DE102011086628A1 - Tubular LED lamp - Google Patents

Abstract

The present invention presents a plastic carrier 1 for holding one or more LED modules 1 within an illumination tube 3. The plastic carrier 1 comprises at least one bendable part 4 which is adapted to hold the plastic carrier 1 within the illumination tube 3 in that it is biased and thus presses against the inner wall of the lighting tube 3. The bendable part 4 may consist of one or more bendable arms 4a, 4b. The plastic carrier is further provided with a snap-fit connector at each of its ends 12, 12b to assist in longitudinal connection of a plurality of plastic carriers 1.

Description

The present invention relates to a tubular LED lamp and a corresponding manufacturing method thereof. The present invention also relates to individual components of the tubular LED lamp, namely a plastic support for holding one or more LED modules within an illumination tube of the tubular LED lamp and an end seal for sealing one end of the illumination tube of the tubular LED lamp ,

Tubular or linear LED lamps are known in the art. Many tubular LED lamps have a design for retrofit or retrofit and are designed to replace known gas discharge lamps. To this end, tubular LED lamps include lighting tubes into which lighting devices or LED modules, typically including an elongated printed circuit board, PCB, having a plurality of LEDs are employed.

To accommodate one or more LED modules in the lighting tube, two solutions are usually used in the prior art. The first solution accommodates LED modules in a lighting tube in which the LED modules comprise low power LEDs and where there is no provision for heat transfer or for robust mechanical fixing of the LED modules to the illumination tube. The second solution fixes LED modules to a metal, such as aluminum, a heat sink, which is itself glued to the lighting tube.

For example disclosed US 2002/0047516 A1 a fluorescent tube formed by a tubular fluorescent body made of a fluorescent glass coated transparent glass and having an ultraviolet LED substrate inserted into the tubular body. The LED substrate is attached to teflon plugs at both ends of the lighting tube by means of support holes and suspension cables. US 2011/0038147 A1 discloses a mounting arrangement for an LED lamp. A plurality of LEDs are mounted on a substrate. The substrate is fastened to the tube of the LED lamp by fasteners.

The document WO 2011/064305 A1 discloses a rectilinear lamp having a tubular bulb of glass wherein a plurality of LEDs are mounted on a printed circuit board or PCB which is inserted in the bulb. The PCB may be made of a material such as aluminum or ceramic to provide a heat sink. The PCB is melted in the glass during the manufacturing process. WO 2011/121145 A1 discloses an LED tube containing a body made of a highly thermally conductive extruded material in the form of a tube. The tube has a hole for receiving at least one LED mounted on a PCB. The PCB is attached by means of fasteners through holes in the pipe.

The problem with the first prior art solution is its reliability because there is no provision for adequate heat transfer and stable mechanical attachment. The solution can further support only a limited diameter of illumination tubes and thus a limited light output. This is due to the fact that the smaller the pipe diameter is designed, the better the thermal conductivity within the pipe and that of course a certain amount of thermal conductivity is to be provided. The problem with the second solution is that the manufacture of these lamps is difficult and that the contact surfaces of aluminum and glass to the first are difficult to construct and, secondly, hardly form a thermal interface that adapts the different coefficients of thermal expansion of the materials.

The present invention has therefore been made to improve the prior art. In particular, one or more of the above-mentioned problems are to be overcome. Generally, the object of the invention is to provide an improved tubular LED lamp that can replace known gas discharge lamps in terms of both mechanical connections and optical properties. In particular, the present invention seeks to form a tubular LED lamp with improved optical and thermal properties and improved stability. Another object of the present invention is to provide a tubular LED lamp which can be easily manufactured and can easily produce tubular LED lamps of various lengths.

The above-mentioned problems are solved by the present invention according to the attached independent claims. The appended dependent claims further develop or develop the inventive concept of the present invention by providing additional advantageous features.

The present invention relates to a plastic carrier for holding one or a plurality of LED modules within an illumination tube, wherein the plastic carrier comprises at least one bendable part which is adapted to hold the plastic carrier within the illumination tube in that it is biased and thus presses against the inner wall of the illumination tube.

The plastic carrier need not be glued or otherwise attached to the lighting tube as by separate fasteners. Rather, the plastic carrier is held by friction with or on the lighting tube. The plastic carrier is partially deformed when inserted into the lighting tube. Due to the elasticity of at least the bendable parts of the plastic carrier, an elastic force similar to a spring force of a prestressed spring will press at least the bendable parts of the plastic carrier against the inner wall of the lighting tube. The plastic carrier can thus be clamped within the lighting tube.

The plastic carrier can be easily inserted and removed from the lighting tube. The manufacture and maintenance of the tubular LED lamp is thus easier. The plastic carrier is also used to transfer heat generated by the LED modules to the wall of the lighting tube. No separate heat sink, such as a heat sink made of aluminum, is required. Since there is no glue joint or any other expensive connection between the plastic carrier and the lighting tube, there is a wide range of compensation for different thermal properties between the material of the lighting tube and the material of the plastic carrier. The material of the lighting tube is preferably glass and optionally plastic.

Preferably, the plastic carrier has an approximately semi-cylindrical shape with a first end side, a second end side, a planar corner surface and a semicircular bottom surface.

The semicircular bottom surface of the plastic carrier is preferably designed so that it fits at least partially to the radius or the curvature of the illumination tube into which the plastic carrier is to be inserted. The semicircular bottom surface then has a large contact surface with the lighting tube when inserted, resulting in better heat transfer. The plastic carrier can therefore act efficiently as a plastic heat sink.

The end faces of the plastic carrier may provide electrical contacts which are connected to the LED modules. Electrical contacts for the LED modules are preferably provided at both opposite ends of the plastic carrier.

Preferably, the bendable member includes a plurality of bendable arms extending on opposite sides of the planar top surface, which extend approximately perpendicular to the planar top surface and which extend in tangential continuation of the semicircular bottom surface.

The bendable arms may be biased in the lighting tube prior to attaching the plastic carrier. Due to their elasticity, the bendable arms will then press against the inner wall of the lighting tube when they are inserted. The bendable arms are designed to approximately continue the curvature of the circular bottom surface approximately perpendicular to the top surface due to the semi-cylindrical shape of the plastic carrier.

