JP3632257B2 - Mold heating apparatus, heating / cooling apparatus and method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a mold heating apparatus, a heating / cooling apparatus, and a method thereof, and in particular, can improve the quality of an injection molded product by preheating the mold surface before injection molding. The present invention relates to an apparatus and a method.
[0002]
[Prior art]
Generally, it is known that when the resin is injected with the temperature of the cavity surface of the resin molding die being increased, the appearance quality and optical characteristics of the molded product are improved. As this type of conventional mold heating apparatus, Japanese Patent Publication No. Sho 60-56604, Japanese Patent Publication No. Sho 62-179912, Japanese Patent Publication No. Sho 62-111182, Japanese Patent Publication No. Sho 63-15707, Techniques described in Japanese Laid-Open Patent Publication No. 62-208918, Japanese Laid-Open Patent Publication No. 58-12714, or Japanese Laid-Open Patent Publication No. 58-21405 can be cited. For example, the technique disclosed in Japanese Patent Publication No. 60-56604 performs resin injection with the cavity surface temperature raised in advance by high-frequency induction heating. Note that Japanese Patent Laid-Open Nos. Sho 62-111182 and 63-15707 disclose similar techniques. In the technique disclosed in JP-A-62-179912, a heating medium such as hot water or hot oil and a cooling medium are alternately circulated through the flow path in the mold to raise and lower the cavity temperature. JP-A-62-208918, JP-A-58-12714 and JP-A-58-21405 disclose similar techniques. In addition, as this kind of technology, the cavity surface of the mold is actively heated by Joule heating or a heater built in the mold, or by SSI (Spotless Surface Injection) molding method. There is a method of passively heating the cavity surface with an injection molten resin.
[0003]
[Problems to be solved by the invention]
However, the technique disclosed in Japanese Patent Publication No. 60-56604 uses high-frequency induction heating, so that high-frequency generating means such as a high-frequency oscillator is required, resulting in an increase in equipment cost. In general, it is necessary to raise the cavity surface temperature to be higher than the heat deformation temperature of the resin that is a molding material. However, the technique of Japanese Patent Application Laid-Open No. Sho 62-179912 has a low heating medium temperature and has a heating performance. It may be insufficient. That is, special heating methods such as high-frequency induction heating, Joule heating, and SSI molding have high heating performance, but have the disadvantages of increased equipment costs and poor maintainability. On the other hand, general heating methods such as heating with a heater built in the mold or heating with hot water or hot oil circulating inside the mold can reduce the equipment cost compared to the above special heating method, While maintainability can be improved, there is room for improvement in terms of heating performance.
[0004]
SUMMARY OF THE INVENTION Accordingly, a first object of the present invention is to provide a mold heating apparatus and method that have good heating performance, reduce equipment costs, and improve maintainability. .
[0005]
Moreover, this invention makes it a 2nd subject to provide the heating-cooling apparatus of the metal mold | die which has favorable heating-cooling performance, can reduce installation cost, and can improve maintainability, and its method. It is.
[0006]
[Means for Solving the Problems]
Claim 1 The mold heating / cooling device according to the present invention is configured so that the back surface of the insert comes into contact with the mold body when the mold is clamped and the back surface of the insert is detached from the mold body when the mold is opened. Thus, a predetermined space is formed between the back surface of the insert and the mold body. On the other hand, when the mold is clamped, the external heating means is retracted to a position where it does not interfere with the insert, and when the mold is opened, the external heating means advances to a position facing either the molding surface or the back surface of the insert to transfer the molding surface by heat transfer. Heat directly or indirectly through the back side. Furthermore, the cooling means provided in the mold body is brought into contact with the back surface of the insert during mold clamping, and the molding surface is cooled via the back surface.
[0007]
Claim 2 The mold heating / cooling device according to the invention is configured such that the back surface of the cavity insert is brought into contact with the mold body when the mold is clamped by the cavity insert moving means, and the back surface of the cavity insert is attached to the mold body when the mold is opened. A predetermined space is formed between the back surface and the mold body. Further, when the mold is clamped, the external heating means is retracted to a position where it does not interfere with the cavity insert, and when the mold is opened, the external heating means advances to a position where it abuts on the back surface of the cavity insert, and the cavity surface passes through the back surface by heat conduction. Heat. Furthermore, the cooling means provided in the mold body is brought into contact with the back surface of the cavity insert during mold clamping, and the cavity surface is cooled through the back surface.
