drawing. When the packaging case is opened, the optical device falls down. This prevents the optical devices from contacting each other. Therefore, a plurality of dot-like gels 181 are arranged at predetermined intervals on the inner bottom surface of the packaging case body 191 so that each gel The bottom of the optical device 182 is fixed to the surface of the optical device 181, and the optical device 182 is placed vertically to increase the number of optical devices 182 accommodated.

 As described above, the guide 22 for preventing the optical device 182 from collapsing is provided in parallel with the optical surface of the optical device 182. On the other hand, the holding force 184 for holding the plurality of optical devices 182 using the lid 193 is provided on the lid 193 in order to further increase the vibration resistance strength by the self-standing force of the optical device 182 due to the adhesive force of the gel 181. A plurality of optical devices 182 are held by covering the packing case main body 191 with a lid 193. Therefore, even in this embodiment, the optical device can be used at a low cost without fouling, and a good packaging case can be provided.

 FIG. 30 is a structural diagram showing a fifth embodiment of the packaging case according to the present invention. Fig. 30 (a) shows a top view of the packing case body with the lid removed with the optical device placed vertically, and Fig. 30 (b) is a cross-sectional view taken along the line AA '. Indicates the covered state. The fifth example is a modification of the fourth example, and the structure of the packing case body and the lid is the same as the fourth example, but the gel application method is changed, It is characterized in that the gel 194 is not arranged in the form of dots but is arranged in a band with a predetermined width. Accordingly, the optical device 182 is fixed to the gel 194 arranged in a band shape with a predetermined width on the inner bottom surface of the packing case main body 191 at a predetermined interval. Put it vertically! /

 Further, a guide 192 for preventing the optical device 182 from falling is provided in parallel with the optical surface of the optical device 182. On the other hand, the optical device 182 is self-supporting due to the adhesive force of the gel 181. However, in order to further increase the vibration resistance, the lid 193 has a holding material 184 for holding a plurality of optical devices 182 using the lid 193. A plurality of optical devices 182 are held by covering the packing case main body 191 with a lid 193. Therefore, even in the case of this embodiment, it is possible to use the optical device at low cost without fouling the optical device, and to provide a good packaging case.

FIG. 31 is a structural diagram showing a sixth embodiment of the packaging case according to the present invention. Fig. 31 (a) shows a top view of the packing case body with the lid removed with the optical device placed vertically, and Fig. 31 (b) is a cross-sectional view taken along the line AA '. Indicates the covered state. 6th implementation The example is a modification of the fourth embodiment, in which the shape of the guide is changed. On the bottom surface of the packaging case body 195, for example, a plurality of rhombus-shaped recesses 196 connected in a plurality of strips (in series) are arranged in parallel, and a dot-like shape is formed at the center of each recess 196. Place gel 181 and secure optical device 182. By storing the optical device 182 in the recess, even if the optical device falls down when the packing case is opened, the optical devices do not contact each other.

 On the other hand, the holding force 184 for holding the plurality of optical devices 182 using the lid 197 is provided on the lid 197 in order to further increase the vibration resistance strength, because the optical device 182 is self-supporting due to the adhesive force of the gel 181. A plurality of optical devices 182 are held by covering the packing case main body 195 with a lid 197. The shape of the recess 196 is not limited to a diamond shape, and may be any shape as long as the optical device 182 can be protected when the optical device 182 falls. Therefore, in this embodiment, the optical device can be used at a low cost without fouling, and a packaging case can be provided that is easy to use.

 FIG. 32 is a structural diagram showing a seventh embodiment of the packaging case according to the present invention. Fig. 32 (a) shows a top view of the packaging case body with the lid removed with the optical device placed vertically, and Fig. 32 (b) is a cross-sectional view taken along the line AA '. Indicates the covered state. The seventh embodiment is a modification of the first embodiment, in which the method of applying the gel for fixing the optical device is changed, and the gel is disposed at two corners of the bottom surface of the optical device to be self-supported. It is fixed. Therefore, a plurality of two point-like gels 198 are applied at predetermined positions on the inner bottom surface of the packing case main body 180 at intervals corresponding to both corners of the bottom surface of the optical device 182, and the surface of each pair of gels 198 is optically applied. The device 182 is fixed, and the optical device 182 is placed vertically to increase the number of optical devices 182 accommodated.