A plurality of bendable arms may be provided on each side of the flat top surface, wherein a distance between the individual bendable arms is the same or varies. A plurality of bendable arms are capable of providing a high frictional force to stably hold the plastic carrier within the lighting tube. The bendable arms may be straight or curved. If they are curved, the radius should be greater than that of the illumination tube into which the plastic carrier is inserted. In order to adjust the curvature of the bendable arms to the radius of the inner wall of the lighting tube, the bendable arms must necessarily be biased. The bendable arms also provide heat transfer from the plastic carrier to the lighting tube and may even act as heat fins that efficiently transfer heat to solid material surrounding the air or arms.

Preferably, the bendable arms are designed so that their pressing against the inner wall of the lighting tube results in a force urging the semicircular bottom surface against the inner wall of the lighting tube.

Since the semicircular bottom surface is pressed against the inner wall of the lighting tube, the contact area with the lighting tube is increased and improved, and therefore better heat transfer can take place. Furthermore, the frictional force between the plastic carrier and the lighting tube increases, so that the plastic carrier is held even more stable within the lighting tube.

Preferably, the plastic carrier has a first end face, a second end face, a top face, and a bottom face, wherein the bendable means are a plurality of curved bendable arms extending from opposite sides of the bottom face extend.

In this alternative embodiment for the plastic carrier, the bendable arms extend away from the top surface of the plastic carrier on which the LED modules are mounted. The curvature of the bendable arms is or are chosen so that they can be biased to accommodate the curvature of the illumination tube into which the plastic carrier is to be inserted. Then, the bendable arms within the lighting tube will press against the inner wall of the lighting tube.

Since the bendable arms in this embodiment extend from the opposite surface from the surface where the LED modules are mounted, the LED modules will be located closer to the inner wall of the lighting tube when inserted with the plastic carrier. A volume or cavity between the LED modules and the inner wall of the lighting tube can thus be drastically reduced. The cavity in question is preferably filled with a matrix or embedding material, as will be explained later. Due to the reduction in the volume of the cavity to be filled with potting material, the manufacturing process can be made more cost effective. In addition, the light generated by a tubular lamp having such a structure can be made brighter.

Preferably, the number and position of the plurality of bendable arms are selected so that there is no resulting torsion of the plastic carrier when held by the bendable arms in an illumination tube.

For example, the same number of bendable arms may be provided on each side of the top surface. Further, if the elasticity of each bendable arm is identical, no torsion of the plastic carrier will result when inserted into the lighting tube. However, other configurations are possible and can be selected carefully. The forces exerted by each of the bendable arms pressing against the inner wall of the lighting tube must be compensated. In particular, a balance between each side of the top surface and a compensation along the length of the plastic carrier are desired. The result is increased stability of the plastic carrier within the lighting tube.

Preferably, the plastic carrier comprises a mounting portion on the top surface adapted to receive and retain the one or more LED modules.

The attachment part can mechanically hold and fix one or more LED modules. For example, a snap or snap connection may be provided. In addition, projections may be provided, under which one or more LED modules can be clamped. With such constructions, it is not necessary to adhere the LED modules to the plastic carrier, thereby achieving a simpler manufacturing process and better thermal properties.

Preferably, the plastic carrier has a thermal conductivity of 0.1 W / mK to 20 W / mK.

The plastic carrier can thus act well as a heat sink and reduce heat, such as replacing aluminum profiles used in the prior art.

Preferably, the plastic carrier consists of a highly reflective material or of an at least partially transparent material.

If the plastic carrier is made of a highly reflective material, it may form an optical cavity or, for example, a parabolic mirror for an ideal color and light distribution of the tubular LED lamp. With or in the case of the partially transparent plastic carrier, a light distribution can take place in all directions.

Preferably, the plastic carrier comprises at least one color conversion material.

By means of the color conversion material, different colors of the light emitted from the tubular LED lamp can be selected. White light can be generated, for example, by using blue LEDs for the LED modules and by using a color conversion material which adds a separate spectral wavelength (preferably yellow) to the blue LED light so that the total emission is perceived as white light.

Preferably, the plastic carrier comprises a first snap connector extending from the first end side and a second snap connector extending from the second end side wherein the first snap connector and the second snap connector are shaped to be adapted to engage a second snap connector or a first snap connector of another plastic carrier, respectively.

Due to the construction of the snap connectors, a plurality of plastic carriers can be connected in a longitudinal direction to produce longer lamps. Typical lengths of individual plastic carriers that can be connected together are 30 to 40 cm. By connecting several subunits, that is several plastic carriers, the lengths of tubular LED lamps can be varied (of course, lighting tubes of different lengths are to be selected). The snap connector also provides a simple mechanism that does not require gluing or similar attachment.

Preferably, the first snap connector and the second snap connector are configured to prevent twisting of the plastic carrier relative to another engaged plastic carrier.

For example, the snap-fit connector may be composed of a plurality of parts engaged with a plurality of parts of another and another snap-in connector, respectively. The engagement should be releasable by applying only sufficient force to the plastic carriers along the length of the tubular LED lamp, but not by twisting the plastic carriers. Two plastic supports connected together should not be able to rotate with respect to each other about their respective longitudinal axis at all. Twisting adjacent plastic substrates (subunits) would also twist the LED modules and result in degraded optical properties of the entire tubular LED lamp.

The present invention is further directed to a tubular lamp comprising at least one lighting tube, at least one plastic support as described above, which is held by the bendable device within the at least one lighting tube, and one or more LED modules on or attached to the plastic carrier.

The tubular LED lamp can replace known gas discharge lamps and be easily formed with or in different lengths. The plastic carrier does not need to be glued or otherwise secured in the lighting tube. Therefore, the lamp can be assembled faster. The tubular LED lamp has good thermal properties because the plastic carrier serves to transfer heat from the LED modules to the illumination tube, that is, it acts as a heat sink.

Preferably, the lighting tube made of glass or plastic.

Preferably, the tubular lamp comprises a plurality of plastic carriers, which are interconnected by respective engagement of a first snap connector of a plastic carrier with or in a second snap connector of another plastic carrier.

The tubular lamp can thus be easily varied in length by inserting a desired number of plastic carriers which are interconnected by the snap connectors into an illumination tube of desired length.