[0008]
Claim 3 In the mold heating apparatus according to the invention, the cavity insert moving means makes the back surface of the cavity insert come into contact with the mold body when the mold is clamped, and the back surface of the cavity insert from the mold body when the mold is opened. A predetermined space is formed between the back surface and the mold body by separating. Further, the first external heating means is retracted to a position where it does not interfere with the cavity insert when the mold is clamped, and the first external heating means advances to a position where it abuts on the back surface of the cavity insert when the mold is opened. The cavity surface is heated. On the other hand, the second external heating means is retracted to a position where it does not interfere with the cavity insert when the mold is clamped, and at the time of opening the mold, the second external heating means advances to a position close to and opposed to the cavity surface of the cavity insert. The cavity surface is heated by radiation. Furthermore, the cooling means provided in the mold body is brought into contact with the back surface of the cavity insert during mold clamping, and the cavity surface is cooled through the back surface.
[0009]
Claim 4 The mold heating apparatus according to the invention is Claim 3 In this invention, the second external heating means is constituted by an electric discharge machining electrode obtained by machining the cavity surface of the cavity insert.
[0010]
Claim 5 The mold heating apparatus according to the invention is Claim 3 In the invention, the second external heating means includes a first heating surface that is closely opposed to the cavity surface of the cavity insert with a predetermined gap when the mold is opened, and extends to the first heating surface. It comprises a second heating surface that contacts the parting surface of the cavity insert and heats the cavity surface via the parting surface by heat conduction.
[0011]
Claim 6 The mold heating apparatus according to the invention is Claim 2 In the invention according to any one of claims 1 to 4, the thickness of at least the portion of the nest corresponding to the cavity surface is in the range of 0.5 mm to 15 mm.
[0012]
Claim 7 In the mold heating method according to the invention, with the mold opening, the back surface of the insert is separated from the mold body to form a predetermined space between the back surface and the mold body. Next, an external heating means as a heat source is advanced into the space, arranged opposite to the back surface of the nest, and the molding surface is heated via the back surface by heat transfer.
[0013]
Claim 8 In the mold heating and cooling method according to the present invention, the mold rear surface is separated from the mold body to form a predetermined space between the back surface and the mold body as the mold is opened. Next, an external heating means as a heat source is advanced into the space, arranged opposite to the back surface of the nest, and the molding surface is heated via the back surface by heat transfer. Thereafter, with mold clamping, the external heating means is retracted from the space, and the cooling means is brought into contact with the back surface of the nest, and the molding surface is cooled via the back surface.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below.
[0015]
FIG. 1 is an explanatory view showing the time of mold cooling by the mold heating / cooling device of the first embodiment of the present invention. FIG. 2 is an explanatory view showing the time when the mold is heated by the mold heating / cooling device according to the first embodiment of the present invention. FIG. 3 is a sectional view showing a heating state by the heating means of the heating / cooling device for the mold according to the first embodiment of the present invention. FIG. 4 is an enlarged cross-sectional view showing a main part of the heating means of the mold heating / cooling device according to the first embodiment of the present invention. FIG. 5 is a cross-sectional view showing a cooling state by the cooling means of the mold heating / cooling device of the first embodiment of the present invention.
[0016]
Since the heating / cooling device of this embodiment is embodied in an injection mold, first, an outline of the structure of the injection mold will be described.