On the other hand, the holding force 184 for holding the plurality of optical devices 182 using the lid 183 is provided on the lid 183 in order to further increase the vibration resistance strength by the self-standing force of the optical device 182 due to the adhesive force of the gel 181. A plurality of optical devices 182 are held by covering the packing case main body 180 with a lid 183. Therefore, in this embodiment as well as the first embodiment, it is possible to provide a low-cost and easy-to-use packaging case without contaminating the optical device. FIG. 33 is a structural diagram showing an eighth embodiment of the packaging case according to the present invention. Fig. 33 (a) shows a top view of the packing case body with the optical device placed flat and secured, with the lid removed, and Fig. 33 (b) is a cross-sectional view taken along the line A-A '. Indicates the covered state. The eighth embodiment is a packing case structure that responds to, for example, a user-powered optical device that is required to be laid flat and delivered. The gel 200 is applied to each of the four corners of the optical device in four spots, and the optical device 182 is fixed to each surface of the gel 200. The packing case body 199 is covered with the lid 201. is there. According to this fixing method, the gel 200 is disposed at a position away from the optical surface of the optical device 182, and the optical surface is not soiled by the gel 200. Therefore, even when the optical device is placed flat as in this embodiment, a packaging case that is low in cost and easy to use can be provided.

 FIG. 34 is a structural diagram showing the ninth embodiment of the packaging case according to the present invention. Fig. 34 (a) shows a top view of the packing case body with the optical device placed flat and secured, with the lid removed, and Fig. 34 (b) is a cross-sectional view taken along the line AA '. Indicates the covered state. The ninth embodiment is a modification of the eighth embodiment, in which a plurality of triangular tapered portions 203 are provided at predetermined intervals on the inner bottom surface of the packing case main body 202, and straddle the two tapered portions 203. When placed flat, four gels 204 are arranged in a dot-like manner at positions corresponding to the four corners of the optical device 182, and a plurality of optical devices 182 are flatly fixed and fixed to the packing case body 202. 2 It is a structure covered with 05. According to this fixing method, only the side of the optical device 182 comes into contact with the gel, and the optical device 182 that does not contaminate the optical surface is placed flat, and it is possible to provide a packaging case that is easy to use at low cost.

 Brief Description of Drawings

 FIG. 1 is a schematic cross-sectional view showing the structure of an optical device packaging case according to the first invention.

 FIG. 2 is a perspective view showing a part of the assembly of the optical device packaging case according to the first invention.

FIG. 3 (a) to (e) are cross-sectional views showing a part of the assembly of the optical device packaging case according to the first aspect of the present invention. 4] (a) and (b) are structural views showing a first embodiment of a packaging case according to the second aspect of the present invention.

 FIG. 5 (a) (b) and (c) are exploded views of a general-purpose tray in the packaging case according to the second aspect of the present invention.

6] (a) and (b) are structural diagrams of a general-purpose tray showing a modification of the first embodiment of the packaging case according to the second invention.

7] (a) and (b) are structural views showing a second embodiment of the packaging case according to the second aspect of the present invention.

8] A front longitudinal sectional view showing the structure of the optical device packaging case according to the embodiment of the third invention.

 [Fig. 9] (a) is an external perspective view showing an example of a lower tray, and (b) and (c) are front longitudinal sectional views showing a state in which an optical device is held.

 FIG. 10 (a) is a front longitudinal sectional view showing a configuration of an optical device packaging case according to an embodiment of the fourth aspect of the present invention. FIG. 10 (b) is an external perspective view showing an example of a tray. ) Is a perspective cross-sectional view of the main part in a state where the optical device is held.