The present invention is directed to an end seal for sealing a lighting tube and for connecting to a plastic carrier within the lighting tube, wherein the end seal comprises a cylindrical body having a first end and a second end and a snap-in connector attached to the first end is provided to engage with or in a snap connector, which is provided at one end of the plastic carrier.

The end seals can be easily attached to one or more plastic supports within the lighting tube by the snap connector. There is no need for their sticking or screwing to the lighting tube. If the plastic carrier is to be removed from the lighting tube for replacement or maintenance of the LED modules, the snap connection can be quickly released.

Preferably, the base body and / or the snap connector are made of plastic.

Preferably, the diameter of at least a part of the cylindrical base body is chosen so that it fits to the inner diameter of the illumination tube, which is to be sealed.

Preferably, the cylindrical body comprises a part of increased diameter at the second end.

The cylindrical body of the end seal can slide into the illumination tube until the end of the illumination tube is sealed by the enlarged diameter portion.

Preferably, the enlarged diameter part is provided with a first through hole and at least one second through hole.

The first through hole may be used to inject a sealing material through the enlarged diameter portion into the lighting tube where it acts as a seal and adhesive for the end seal. The air, which is necessarily replaced by the sealing material, is discharged through the second through hole.

Preferably, the at least one second through-hole has a smaller diameter than the first through-hole.

Due to the smaller diameter of the second through-hole, after all the air is replaced by the injected sealing material and after the sealing material starts to leak through the second through-hole, it or the sealing material becomes solid in the second through-hole due to its viscosity.

Preferably, the cylindrical base body comprises a part of reduced diameter in its central portion.

The reduced diameter portion in the central portion of the body acts as a sealing space with the inner wall of the lighting tube. The seal space fills with sealant material when injected.

Preferably, the body comprises an elongated groove extending along at least a portion of the body, wherein the elongated groove is aligned to continue the first through hole to the enlarged diameter portion.

The elongate groove is provided to more evenly distribute the injected sealing material in the seal space.

Preferably, the base body is provided with an annular groove for receiving an O-ring.

If an O-ring is aligned in the groove of the seal space defined by the reduced diameter portion in the central portion of the body, the seal space is even more tightly sealed to the inside of the illumination tube where the plastic carrier and the LED substrate are sealed. Modules are located.

Preferably, the end seal comprises a guide channel extending from the first end to the second end through the entire body.

The guide channel can be used to fill the inside of the illumination tube, that is to say the cavity between the plastic carrier or the LED modules and the illumination tube, with a matrix material, for example with a material containing a phosphor. The guide channel is preferably a channel which extends straight from the first end to the second end of the base body. The diameter of the guide channel should be large enough to allow efficient injection of viscous matrix material.

Preferably, electrical connections for the LED modules extend through the base body.

The LED modules inside the lighting tube 3 a tubular LED lamp can then be easily contacted from the outside.

The present invention further relates to a tubular lamp, comprising at least one lighting tube, at least one plastic carrier within the at least one lighting tube, wherein the plastic carrier is provided at each of its ends with a snap connector, wherein one or more LED modules on or on the Plastic carriers are mounted and wherein two end seals, as described above, are provided, wherein the snap connector of each end seal is releasably engaged with the snap connectors of the plastic carrier in engagement.

The tubular lamp can be easily assembled and disassembled without screws.

Preferably, cavities within the illumination tube between the LED modules or the plastic carrier and the inner wall of the illumination tube are or are filled with a matrix material.

In this way, the lamp is efficiently sealed against dust and dirt entering the lighting tube. The service life can thus be extended. Furthermore, the matrix material in the illumination tube can improve the optical properties of the LED lamp. The matrix material may change the emitted wavelength and may assist, for example, in generating white light.

Preferably, the matrix material comprises a silicone material.

Preferably, the matrix material comprises one or more phosphors.

The present invention further relates to a manufacturing method of a tubular lamp, the method comprising the steps of attaching at least one or more LED modules to a plastic carrier, inserting the plastic carrier into a lighting tube, connecting an end seal with at each end of the plastic carrier to seal the illumination tube, injecting a matrix material through a conduit through at least one of the end seals to fill voids between the one or more LED modules and the inner wall of the illumination tube.

By filling the cavities between the LED modules and the illumination tube with a matrix material, the mechanical and optical properties of the tubular lamp can be changed or improved. The filling can take place even after the lamp has been mounted. The matrix material may, on the one hand, act as an adhesive which bonds the plastic carriers and the LED modules together, and on the other hand, it may act as an optical medium which trims the optical properties.

Preferably, the insertion or insertion of the plastic carrier comprises a deformation of at least a part of the plastic carrier so that it is biased and thus presses against the inner wall of the lighting tube.

By biasing the plastic carrier before or during its insertion into the lighting tube of the deformed part of the plastic carrier is a spring force, which arises due to its elasticity, exert on the inner wall of the lighting tube. Therefore, the plastic carrier is held by frictional forces within the lighting tube. The matrix material may further act as an adhesive. No screws or similar fasteners are required.

Preferably, the matrix material contains one or more phosphors.

With the matrix material containing one or more phosphors, the spectral characteristics of the lamp can be tailored. For example, white light can be achieved. Therefore, the LED modules could emit blue light, and the phosphor particles in the matrix material, when excited by the blue light, add another wavelength (such as yellow) to the light, so that the perceived total light of the lamp in the white area of the light spectrum lies.

Preferably, the method further comprises, prior to injecting the matrix material, a step of coating an inner wall of the lighting tube with a material comprising at least one phosphor.

The coating material may additionally influence the optical properties of the tubular lamp. For example, a color conversion or a light dispersion can be achieved.

Preferably, the method further comprises, prior to injecting the matrix material, a step of injecting a filler material to selectively coat an inner wall of the lighting tube.

In this way, two layers of two different materials may be provided to be located between the LED modules and the inner wall of the lighting tube. More flexibility is achieved when the optical properties of the tubular lamp are tailored.

Preferably, the method further comprises a step of injecting a sealing material through a first through-hole of each of the end seals to respectively fill a sealing space between the end seals and the inner wall of the lighting tube.

The sealing material may fill the sealing space and adhere the end seals and the lamp to the inner walls of the lighting tube. The inside of the lighting tube, where the LED modules are located, is then well protected against or against dust and dirt.