[0017]
1 and 2, the injection mold according to the present embodiment has a movable main mold 14 attached to a movable die plate 11 via a movable attachment plate 12 and a spacer block 13. On the right side surface of the movable main mold 14, a core surface 14 a having a convex cross section protruding rightward is formed, and the core surface 14 a constitutes a part (inner side surface portion) of the molding space S. An extrusion pin 16 is fixed to the space in the spacer block 13 so as to protrude rightward through an extrusion plate 15. The extrusion pin 16 is flush with the core surface 14a of the movable main mold 14 at the mold clamping position shown in FIG. Further, at the mold opening position shown in FIG. 2, the push plate 15 is moved rightward by the drive shaft 17 of the drive mechanism, and the tip surface of the push pin 16 protrudes rightward from the core surface 14 a of the movable main die 14. The molded product after cooling and solidification can be easily taken out. On the other hand, a fixed back plate 23 is fixed to the fixed side die plate 21 via a fixed side mounting plate 22. An introduction recess 23a for introducing the injection nozzle 24 is formed at the center of the right side surface of the fixed back plate 23, and the center of the fixed side mounting plate 22 and the fixed side die plate 21 communicates with the introduction recess 23a. Introducing holes 22a and 21a are respectively formed. A sprue 23b and a runner 23c are formed in the center of the introduction recess 23a of the fixed back plate 23, and the tip of the injection nozzle 24 is connected to the sprue 23b through the introduction holes 21a and 22a and the introduction recess 23a. It comes to wear. In addition, since the above structure is the same as that of a general injection mold, the detailed description of a relevant part is abbreviate | omitted.
[0018]
The fixed back plate 23 is a cooling section 23d having a convex cross section projecting leftward from the center of the left side surface. A plurality of cooling holes 23e are provided on the right side of the cooling portion 23d of the fixed back plate 23 in the front-rear direction (a direction orthogonal to the paper surface in FIGS. 1 and 2), and cooling fluid such as cooling water is supplied to the cooling holes 23e. By circulating, the temperature of the cooling part 23d is lowered. A fixed main mold 24 is attached to the left side surface of the fixed back plate 23 so as to be movable left and right. A fixed main mold moving mechanism (not shown) allows the mold clamping position shown in FIG. 1 and the mold opening position shown in FIG. It is designed to reciprocate between the two. A cavity insert 26 is fitted and fixed to the central portion of the fixed main mold 24 via a heat insulating plate 25.
[0019]
As shown in FIG. 3, the cavity insert 26 has a cavity surface 26a that forms the other part (outer surface portion) of the molding space S, and a back surface 26b that is located on the opposite side of the cavity surface 26a. The left side surface 26d of the cavity insert 26, the left side surface 24a of the fixed main mold 24, and the left side surface 25a of the heat insulating plate 25 are flush with each other to form a parting surface or a parting line PL. Further, the right side surface 24b of the fixed main mold 24 and the right side surface 25b of the heat insulating plate 25 are flush with each other, and a receiving hole having a shape in which the cooling portion 23d of the fixed back plate 23 is closely fitted in the center of the heat insulating plate 25. 25 c is formed, and a step-shaped recess is formed between the right side surface 25 b of the heat insulating plate 25 and the back surface 26 b of the cavity insert 26. Then, as shown in FIG. 5, in the mold clamping state, the cooling portion 23d is tightly fitted in the receiving hole 25c, the cooling portion 23d is in close contact with the back surface 26b of the cavity insert 26, and the right side of the fixed main die 24 The surface 24 b is in close contact with the left side surface 23 f of the fixed back plate 23. Further, in the mold clamping state, the left side surfaces 24 a, 25 a, and 26 d of the fixed main mold 24, the heat insulating plate 25, and the cavity insert 26 are in close contact with the right side face of the movable main mold 14. A molding space S having a substantially U-shaped cross section is formed between the cavity surface 26 a and the core surface 14 a of the movable main mold 14. In addition, a gate 26c is formed in the center of the cavity insert 26 so as to align and communicate with the runner 23c of the fixed back plate 23.