 [FIG. 11] (a) and (b) are longitudinal sectional views of a packaging case for an optical device according to another embodiment of the present invention, respectively.

 FIG. 12 is a longitudinal sectional view of an optical device packaging case according to another embodiment of the fourth invention.

 FIGS. 13A and 13B are a partial cross-sectional perspective view of a packaging case according to an embodiment of the fifth aspect of the present invention and a plan view showing a state in which an optical device is held in the case. .

 [FIG. 14] (a) and (b) are a front view and an end view showing the basic shape of the arrangement means constituting the optical device packaging case according to the embodiment of the fifth invention.

圆 15] End views showing a modification of the bellows sheet, (a) is a diagram of a substantially trapezoidal shape, and (b) is a diagram of a shape having a tapered portion in which the width of the tip gradually decreases.

16] FIG. 16 is a perspective view showing a main part of another embodiment of the packing case of the fifth invention.

[FIG. 17] (a), (b) and (c) are plan views showing a packing procedure of an optical device by a packing case according to another embodiment of the present invention. [FIG. 18] (a), (b) and (c) are a perspective view, a plan view and a longitudinal sectional view showing a state in which an optical device is held in a packaging case according to an embodiment of the sixth aspect of the present invention. is there.

 [FIG. 19] (a) and (b) are a front view and an end view (viewed in the direction of arrow A) showing the basic shape of the arrangement means constituting the optical device packaging case according to the embodiment of the sixth present invention. ).

 20 (a) to (h) are end views showing a modified configuration example of the coil spring of the sixth aspect of the present invention.

 FIG. 21 is an explanatory diagram of a configuration example in which three or more coil springs are arranged in parallel.

[FIG. 22] (a) and (b) are configured so that the width (pitch width) of the opening is changed so that optical devices having different thicknesses and shapes can be held by using the coil spring having the same configuration. It is a figure which shows an example.

 [FIG. 23] (a) and (b) are diagrams illustrating a configuration example in which an optical device held by a coil spring is vacuum-packed.

 FIG. 24 (a) is a cross-sectional view of an optical device packaging case according to an embodiment of the seventh invention.

(B) is an exploded assembly sectional view.

FIG. 25 is a perspective view showing an example of the upper surface structure of the lower tray.

 [FIG. 26] (a), (b) and (c) are structural views showing a first embodiment of a packing case according to the eighth aspect of the present invention.

 FIGS. 27A and 27B are structural views showing a second embodiment of the packaging case according to the eighth aspect of the present invention. FIGS.

 28 (a) and 28 (b) are structural views showing a third embodiment of the packing case according to the eighth aspect of the present invention.

 FIGS. 29 (a) and 29 (b) are structural views showing a fourth embodiment of the packing case according to the eighth aspect of the present invention.

 30 (a) and 30 (b) are structural views showing a fifth embodiment of the packing case according to the eighth aspect of the present invention.

 FIGS. 31 (a) and 31 (b) are structural views showing a sixth embodiment of the packing case according to the eighth aspect of the present invention.

[FIG. 32] (a) and (b) are structures showing a seventh embodiment of the packing case according to the eighth aspect of the present invention. FIG.

 [FIG. 33] (a) and (b) are structural views showing an eighth embodiment of the packing case according to the eighth aspect of the present invention.

 FIGS. 34 (a) and (b) are structural views showing a ninth embodiment of the packing case according to the eighth aspect of the present invention.

 FIG. 35 is a cross-sectional view showing the structure of a conventional optical device packaging case.

 FIG. 36 is a plan view of a frame member used in a conventional optical device packaging case.

 FIG. 37 is an explanatory diagram of a structural example showing a configuration of an example of a conventional packaging case for an optical device.

 FIG. 38 (a) (b) and (c) are explanatory diagrams of a conventional example.

 FIG. 39 is a cross-sectional view of a conventional optical device packaging case.

 FIG. 40 is an external view showing a configuration of a conventional optical device packaging case.

 FIG. 41 is an external view showing a configuration of a conventional optical device packaging case.