Preferably, the sealing material comprises a silicone material. Silicone material is cheap and a good working gasket material.

Preferably, the method further comprises a step of positioning the lighting tube in an upright orientation for the steps of injecting the matrix material and / or the sealing material.

Preferably, the injected matrix material and the sealing material glue the plastic carrier or the end seals to the illumination tube.

The mechanical stability of the tubular lamp can thus be improved. In addition, the temperature properties can be improved so that the heat is now additionally transferred via the injected matrix material from the LED modules to the illumination tube can be. The matrix material may act as an additional heat sink with a large surface area for the plastic carrier. The matrix material also protects the LED modules.

Preferably, in the injection step of the sealing material, air is discharged through at least a second through-hole of the at least one of the end connectors.

The removal of air allows for improved sealing without any air bubbles being trapped in the sealing material. The stability is thus increased and the likelihood of deterioration of the sealing material over time is reduced.

Preferably, the diameter of the second through-hole is smaller than the diameter of the first through-hole so that the sealing material is prevented from leaking through the second through-hole. The sealing material will automatically seal the second through hole.

Preferably, the method further comprises a step of applying a ball attachment to the one or more LED modules after attaching the one or more LED modules to the plastic carrier.

A transparent ball attachment material provides the advantage that the injected matrix material is easily spaced from the light (and heat) generating surface of the LED chips on the LED modules. Thus, the requirements as to the temperature stability of the matrix material or the phosphors within the matrix material can be lowered. Silicone can be used as matrix material. The one or more phosphors additionally tailor the optical properties of the tubular lamp.

Preferably, the ball studs or spherical attachments are formed by dispensing a transparent material, which preferably contains one or more phosphors.

Preferably, in the mounting step, the one or more LED modules are mechanically attached to a mounting part of the plastic carrier.

The manufacturing process is simplified because the LED modules are not glued or soldered.

The present invention further relates to a tubular lamp obtained by the above-described manufacturing method.

The obtained tubular lamp has all the advantages described above.

In summary, the present invention provides a plastic carrier, an end seal, and a tubular lamp manufacturing method. The resulting tubular lamp has improved optical and mechanical properties, for example, in terms of stability and desired light. The tubular lamp can be more easily manufactured than commonly known tubular lamps.

In the following, the present invention will be explained in more detail with reference to the accompanying drawings.

1 shows a first embodiment of a plastic carrier according to the present invention.

2a and 2 B show a first embodiment of a plastic carrier according to the present invention.

3a and 3b show a first embodiment of a plastic carrier according to the present invention.

4 shows a connection of two snap connectors of a plastic carrier according to the present invention.

5a and 5b show a second embodiment of a plastic carrier according to the present invention.

6a and 6b show a first embodiment of an end seal according to the present invention.

7 shows a second embodiment of an end seal according to the present invention.

8b shows a tubular lamp designed and manufactured according to the present invention.

8a and 8c show an end seal according to the present invention in a lighting tube in a tubular lamp.

1 shows a plastic carrier 1 according to the present invention. In particular shows 1 a plastic carrier 1 according to a first embodiment. The plastic carrier 1 is or is in a lighting tube 3 for mounting a tubular lamp 20 used. The plastic carrier 1 is caused by frictional and elastic forces inside the lighting tube 3 held. The plastic carrier 1 needs on the lighting tube 3 not glued or otherwise attached (for example, by means of separate fasteners, such as screws). Responsible for that is that part of the plastic carrier 1 is bendable and before or during insertion of the plastic carrier 1 into the lighting tube 3 can be biased. The elasticity of the bendable parts 4 then acts like a preloaded spring and exerts a compressive force against the inner wall of the lighting tube 3 out. The bendable parts 4 are in 1 for example, as two prestressed arms 4a shown, which are suitable against the inner wall of the plastic pipe 3 to press.

The plastic carrier 1 is with a LED module 2 provided, which is attached to the top surface. The LED module 2 Includes one or more LEDs and generates light and heat when in use. Thus, the plastic carrier 1 designed to act as a heat sink to heat from the LED module 2 to the lighting tube 3 transferred to. The plastic carrier 1 is therefore preferably made of a conventional polymer such as polyamide, polyethylene terephthalate, polycarbonate, polyprolylene, LCP, PPS, TPE, elastomers or the like. The plastic carrier 1 can also be made of highly filled polymers to achieve better thermal conductivity. The thermal conductivity of the plastic carrier 1 is preferably in a range from 0.1 W / mK to 20 W / mK, more preferably from 1 W / mK to 20 W / mK, most preferably from 10 W / mK to 20 W / mK. The lighting tube 3 is preferably made of glass, but may optionally be made of a plastic material.

The plastic carrier 1 may be made of a highly reflective plastic material, or it may be provided with a reflective coating on its surfaces. Then the plastic carrier 1 act as an optical cavity or as a parabolic mirror to detect light passing through the LED modules 2 has been emitted, to reflect, to focus or to redirect. An optical cavity can be designed for an ideal color and light distribution of the LED modules. A deliberately conducted emission of light can be achieved. Alternatively, the plastic carrier 1 be at least partially transparent, so that light, which is distributed by the LED modules, through the plastic carrier 1 is not blocked, and it can thus be emitted in all directions.

In or in the first embodiment, the plastic carrier 1 Shaped to a first end side 6a , a second end page 6b shown at opposite ends of the semi-cylindrical plastic carrier 1 are arranged. The plastic carrier 1 also has a flat top surface 5a and a semi-circular bottom surface 7a on, like in 1 shown. The curvature or radius of the semicircular bottom surface 7a preferably matches the curvature or radius of the inner wall of the lighting tube 3 in which the plastic carrier 1 for mounting a tubular lamp 20 is to be attached.

On or on the flat top surface 5a of the plastic carrier 1 are one or more LED modules 2 appropriate. Preferably, the top surface 5a a mounting area nine , For example, a recess or a cavity in the or the LED modules 2 can be accommodated. In addition, protruding and bendable elements may be provided, among which the LED modules 2 can be clamped. Preferably, the LED modules 2 in the attachment area nine be kept stable without the use of adhesive. The LED modules 2 For example, under the above elements and / or in the mounting area nine be connected by a snap or locking connection.