[0020]
The fixed main mold 24, the heat insulating plate 25, and a fixed main mold moving mechanism (not shown) constitute a cavity insert moving means for reciprocating the cavity insert 26 in the left-right direction. The back surface 26b is brought into contact with the left side surface 23f of the fixed back plate 23 as a mold body, and when the mold is opened, the back surface 26b of the cavity insert 26 is separated from the left side surface 23f of the fixed back plate 23 and the back surface 26b. A space with a predetermined interval is formed between the fixed back plate 23 and the fixed back plate 23. Further, by a cooling portion 23d and a cooling hole 23e provided on the fixed back plate 23 as the mold body, the cavity surface 26a is brought into contact with the back surface 26b of the cavity insert 26 at the time of clamping, and the cavity surface 26a is interposed through the back surface 26b. A cooling means for cooling is configured. As in the case of a general injection mold, the fixed main mold 24 is supported on the fixed back plate 23 via the guide pins 27, and the fixed main mold 24 and the movable main mold 14 are moved left and right via the guide pins 27. It is guided and aligned with the exact clamping position.
[0021]
Next, the external heating means of this embodiment will be described.
[0022]
As shown in FIG. 3, the present embodiment includes first and second external heating means 31 and 32 having a substantially square block shape corresponding to the cavity surface 26a as external heating means. The first external heating means 31 is retracted by the first moving mechanism 41 to a retracted position (position in FIG. 1) that does not interfere with the cavity insert 26 when the mold is clamped, and the cavity insert 26 when the mold is opened. The cavity surface 26a is heated through the back surface 26b by heat conduction by advancing to a heating position (position shown in FIG. 2) in close contact with the back surface 26b of the surface. Note that the width and height (front and rear dimensions and vertical dimension in the figure) of the first external heating means 31 are set to be smaller than the width and height of the accommodation holes 25c of the heat insulating plate 25 by a predetermined value, respectively. The front and back and upper and lower side surfaces of the heating means 31 are in contact with the heat insulating plate 25 to prevent the heat insulating plate 25 from being directly heated. The dimension of the first external heating means 31 is set so that at least substantially the entire back surface 26b corresponding to the cavity surface 26a can be heated, and the dimension of the accommodation hole 25c of the heat insulating plate 25 is set correspondingly.
[0023]
Here, the thickness of the cavity insert 26 is preferably set to 15 mm or less at least in the portion corresponding to the cavity surface 26a in order to improve heat conduction from the back surface 26b side. In particular, it is more preferable to set the thickness of the cavity insert 26 at the portion where the first external heating means 31 abuts within this range. If the thickness exceeds 15 mm, the heat conduction efficiency is lowered, and the heat transfer time from the back surface 26b side of the cavity insert 26 to the cavity surface 26a side may be increased. On the other hand, such a thickness is preferably 0.5 mm or more when the cavity insert 26 is processed by cutting. If the thickness is less than 0.5 mm, the cavity insert 26 may be difficult to cut or the workability may be reduced. When the cavity insert 26 can be processed to be thinner by a processing method other than cutting, the lower limit value may be set to about 0.2 mm, for example. However, when the lower limit is less than 0.2 mm, the cavity insert 26 may be thermally deformed during heating or may be damaged by the injection pressure of the resin.
[0024]
The second external heating means 32 is retracted by the second moving mechanism 42 to a retracted position (position shown in FIG. 1) that does not interfere with the cavity insert 26 when the mold is clamped, and the cavity insert when the mold is opened. The cavity surface 26a is advanced to a heating position (position shown in FIG. 2) that faces and opposes the cavity surface 26a with predetermined gaps d1, d2, and d3, and the cavity surface 26a is heated by heat radiation. The width and height (front and rear dimensions and vertical dimension in the figure) of the second external heating means 32 are set smaller than the width and height of the cavity surface 26a of the cavity insert 26 by a predetermined value, respectively. The front and rear and upper and lower side surfaces of the heating means 32 abut against the cavity insert 26 to prevent the cavity insert 26 from being directly heated. The gaps d1, d2, d3 between the second external heating means 32 and the cavity surface 26a are desirably made as small as possible to increase the heat radiation efficiency, and preferably about 0.2 mm. If the gap is less than 0.2 mm, it may be difficult to secure a constant gap between the second external heating unit 32 and the cavity surface 26a. May come into contact with the cavity surface 26a and cause damage.
[0025]
Next, the detail of a structure of the 1st and 2nd external heating means 31 and 32 is demonstrated. Since the first external heating unit has the same configuration as that of the second external heating unit, the same reference numerals are assigned to the corresponding portions, and redundant description is omitted here.