 FIG. 42 is an external view showing a configuration of a conventional optical device packaging case.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Optical device, 2 ... Frame member, 3 ... Adhesive sheet, 4 ... Bottom plate member, 5 ... Adhesive sheet, 6 ... Lid member, 7 ... Locking part, 8 ... Through-hole, 11 ... Frame member, 12 ... Bottom member, 12a ... Locked part, 13 ... Lid member, 14 ... Adhesive sheet, 15 ... Translucent member, 16 ... Case for translucent member, 17 ... Through hole , 22 ... Packing case body, 23 ... Recess, 24 ... Fixing tape, 25 ... Optical device, 26 ... Lid, 27 ... Packing case, 28 ... Optical device, 29 ... General purpose tray, 30 ... Top cover, 31 ... Bottom plate, 32 ... Window, 33 ... Adhesive tape, 34 ... Substrate for tray, 36 ... Adhesive tape, 37 ... Optical device, 40 ... Packing case, 51 ... Packing case for optical device, 52 ... Lower case, 53 ... Recess, 54 ... Inner wall, 54a ... Inner side wall, 54b ... Bottom wall, 55 ... Adhesive layer, 60 ... · Upper case, 70 ··· Optical device, 70a… Optical film, 81 ··· Optical Vise packing case, 82 ··· Tray, 82a --- Upper surface, 83 ··· Lower convex portion, 83a ··· Small protrusion, 84 ··· Cushion member, 85 ··· Lower adhesive layer, 86 ··· · Adhesive layer, 90… lid member, 90a… Ceiling surface, 91 ··· Upper convex portion, 92 ··· Cushion member, 93 ··· Adhesive layer, 94 ··· Adhesive layer, 100 ··· Optical device, 100a ··· Non Optical surface, 100c ... Front and back surfaces, 101 ... Packing case, 102 ... Case, 103 ... Lower case, 104 ... Upper case, 105 ... Bottom plate, 106 ... Frame, 106a ... Wall, 110 ... Adhesive layer, 110 、 ... Adhesive layer, 110a ... Adhesive layer, llOb --- Adhesive layer, 110c ... Adhesive layer, 111 ... Aligning means, 112 ... Bellows Sheet, 112 ··· Jaraba sheet, 112A… Opening portion, 112A… Result opening portion, 112Β ··· Opening portion, 112a… Locked portion, 1 15 ··· Adhesive layer, 121 ··· Packing case, 122 ······························································································································· 131 ················· IJ means, 132 ··· = 3 Inlet spring, 132 ··· = 3 Inlet spring, 132−Open 咅 ^ 132a --- Locked part, 133 ··· Line member ················································· 151 ········································································· · Upper elastic body, 156 ... Lower tray body, 157 ... Lower elastic body, 158 ... Elastic member, 15 9 ... Lid member, 160 ... Stepped portion, 161 ... Recess, 162 ... Recessed portion, 163 ... Stepped portion, 180 ... Packing case body, 181 ... Gel, 182 ... Optical device, 182 ... Optical device, 182a ... Optical device, 182b ... Optical device, 183 ... Lid, 184 ... Retaining material, 184a ... Retaining material, 184b ... Retaining material, 185 ... Packing case body, 186 ... Plate, 187 ... Lid, 188a ... Lower plate, 188b ... Upper plate, 189 ... Packing case body, 190 ... Lid, 191 ... Packing case body, 192 ... Guide, 193 ... · Lid, 194 ... Gel, 195 ··· Packing case body, 196 ··· Recess, 197 ··· Lid, 198 ··· Gel, 199 ··· Packing case body, 200 "Gel.