2a shows how a plurality of bendable arms 4a especially in the first embodiment of the plastic carrier 1 can be provided. The majority of bendable arms 4a extends upwards and extends approximately at right angles to the flat top surface 5a , They point in one direction from the semicircular bottom surface 7a path. The bendable arms 4a extend on opposite sides of the flat top surface 5a , especially the opposite sides, not on the first end side 6a or the second end side 6b but rather the opposite sides along the longitudinal extent of the plastic carrier 1 , The longitudinal extent of the elongated tubular lighting tube 3 used plastic carrier 1 is in 2 B shown.

The bendable arms 4a extend in such a way from the top surface 5a in that they tangentially determine the curvature or the radius of the semicircular bottom surface 7a continue. The bendable arms 4a can be preloaded by them before inserting the plastic carrier 1 into the lighting tube 3 or if the plastic carrier 1 into the lighting tube 3 is used, pressed against each other. Then the bendable arms 4 in the lighting tube 3 in the direction opposite to the direction in which they were bent, that is against the inner wall of the lighting tube 3 on both sides of the flat top surface 5a Press or press. Thus, the plastic carrier 1 in the lighting tube 3 clamped, and it can be achieved a stable position.

Pressing the bendable arms 4a against the inner wall of the lighting tube 3 preferably leads to a downward force, that is, a force coming from the top surface 5a to the semicircular bottom surface 7a directed so that the semicircular bottom surface 7a against the inner side wall of the lighting tube 3 is pressed. To create such a downward force, the abutment region of the bendable arms is or is 4a with or on the inner wall of the lighting tube 3 preferably in an area above the median plane of the illumination tube 3 , This means that the bendable arms 4a against the inner walls of the lighting tube 3 Press into positions where the lighting tube 3 already tapered or tapered above the top surface. Then, a force component is not only left and right (that is, in the plane of the flat top surface 5a ), but also directed toward the ground (that is, to the ground surface 7a ). The force components press the entire plastic carrier 1 down (that is, they press the semicircular surface 7a to the inner walls of the lighting tube 3 ).

The plastic carrier 1 can also be shaped according to a second embodiment, which in 5a and 5b is shown. In or out 5a can be seen that the plastic carrier 1 has a cross section similar to a bat. The plastic carrier has namely, as in or in the first embodiment, a first end side 6a and a second end side 6b , on. The plastic carrier 1 has a top surface 5b and a floor area 7b in which or wherein the bottom surface 7b not semicircular as in the first embodiment. Bendable arms 4b extend from the bottom surface 7b in a curved manner so that their tips approach each other. The radius or curvature of the bendable arms 4a should be greater than the curvature of the lighting tube 3 , However, the bendable arms are suitable for insertion into the lighting tube 3 or, when inserted into the lighting tube, to be biased so that it curves to the curvature of the lighting tube 3 adapt and thus due to their elasticity against the inner wall of the lighting tube 3 to press. The principal mechanism is the same as described for the first embodiment.

The protrusion of the bendable arms 4b from the bottom surface 7b (instead of the top surface, as in the first embodiment) has the effect that the one or more LED modules 2 closer to the inner wall of the lighting tube 3 are arranged. A volume or space between the LED modules 2 and the lighting tube 3 is drastically reduced. This volume can be filled with a matrix material, as explained below. By reducing the volume, less material is needed.

In or in both embodiments of the plastic carrier 1 can be a plurality of bendable arms 4a . 4b be arranged in parallel, as in 2a shown. This means that along the length of the plastic carrier 1 a plurality of bendable arms 4a . 4b on both sides of the deck area 5a . 5b or the bottom surface can be arranged. A fixed or varying distance is between each tow part of the bendable arms 4a . 4b intended. In any case, the number and position of the plurality of bendable arms 4a . 4b chosen so that there is no twist on the plastic carrier 1 works when he is in the lighting tube 3 used and by pressing the bendable arms 4a . 4b against the inner wall of the lighting tube 3 is held.

As in 3a and 3b shown is the plastic carrier 1 (for both embodiments) with a snap or latching connector 8a . 8b on the first end side 6a or the second end side 6b Mistake. The snap-in or snap-in connectors 8a and 8b can be designed as plug-in or receiving parts, so that they are suitable to intervene or snap into each other or snap. For example, the plastic carrier 1 a receiving part latching connector 8a on a first end side 6a and a male latching connector 8b on the second end side 6b exhibit. The two end pages 6a . 6b However, they can also be provided with identical snap or latching connectors.

The locking connector 8a . 8b are intended to be in the longitudinal connection of two plastic carriers 1 to support. This is necessary to make longer tubular lamps, such as for mirroring the length of known gas discharge lamps. Therefore, the first snap or latch connector should 8a a first plastic carrier 1 be shaped so that it is capable of, with or in the second snap or latching connector 8b a second plastic carrier 1 intervene. For example, in 3a and 3b the first snap connector 8a as a recess, a gap or a cavity in the plastic carrier 1 near the first end side 6a designed. The second snap connector 8b For example, it is designed as two elements from the second end side 6b protruding, wherein the protruding elements are designed with hook-like tips. The hook-like tips are able to snap into the recess or gap, that is, to engage or snap into the recess from opposite sides. The protruding elements are made of plastic and elongated; so they are elastic. For snapping or locking on or in the recess are the First, the protruding elements are bent away from each other and secondly snap into the recess due to the elastic force tending to bend them back against each other.

In 4 is shown another way, corresponding snap or snap connector 8a . 8b to design. A second snap connector 8b is for a first plastic carrier 1 provided and has two protruding hook-like elements 80b and 81b on. A first snap connector 8a on a second plastic carrier 1 has a protruding element 80a which contains recessed areas which are shaped around the hook-like elements 80b and 80a the second snap connector 8b of the first plastic carrier 1 to record appropriately. The hook-like elements are again elastic and can thus be bent away and then into the recessed areas of the protruding element 80a be snapped back. The snap connectors can be designed in many ways as long as they provide a connection that is stable and requires some force to be released, such as the elastic force, around the hook-like elements 80b and 81b flex away. A snap or snap connection should prevent a plastic carrier 1 is capable of relating to a second plastic carrier 1 to twist with which he is connected. In particular, the plastic carrier should 1 through the snap connectors 8a . 8b be blocked from twisting about its longitudinal axis. The snap connectors 8a . 8b are a type of mechanical fasteners that come with the plastic carrier 1 are integrated.