[0026]
As shown in FIG. 4, the first and second external heating means 31 and 32 are formed on the flat plate-like support plates 31a and 32a via the plate-like heat sources 31b and 32b, and the plate-like heat plates 31c and 32c. It has a three-layered square block shape. The support plates 31a, 32a are located on the first or second moving mechanism 41, 42 side, and preferably to prevent the influence of heat transfer to the first or second moving mechanism 41, 42, It is made of a heat insulating material. The heat sources 31b and 32b may be any heat sources that can heat the hot plates 31c and 32c to a desired temperature, for example, near 350 ° C. within a predetermined time, corresponding to the melting temperature of the injection resin. A known electric heater may be incorporated in the metal, or a heating fluid such as hot oil may be circulated. Further, the hot plates 31c and 32c are formed of a metal having a good thermal conductivity such as a copper plate. In the present embodiment, as the hot plate 32c of the second external heating means 32, an electric discharge machining electrode obtained by machining the cavity surface 26a of the cavity insert 26 is used, and the gaps d1, d2 between the hot plate 32c and the cavity surface 26a are used. , D3 are easily maintained at a constant value. As the first and second moving mechanisms 41, 42, various known two-dimensional or three-dimensional moving mechanisms such as two-dimensional or three-dimensional combinations of hydraulic cylinders may be employed. Can do.
[0027]
Next, an injection molding operation using the mold heating and cooling method by the mold heating and cooling apparatus of the present embodiment configured as described above will be described. The injection molding operation is performed according to a control program stored in advance in the ROM by using a control unit including a CPU, a ROM, a RAM, and the like. FIG. 6 is a process diagram showing a mold heating and cooling method according to the first embodiment of the present invention.
[0028]
First, in a mold opening process as a space forming process, a mold clamping device (not shown) of an injection molding machine is driven, and a movable main mold 14 is moved via a movable die plate 11, a movable attachment plate 12, and a spacer block 13. Is moved to the left, and a sufficient space is provided between the fixed main mold 24 and the fixed back plate 23 as the mold opening position of FIG. At the same time, the fixed main mold 24 is moved to the left by the fixed main mold moving mechanism, the back surface 26b of the cavity insert 26 is separated from the fixed back plate 23, and between the movable main mold 14 and the fixed back plate 23. It is arranged at a substantially middle position. As a result, as shown in FIG. 2, predetermined intervals are provided between the fixed back plate 23 and the back surface 26b of the cavity insert 26, and between the cavity surface 26a of the cavity insert 26 and the movable main mold 14, respectively. A space is formed.
[0029]
Next, in the hot plate approaching process, the first moving mechanism 41 is driven to advance the first external heating means 31 having the heat source 31b into the space between the fixed back plate 23 and the fixed main mold 24. The hot plate 31 c is disposed opposite to the back surface 26 b of the cavity insert 26. At the same time, the second moving mechanism 42 is driven, the second external heating means 32 having the heat source 32b is advanced into the space between the fixed main mold 24 and the movable main mold 14, and the hot plate 32c is moved into the cavity. The insert 26 is disposed opposite to the cavity surface 26a.