Claims

The scope of the claims

 [1] A bottom plate member having an adhesive sheet disposed on the upper surface, an annular frame member placed on the upper surface of the bottom plate member, a concave portion having an open bottom surface, and another adhesive on the ceiling surface of the concave portion And a cap-shaped lid member that covers the bottom plate member in a state of surrounding the frame member and has a configuration in which a sheet is attached, and an in-frame dimension of the frame member is When the optical device is accommodated in the frame, both end surfaces in the width direction of the optical device are set to be supported by both wall surfaces in the frame, and are exposed in the frame of the frame member. When the cap-shaped lid member is covered with the optical device placed on the pressure-sensitive adhesive sheet disposed on the top surface of the bottom plate member, the other end where the upper end of the optical device is disposed on the inner top surface of the cap-shaped lid member. Configured to abut against adhesive sheet A packaging case for an optical device.

 2. The packaging case for an optical device according to claim 1, wherein a peripheral edge portion of the bottom plate member is configured to be fitted to an opening end portion of the cap-shaped lid member.

 [3] The optical device according to [1], wherein a peripheral edge portion of the bottom plate member and a peripheral edge portion of the frame member are configured to be fitted to an opening end portion of the cap-shaped lid member. Packing case.

 [4] A method of accommodating an optical device in the optical device packaging case according to any one of claims 1 to 3,

 Placing a jig having a through-hole corresponding to the optical device housed above the frame member;

 Inserting the optical device into the through-hole of the jig and bonding the lower end of the optical device to the adhesive sheet on the upper surface of the bottom plate member; and

 Removing the jig;

 The cap member is covered with an upward force so that the bottom plate member or the frame member is fitted with the lower end of the cap lid member, and the upper end of the optical device is placed on the other adhesive sheet on the ceiling surface of the cap lid member. An optical device packaging method comprising: a step of bonding.

[5] A tray member having a hollow portion for housing the optical device, and a lower surface of the tray member In an optical device packaging case comprising a bottom plate covering a side opening and an upper lid covering an upper surface side opening of the tray member,

 The hollow portion is a through-hole penetrating the central portion of the tray member from the upper surface to the lower surface, and at least two pieces are provided at a predetermined interval on the lower surface of the tray member so that the adhesive surface is exposed in the hollow portion. A packaging case for optical devices, characterized in that it has a configuration with an adhesive tape attached.

 6. The optical device according to claim 5, wherein the interval between the adhesive tapes is set wider than the effective diameter of the optical surface of the optical device and narrower than the outer dimension of the optical device. Packing case.

 [7] The tray member is structured to be stacked in a plurality of stages, and the bottom surface opening of the bottom tray member is covered with a bottom plate while the tray member is stacked, and the top surface opening of the top tray member is covered with an upper lid. The optical device packaging case according to claim 5 or 6,

[8] In a packaging case for an optical device, comprising: a lower case having a recess on the upper surface for holding a flat optical component in a flat state; and an upper case covering the upper surface of the lower case. The inner wall is a concave curved surface including an arc shape or an elliptical arc shape in the longitudinal section, and is configured such that the distance between the facing inner walls gradually decreases as the force is directed downward. Case.

9. The optical device packaging case according to claim 8, wherein an adhesive layer is provided on the opposing inner wall surfaces of the recess.

10. The optical device packaging case according to claim 8, wherein a planar shape of the recess is a rectangle.

[11] An optical device packaging case containing a plurality of optical devices as polyhedrons in which at least two non-optical surfaces face each other in parallel, a tray on which the optical devices are placed on an upper surface, A lid member enclosing a space including the optical device on the tray,

The upper surface of the tray is provided with at least one long lower convex portion that supports the center of the bottom surface of each optical device in a state where the plurality of optical devices are arranged in a row. The upper part of the unit is provided with a lower elastic adhesive member that adheres to the bottom of each optical device.

 The ceiling surface of the lid member includes at least one long upper convex portion that supports the center of the upper surface of each optical device, and an upper elastic adhesive member that adheres to the upper surface of each optical device on the lower surface of the upper convex portion. Provided,

 The optical device packaging case, wherein an adhesive force of the lower elastic adhesive member is set stronger than an adhesive force of the upper elastic adhesive member.

 [12] By making the total adhesive area of the lower elastic adhesive member larger than the total adhesive area of the upper elastic adhesive member, the adhesive force of the lower elastic adhesive member is changed to the adhesive force of the upper elastic adhesive member. 12. The optical device packaging case according to claim 11, wherein the optical device packaging case is set stronger.