A tubular lamp 20 in accordance with the present invention typically includes a lighting tube 3 and at least one plastic carrier 1 which, as explained above, by the bendable means or devices 4 inside the lighting tube 3 is held. The design of the plastic carrier 1 has also been described in detail above. One or more LED modules 2 are on the plastic carrier 1 appropriate. A tubular lamp 20 may also be a plurality of plastic carriers 1 include, through their respective snap connectors 8a . 8b , as described above, are interconnected. The length of each plastic carrier 1 is preferably in the range of 30 to 40 cm. By connecting a plurality of subunits (plastic carrier 1 ) can be longer tubular lamps 20 be assembled. Preferably, the tubular lamp comprises 20 an end seal 10 at each end of its lighting tube 3 , The end seals 10 are or serve to seal the lighting tube 3 and they are for easy connection with a plastic carrier 1 inside the lighting tube 3 designed or designed.

In 6a respectively. 6b is a first embodiment of such an end seal 10 shown. The final seal 10 consists of an approximately cylindrical body 11 with a first end 12a and a second end 12b , The cylindrical body 11 has areas of different diameters, as explained below. The main body 11 is at its first end 12a with a latch or snap connector 13 for engagement with or in a latch or snap connector 8a . 8b provided on one of the ends of a plastic carrier 1 is provided. end seals 10 can with the plastic carrier 1 at each end of the lighting tube 3 be connected and thus can provide an easily attachable seal.

The main body 11 and / or the latch or snap connector 13 are preferably made of plastic. Preferably, the material is the same material as that for the plastic carrier 1 what has been specified above is chosen. The final seal 10 should have a diameter such that it can be sealed in the lighting tube 3 can be used. Therefore, at least the first end should be 12a of the basic body 11 be the same or slightly smaller diameter than the diameter of the inner wall of the lighting tube 3 , At the second end 12b should be the end seal 10 an area 17 have enlarged diameter, so that when the first end 12a into the lighting tube 3 is used, the second end 12b the lighting tube 3 concludes.

The production of a preferred embodiment of the tubular lamp 20 includes that a sealing material and / or a matrix material in the illumination tube 3 be introduced. As in 6b shown, indicates the end seal 10 in that area 17 enlarged diameter at the second end 12b a first through hole 15a on. On the other side of the area 17 enlarged diameter sets an elongated groove 16 the channel direction of the first through hole 15a continued. The groove 16 runs along the length of the end seal 10 on the surface of the main body 11 and passes through an area 18 of reduced diameter. The first through hole 15a can be used to seal material in the tubular lamp 20 to inject after the end seal 10 is attached by their connection to the plastic carrier 1 inside the lighting tube 3 , The injected sealing material is passed through the first through hole 15a and then along the body 11 in the elongated groove 16 will flow and will fill up a sealing space passing through the area 18 reduced diameter and the inner wall of the lighting tube 3 is fixed. To the replaced air from the Sealing chamber is the end seal 10 further with at least one second through hole 15b Mistake. The second through hole 15b preferably has a diameter that is smaller than the diameter of the first through-hole 15a , The diameter of the second through-hole 15b should be chosen small enough so that air can be removed, but sealing material, such as a silicone, not through the second through hole 15b can escape. The sealing material becomes due to its viscosity within the second through hole 15b become tight and closes the channel tight.

The final seal 10 is preferably further with an annular groove 14 provided for receiving an O-ring. The annular groove follows the circumference of the body 11 , The annular groove 14 crosses the oblong groove 16 preferably at right angles. The annular groove 14 is preferably closer to the first end 12a the end seal 10 as to the area 18 provided reduced diameter. The captured O-ring acts to allow sealing material to flow toward the first end 12a to avoid if the sealing space, passing through the area 18 of the reduced diameter and the inner wall of the lighting tube 3 is set, is completely filled.

The final seal 10 further preferably comprises a pipeline 19 passing through the entire body 11 runs and the first end 12a with the second end 12b combines. The pipeline 19 is in 6b represented by a dashed line. The tubing may be used to inject a matrix material into the tubular lamp 20 be used, namely in the cavities between the plastic carrier 1 and the inner wall of the lighting tube 3 , The pipeline 19 can be a straight channel through the end seal 10 be. The channel should have a diameter large enough to allow the matrix material to be pushed through. The pipeline 19 is with the through hole 15a or the through hole 15b preferably not in connection (connection).

The final seal 10 is further provided with one or more electrical connections or connections that through the entire body 11 run. The electrical connection is or serves to connect the LED modules 2 that are inside the lighting tube 3 located, with the outside of the tubular lamp 20 if the end seal 10 the lighting tube 3 closes. The electrical connections may be wires, preferably with the main body 11 integrated or molded in this. The electrical connections can also be through the pipeline 19 run. The inner wall of the pipeline 19 could also be coated with a conductive layer to form the electrical connections.

As in 6a and 6b can be seen, the latch or snap connector 13 be made of any number of protruding elements, for example, as shown, of three protruding elements 13a . 13b . 13c wherein, for example, two of the above elements 13a . 13b are arranged parallel and have hook-shaped end portions. These elements 13a . 13b can with recording snap connector elements 8a . 8b of the plastic carrier 1 are brought into engagement, which are formed for example as recesses. As described above, the snap connector is 13 to shape it with a snap connector 8a . 8b a plastic carrier 1 be brought into engagement in an elastic locking or snap. Many configurations are possible, the requirements being that twisting of the end seal 10 in relation to a plastic carrier 1 with which the end seal 10 is not possible. In addition, a certain amount of force should be required to release the snap connectors, for example, the force required to support the protruding elements 13a . 13b to bend apart.