[0030]
2 and 3, in the heating process, the first and second moving mechanisms 41 and 42 bring the hot plate 31c of the first external heating means 31 into close contact with the back surface 26b of the cavity insert 26. At the same time, the hot plate 32c of the second external heating means 32 is placed close to the cavity surface 26a with predetermined gaps d1, d2, d3. Then, the hot plate 31c of the first external heating means 31 heats the back surface 26b of the cavity insert 26 by heat conduction, and indirectly heats the cavity surface 26a as a molding surface from the back surface 26b side. At the same time, the hot plate 32c of the second external heating means 32 directly heats the cavity surface 26a of the cavity insert 26 by heat radiation. The heating time in this heating step is the thickness of the portion corresponding to the cavity surface 26a of the cavity insert 26 to be heated, the target heating value of the cavity surface 26a according to the type of injection resin, and the heating temperature of the hot plates 31c and 32c. It changes suitably according to etc. For example, when the ABS resin is injected, the thickness of the portion corresponding to the cavity surface 26a of the cavity insert 26 is 10 mm, and the target temperature of the cavity surface 26a is 130 ° C., the heating temperature of the hot plates 31c and 32c is about 350. When it is set to ° C., the heating time is about 30 to 40 seconds. In addition, when the thickness of the portion corresponding to the cavity surface 26a of the cavity insert 26 is changed to 5 mm under such conditions, the cavity surface 26a can be brought to the same temperature as the above temperature with a heating time of 20 seconds or less. In this case, if the heating time is 1 minute, the temperature of the cavity surface 26a can be about 200 ° C. At this time, the heat insulating plate 25 prevents the cavity insert 26 from radiating heat. In addition, since the hot plate 32c of the second external heating means 32 is constituted by the electric discharge machining electrode, the gap with the cavity surface 26a can be set to an extremely small and uniform interval of 0.2 mm, and the heat radiation can be reduced. It can be performed efficiently and can be prevented from being damaged by contact. Furthermore, since the cavity insert 26 is made as thin as possible, heat conduction from the back surface 26b side can be performed efficiently. The temperature of the cavity surface 26a itself is determined according to the type of resin, the heating deformation temperature, etc., as in the normal mold temperature adjustment technique.
[0031]
Thereafter, in the hot plate separation step, the first moving mechanism 41 separates the hot plate 31c of the first external heating means 31 from the position where it contacts the back surface 26b of the cavity insert 26, and the cavity insert 26 and the fixed back are fixed. Retreat from the space between the plate 24 to the retreat position of FIG. At the same time, the second moving mechanism 42 separates the hot plate 32c of the second external heating means 32 from a position approaching the cavity surface 26a of the cavity insert 26, and the cavity insert 26 and the movable main mold 14 are separated from each other. Retreat from the space between them to the retreat position of FIG.
[0032]
Thereafter, in the mold clamping process, the fixed main mold moving mechanism is driven to clamp the fixed main mold 24 to the fixed back plate 23 and the mold clamping device is driven to move the movable side die plate 11 and the movable side attachment. The movable main mold 14 is clamped to the fixed main mold 24 and the fixed back plate 23 via the plate 12 and the spacer block 13. Then, the movable main mold 14 and the cavity insert 26 are clamped at the parting surface, and a molding space S having the same shape as the molded product shape is formed between the core surface 14a and the cavity surface 26a, and the fixed back plate. 23 sprues 23 b and runners 23 c communicate with the gate 26 c of the cavity insert 26. At the same time, the cooling portion 23 d of the fixed back plate 23 is in close contact with the back surface 26 b of the cavity insert 26. In this state, by pressing the tip of the injection nozzle 24 against the sprue 23b, the molten resin can be injected and injected from the injection nozzle 24 into the molding space S through the sprue 23b, the runner 23c, and the gate 26c.
[0033]
Then, in the injection process of the injection cooling process, molten resin is injected and injected into the sprue 23b from the injection device (not shown) through the injection nozzle 24, and between the cavity surface 26a and the core surface 14a from the gate 26c through the runner 23c. The molding space S to be formed is filled with molten resin. At this time, since the cavity surface 26a is heated to a desired temperature, the molten resin in contact with the cavity surface 26a reliably maintains the heat deformation temperature (for example, 160 ° C. to 170 ° C. in the case of ABS resin), and the flow mark, Generation | occurrence | production of a silver streak (silver stripe) etc. can be prevented reliably. Further, since the cooling portion 23d of the fixed back plate 23 is in close contact with the back surface 26b of the cavity insert 26 at the time of injection, a large amount of cooling fluid such as cooling water is supplied and distributed to the cooling holes 23e of the fixed back plate 23. By doing so, the back surface 26b of the cavity insert 26 can be instantaneously cooled by the cooling portion 23d as a cooling means, and the cavity surface 26a can be rapidly cooled by heat conduction, thereby sufficiently promoting the cooling and solidification of the molten resin. be able to. At this time, since the cavity insert 26 is made as thin as possible, the cooling efficiency can be improved. As a result, the injection resin becomes the heat deformation temperature or lower and quickly cools and solidifies, and a molded product having a predetermined shape corresponding to the molding space S is quickly molded. It should be noted that the temperature gradient of the cavity surface 26a from the injection of the molten resin to the cooling and solidification can be appropriately adjusted by the initial set heating temperature of the cavity surface 26a and the set cooling temperature of the cooling unit 23d.