 [13] The adhesive force of the lower elastic adhesive member is set stronger than the adhesive force of the upper elastic adhesive member by making the number of the lower convex portions larger than the number of the upper convex portions. The optical device packaging case according to claim 11.

 [14] An optical device packaging case for storing a plurality of optical devices as polyhedrons in which at least two non-optical surfaces face each other in parallel, a tray on which the optical devices are placed on an upper surface, A lid member enclosing a space including the optical device on the tray, and at least one of the plurality of the optical devices arranged in a row on the upper surface of the tray to support a central portion of the bottom surface of each optical device. In the one provided with a long lower convex part and a lower elastic adhesive member that is disposed on the upper surface of the lower convex part and adheres to the lower surface of each optical device

 A packaging case for an optical device, comprising: at least one elongated upper convex portion that supports a central portion of an upper surface of each optical device on a ceiling surface of the lid member.

[15] In a packaging case for an optical device, comprising: an array means for arranging a plurality of optical devices in series at a predetermined pitch in parallel;

As the arrangement means, a plurality of bellows sheets standing in parallel on the bottom surface of the case with a predetermined interval in the width direction are used, and both end edges of the optical device are inserted and held in the open portions of the respective bellows sheets. Optical device packaging case, characterized in that Source.

 16. The packaging case for an optical device according to claim 15, wherein both ends of the bellows sheet in the longitudinal direction are supported by both opposing inner walls of the case.

 17. The packaging case for an optical device according to claim 15 or 16, wherein the bellows sheet has a bottom side adhered to an inner bottom surface of the case.

 18. The optical device packaging case according to claim 15, 16 or 17, wherein an edge of the optical device is adhered and held by an adhesive layer provided on an inner wall of an open portion of the bellows sheet.

 [19] In a packaging case for an optical device, comprising: an array means for arranging a plurality of optical devices in series at a predetermined pitch; and a case holding the array means.

 As the arrangement means, two coil springs arranged in parallel with a predetermined interval in the width direction are used, and both end edges of the optical device are inserted into a gap formed between the pitches of the coil springs to be elastic. A packaging case for optical devices, characterized in that it is configured to be held in a mechanical manner.

 20. The packaging case for an optical device according to claim 19, wherein the end surface of the coil spring has a circular shape, an arc shape, an elliptical shape, or a polygonal shape.

 21. The optical device packaging case according to claim 19 or 20, wherein the case includes pitch adjusting means for setting a pitch width of the coil spring at an arbitrary interval.

 22. The packaging case for an optical device according to claim 21, wherein the pitch adjusting means is means for expanding both ends of the coil spring to support the pitch width.

23. The optical device packaging case according to claim 21, wherein the pitch adjusting means is a winding means for winding up an end portion in the longitudinal direction of the coil spring.

24. The optical device packaging case according to claim 19, wherein the plurality of coil springs and the plurality of optical devices held by the coil springs are vacuum-sealed in a bag. .

[25] A lower tray having a first recess for accommodating an optical device on an upper surface; An optical device packaging case for storing an optical device between an upper tray having a second recess provided on the lower surface at a position corresponding to the recess of

 An optical device packaging case, wherein an elastic member and a lid member are arranged in a gap between an inner bottom surface of the second recess and an upper surface of the optical device.

[26] A lower tray having step portions for holding the four corners of the rectangular optical device on the upper surface, and a recess on the lower surface at a position corresponding to the rectangular optical device held on the first step portion. An optical device packaging case for storing an optical device between the upper tray and an elastic member and a lid member arranged in a gap between the inner bottom surface of the recess and the upper surface of the rectangular optical device. Packaging case for optical devices.

27. The optical device packaging case according to claim 26, wherein protrusions that contact the four corners of the optical device are formed on the surface of the lid member on the optical device side.

[28] The optical device packaging case according to any one of [25] to [27], wherein the elastic member is a double-sided adhesive member.