7 shows a second embodiment of an end seal 10 , The final seal 10b has many features in common with the end seal 10b of the first embodiment. Features can also be combined. The final seal 10 again has a basic body 11 , a first end 12a and a second end 12b on. The final seal 10 is designed so that a matrix material in the tubular lamp 20 can be injected. Therefore, the main body 11 an area 18 of reduced diameter in its middle section. A first through hole 15a connects the second end 12b with the area 18 of reduced diameter, wherein or wherein the channel direction of the first through-hole 15a through an elongated groove 16 will continue. A second through hole 15c connects the area 18 reduced diameter with the first end 12a wherein the second through-hole 19 the channel direction of the elongated groove 16 continues. For attachment to a plastic carrier 1 in the lighting tube 3 is the first end 12a as described above for the first embodiment again with a snap or snap connector 13 Mistake.

When the tubular lamp 20 assembled and the end seal 10b the lighting tube 3 can close a matrix material in the lamp 20 through the first through hole 15a , the elongated groove 16 and the second through hole 15c be injected. The matrix material becomes also fill a sealing space through the area 18 reduced diameter and the inner wall of the lighting tube 3 is fixed. The matrix material can act as a sealing material and the end seal 10b on the lighting tube 3 glue.

The following is a manufacturing method of a tubular lamp 20 explained. The tubular lamp 20 includes a plastic carrier 1 as introduced above, one or more LED modules 2 , two end seals 10 as described above, and at least one lighting tube 3 ,

At the beginning will be at least one or more LED modules 2 on the plastic carrier 1 appropriate. Preferably, the LED modules 2 on the plastic carrier 1 not glued, but mechanically fastened, for example by a snap or Rastanbringung. Therefore, the attachment part described above is nine on the plastic carrier 1 intended. The plastic carrier 1 will then be in a lighting tube 3 used. For inserting the plastic carrier 1 becomes the plastic carrier 1 (or at least part of the plastic carrier 1 ) deformed by bending so that it is biased when it enters the lighting tube 3 is used. He then pushes, if he is inside the lighting tube 3 is arranged, against the inner wall of the lighting tube 3 and ensures that a frictional force the plastic carrier 1 holds in place. Part of the plastic carrier 1 which is deformed, for example, the bendable arms 4a . 4b be as described above.

If the plastic carrier 1 in the lighting tube 3 has been arranged, become end seals 10 with the snap-in or snap connectors 8a . 8b of the plastic carrier 1 at each end of the lighting tube 3 connected. In case of more than one plastic carrier 1 used and in the lighting tube 3 is used, are end seals 10 with the outermost plastic carriers 1 at the ends of the lighting tube 3 connected. The connection of the end seals 10 with the plastic carrier 1 can, as described above, by suitable snap or snap connector 8a . 8b and 13 be accomplished at the ends of the plastic carrier 1 or the end seals 10 are provided. An end seal 10 should be equipped with a snap or snap connector, which is suitable to be with the first latch or snap connector of a plastic carrier 1 to connect, and the outer end seal 10 should be with a snap connector 13 be equipped, which is suitable, with the second latch or snap connector 8b of the plastic carrier 1 connect to.

Finally, if the plastic carrier 1 and the end seals 10 and that at least one lighting tube 3 assembled, a matrix material and / or a sealing material through at least one of the end seals 10 injected. The matrix material can, for example, through the pipeline 19 an end seal 10 , as described above, are injected to voids between the LED modules 2 and the inner wall of the lighting tube 3 inside the lighting tube 3 to fill. The matrix material may be a material containing a phosphor so as to provide the spectral characteristics of that of the LED modules 2 to change emitted light and thus the emission characteristics of the tubular lamp 20 to influence. The matrix material may include one or more phosphors for adding light of a different wavelength to the light of the LED modules 2 contain. In order to cause, for example, emitted blue light to be perceived as white light, an appropriate yellow wavelength can be added by the phosphors.

In case of the plastic carrier 1b According to the second embodiment, the injected matrix material should be prevented from entering the large cavity between the bendable arms 4b at the bottom surface 7b of the carrier 1b enter. Therefore, the plastic carrier 1b be provided with suitable sealing means of the second embodiment. The sealing means could be at the interface of the bendable arms 4b and the floor area 7b be provided.

It is preferred, however, that the matrix material be allowed to enter any voids that exist between the LED modules 2 and the inner wall of the lighting tube 3 above the top surface 5a . 5b the plastic carrier 1 are located. If the attachment part or area nine in which the LED modules 2 can be introduced by snapping, provided with protruding elements, as explained above, in order to achieve a more stable snap fit, the matrix material is also allowed in any contact surfaces between these protruding elements and the LED modules 2 enter.

Before the injection of the matrix material, the inner wall of the lighting tube 3 be coated with a different material, which preferably also comprises at least one phosphor. The coating of the lighting tube 3 can be before mounting the components of the tubular lamp 20 be performed. In this way, two layers are defined, that is a coating layer and the matrix material, both the LED modules 2 cover and in combination the optical properties of the tubular lamp 20 can change. Another way, achieving such a double layer is to include a filler material in the tubular lamp prior to injecting the matrix material 20 to inject the inner wall of the lighting tube 3 selectively coat.

The manufacturing method may further include a step of injecting a sealing material, for example, through the first through hole 15a each of the end seals 10 as explained above. As in 6b is shown, when sealing material, such as silicone, through the first through hole 15a is injected, the sealing material through the elongated groove 16 flow and fill in the seal chamber that goes through the area 18 smaller diameter and the inner wall of the lighting tube 3 is fixed. The sealing material will be the plastic end seals 10 to the inner wall of the lighting tube 3 seal and glue. This will provide protection for the components in the tubular lamp 20 , For example, against or from dirt and dust provided. In addition, stability of the overall arrangement is ensured.

When the sealing material through the first through hole 15a is injected, air is replaced and through the second through hole 15b pushed out until no air is left in the seal chamber. The sealing material then becomes the second through hole 15b block to seal the seal chamber to the outside.

The two injection steps described above can be carried out sequentially. It does not matter which of the injection steps is executed first. Preferably, however, the matrix material first passes through the pipeline 19 in the cavities between the LED modules 2 and the inner wall of the lighting tube 3 filled. Second, the sealing material is placed in the sealing spaces on both sides of the lighting tube 3 filled to the tubular lamp 20 to close and seal.

To execute the injection steps is the illumination tube 3 in an upright (vertical) position, and the materials are from the lower side of the upright tubular lamp 20 inject. This means that the injected materials are pushed upwards. When the matrix material passes through the pipeline 19 one of the end seals 10 is pressed and the lighting tube 3 is in an upright position, the replaced air is up and out of the pipeline 19 the second end seal 10 at the upper end of the lighting tube 3 pressed. Thus, it can be ensured that the air is effectively and efficiently dissipated and that no air pockets are formed in the matrix material.

The LED modules 2 On or on the plastic carrier can also be provided with one or more ball attachments. Ball attachments are preferably prior to assembly of the components of the lamp 20 issued. A ball attachment can be via an LED module 2 or he may have a plurality of LED modules 2 cover. A ball attachment may be made of a material which is transparent and / or of a material containing one or more phosphors. A ball attachment is preferably a hemispherical collection of dispensed material, which is each LED module 2 covered. The ball attachment thus protects the LED module 2 and can be used to determine the light output characteristics of the respective LED module 2 to change.

The one or more of the ball cups also serves to slightly dissociate the injected matrix material from the light-generating surface of the one or more LED chips included in each LED module 2 are included. Thus, the heat stability requirements of the matrix material or phosphors in the matrix material are reduced since the heat is not generated directly at the matrix material interface. Heat from the LED modules 2 is through the plastic carrier 1 led away, which acts as a heat sink, and by the ball attachment material, which absorbs the heat directly from the LED modules 2 absorbed before secondary heat is released to the matrix material.

The heat transfer in the tubular lamp 20 is, as described above, by the design or the design of the plastic carrier 1 optimized. An efficient heat sink, the heat to the lighting tube 3 is provided without the need to provide a separate aluminum heat sink. By injecting the matrix material, a large area surface contact between the inner wall of the illumination tube 3 and the plastic carrier 1 or the LED modules 2 educated. This leads to a more efficient cooling and heat reduction of the matrix material. The matrix material 1 also ensures extra stability for the tubular lamp 20 , The production of the tubular lamp 20 is easy and can be applied to the manufacture of lamps 20 be easily adjusted with different lengths.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2002/0047516 A1 [0004]
• US 2011/0038147 A1 [0004]
• WO 2011/064305 A1 [0005]
• WO 2011/121145 Al [0005]

Claims (15)

Plastic carrier ( 1 ) for holding one or more LED modules ( 2 ) within a lighting tube ( 3 ), wherein or wherein the plastic carrier ( 1 ) at least one bendable part ( 4 ), which is suitable, the plastic carrier ( 1 ) within the lighting tube ( 3 ) in that it is biased and thus against the inner wall of the lighting tube ( 3 ) presses or presses. Plastic carrier according to claim 1, wherein or the plastic carrier ( 1 ) has an approximately semi-cylindrical shape with a first end surface ( 6a ), a second end surface ( 6b ), a flat top surface ( 5a ) and a semi-circular bottom surface ( 7a ) having. Plastic carrier ( 1 ) according to claim 2, wherein or the bendable part ( 4 ) a plurality of bendable arms ( 4a ) located on opposite sides of the flat top surface (FIG. 5a ) which are approximately perpendicular to the flat top surface (FIG. 5a ) and in tangential continuation of the semi-circular bottom surface ( 7a ). Plastic carrier ( 1 ) according to claim 3, wherein or the bendable arms ( 4a ) are designed so that their pressing against the inner wall of the lighting tube ( 3 ) leads to a force which the semicircular bottom surface ( 7a ) against the inner wall of the lighting tube ( 3 ) presses or presses. Plastic carrier according to claim 1, wherein or the plastic carrier ( 1 ) a first end page ( 6a ), a second end page ( 6b ), a top surface ( 5b ) and a floor surface ( 7b ), wherein or the bendable means or devices ( 4b ) a plurality of curved bendable arms ( 4b ) extending from opposite sides of the floor surface ( 7b ) extend. Plastic carrier ( 1 ) according to one of claims 2 to 5, wherein the number and position of the plurality of bendable arms ( 4a . 4b ) are selected so that no resulting torsion of the plastic carrier ( 1 ) when passing through the bendable arms ( 4a . 4b ) in a lighting tube ( 3 ) is held. Plastic carrier ( 1 ) according to one of claims 2 to 6, comprising a mounting region ( nine ) on the top surface ( 5a . 5b ), which is suitable for the one or more LED modules ( 2 ) record and hold. Plastic carrier ( 1 ) according to any one of claims 1 to 7, wherein or the plastic carrier ( 1 ) has a thermal conductivity of 0.1 W / mK to 20 W / mK. Plastic carrier according to one of claims 1 to 8, wherein or the plastic carrier ( 1 ) is made of a highly reflective material or an at least partially transparent material. Plastic carrier ( 1 ) according to one of claims 1 to 9, wherein or the plastic carrier ( 1 ) comprises at least one color conversion material. Plastic carrier ( 1 ) according to one of claims 2 to 10, wherein or the plastic carrier ( 1 ) a first latch or snap connector ( 8a ) extending from the first end ( 6a ) and a second snap-in connector ( 8b ) extending from the second end face ( 6b ), in which or wherein the first latch or snap connector ( 8a ) and the second latch or snap connector ( 8b ) are shaped so that they are capable of with or in a second latch or snap connector ( 8b ) or first latch or snap connector ( 8a ) of another or further plastic carrier ( 1 ) intervene. Plastic carrier ( 1 ) according to claim 11, wherein the first snap-in connector ( 8a ) and the second snap-in or latching connector ( 8b ) are designed so that they rotate the plastic carrier ( 1 ) with respect to another engaged plastic carrier ( 1 ) prevent. Tubular lamp ( 20 ), comprising at least one lighting tube ( 3 ), at least one plastic carrier ( 1 ) according to one of claims 1 to 11, which is provided by the bendable means or devices ( 4 ) within the at least one lighting tube ( 3 ) and one or more LED modules ( 2 ) attached to the plastic carrier ( 1 ) are mounted. Tubular lamp ( 20 ) according to claim 13, wherein or the illumination tube ( 3 ) is made of glass or plastic. Tubular lamp ( 20 ) according to claim 12 or 13, comprising a plurality of plastic carriers ( 1 ) obtained by respective engagement of a first snap-in connector ( 8a ) of a plastic carrier ( 1 ) with or in a second snap or latching connector ( 8b ) of another or further plastic carrier ( 1 ) are interconnected.

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