[29] The optical device packaging case according to any one of [25] to [28], wherein the thickness of the elastic member can be selected according to the thickness of the optical device.

30. The optical device packaging case according to any one of claims 25 to 29, wherein the thickness of the lid member can be selected according to the thickness of the optical device.

[31] a packing case for storing an optical device,

 A plurality of dotted gels are arranged at predetermined intervals on the inner bottom surface of the box-shaped packing case body, and the optical devices are vertically placed on the surfaces of the respective gels so as to be self-supporting. A packaging case for an optical device, wherein a lid having a holding material at a position corresponding to is put on the packaging case main body, and the plurality of optical devices are held by the holding material.

[32] a packing case for storing an optical device,

A plurality of dotted gels are arranged at predetermined intervals on the inner bottom surface of the box-shaped packing case body, and the optical devices are vertically placed on the surfaces of the respective gels so as to be self-supporting. A partition plate having a holding member provided at a position corresponding to the optical device. The optical device is held by the holding material, and a plurality of dotted gels are arranged at predetermined intervals on the upper surface of the partition plate, and the optical device is vertically placed on the surface of each gel to be fixed independently. And a cover having a holding material provided at a position corresponding to the plurality of optical devices fixed and self-supporting is placed on the packing case body, and the plurality of optical devices are held by the holding material. Packaging case for optical devices.

 [33] a packing case for storing an optical device,

 An optical device is vertically placed on each of the gels on the lower plate in which a plurality of point-like gels are arranged at a predetermined interval so as to be fixed independently, and a holding material is provided at a position corresponding to each of the plurality of optical devices fixed and self-supported. A packaging case for optical devices, wherein each optical device sandwiched and held by a provided upper plate is housed in a box-shaped packaging case body and covered with a lid.

 [34] A guide for preventing the optical device from falling down is provided between the optical surfaces of the plurality of optical devices that are vertically fixed and fixed independently, extending in parallel to the optical surface of the optical device from the inner surface of the packing case. 34. A packaging case for an optical device according to any one of claims 31 to 33.

 [35] In the packing case, the gel is arranged in a band shape with a predetermined width, and a plurality of optical devices are fixed and self-supported on the gel at predetermined intervals. The optical device packaging case described in any one of 34.

 [36] A packaging case for storing an optical device,

 A plurality of concave portions having a predetermined shape are provided in a strip shape on the inner bottom surface of the box-shaped packing case body, dot-like gels are arranged in the concave portions, and an optical device is vertically placed on the surface of the gel so as to be self-supporting, An optical device characterized in that a lid having a holding material provided at a position corresponding to the plurality of optical devices fixed and self-supported is placed on the packing case body, and the plurality of optical devices are held by the holding material. Device packaging case.

 [37] A packaging case for storing an optical device,

Two or more point-like gels are arranged at predetermined positions on the inner bottom surface of the box-shaped packing case body at intervals corresponding to both corners of the bottom surface of the optical device to be self-supported, and the optical surfaces of each pair of gels are optically arranged. The device is fixedly self-supported, and a lid having a holding material provided at a position corresponding to the optical device fixed and self-supported is placed on the packing case body, and the plurality of optical devices are mounted. A packaging case for an optical device, wherein a chair is held by the holding material.

 [38] a packing case for storing an optical device,

 On the inner bottom surface of the box-shaped packing case body, four gels are arranged in a dotted pattern at positions corresponding to the four corners of a plurality of optical devices to be laid flat, and the optical devices are fixed to the surface of each gel and covered. A packaging case for optical devices, characterized by being covered.

[39] a packing case for storing an optical device,

 A plurality of triangular tapered portions are provided at predetermined intervals on the inner bottom surface of the box-shaped packing case body, and the gel is placed at positions corresponding to the four corners of the optical device when placed flat across the two tapered portions. A packaging case for optical devices, which is arranged in four spots in a dotted manner, wherein a plurality of optical devices are mounted flat on the surface of the gel, and a lid is placed on the packaging case body,