[0034]
Thereafter, in the mold opening process shown in FIG. 3, the mold clamping device is driven to open the movable main mold 14 away from the fixed main mold 24. As a result, the core surface 14a and the cavity surface 26a are opened, and the molded product is released from the cavity surface 26a and remains on the core surface 14a. Thereafter, in the product take-out step, an extrusion driving means (not shown) is driven, the push pin 16 protrudes from the core surface 14a, and the molded product is pushed out from the core surface 14a to be removed, thereby taking out the product.
[0035]
Thereafter, the above series of steps can be repeated to continuously obtain a resin molded product having a desired shape.
[0036]
As described above, the mold heating and cooling device of the above embodiment is connected to the cavity insert 26 having the cavity surface 26a that forms a part of the molding space S and the back surface 26b that is located on the opposite side of the cavity surface 26a. When the mold is clamped, the back surface 26b of the cavity insert 26 is brought into contact with the fixed back plate 23 as a mold body, and when the mold is opened, the back surface 26b of the cavity insert 26 is detached from the fixed back plate 23 and Clamping is performed by a fixed main mold 24, a heat insulating plate 25, a fixed main mold moving mechanism as a cavity nest moving means 24 that forms a predetermined space between the back surface 26 b and the fixed back plate 23, and a first moving mechanism 41. At the time of retreating to a position where it does not interfere with the cavity insert 26, when the mold is opened, it advances to a position where it abuts against the back surface 26b of the cavity insert 26, and heat transfer from the hot plate 31c. The first external heating means 31 that heats the cavity surface 26a via the back surface 26b and the second moving mechanism 42 are used to retract to a position that does not interfere with the cavity insert 26 during mold clamping, and When opened, a second external portion having a hot plate 32c that advances to a position facing and close to the cavity surface 26a of the cavity insert 26 with a predetermined gap and heats the cavity surface 26 by heat radiation from the hot plate 32c. A cooling unit 23d and a cooling hole, which are provided on the heating unit 32 and the fixed back plate 23, abut against the back surface 26b of the cavity insert 26 during mold clamping, and cool the cavity surface 26a via the back surface 26b. 23e.
[0037]
Therefore, in the above embodiment, when the mold is heated, the cooling portion 23d is separated from the cavity insert 26 and does not cool the cavity insert 26. Therefore, the first and second external heating means 31 and 32 are used. The cavity insert 26 can be heated efficiently and quickly. Further, when the mold is cooled, the first and second external heating means 31 and 32 are retracted from the cavity insert 26 and the cavity insert 26 is not heated. Cooling can be performed efficiently and quickly, and the cooling and solidification rate of the resin can be increased. As a result, the heating performance and the cooling performance can be improved, respectively, and the molding cycle from the resin injection after heating the mold to the solidification and removal of the resin accompanying the cooling of the mold can be greatly shortened. In addition, since the first and second external heating means 31 and 32 and the cooling unit 23d operate independently in a thermally separated form, the optimum temperature of the cavity surface 26a is determined according to the type of the injection resin and the like. A thermal gradient can be obtained easily and quickly, and product quality can be improved. That is, in the case of heating with a heater built in the mold or a heating source such as hot water or hot oil as in the prior art, the temperature of the heating source itself is not easily lowered, and the thermal responsiveness during cooling was not sufficient. In this embodiment, since the first and second external heating means 31 and 32 as the heating source are retracted to a position spatially separated from the mold, the thermal response in the case where the mold is the heating source or the like. The sex can be increased. Then, by increasing the mold temperature at the start of resin material emphasis, the appearance of the molded product is improved, and the mold temperature is lowered by the heat removal action by the cooling part 23d that starts immediately after mold clamping. The molding cycle required until product removal can be shortened. In other words, the apparatus of the present embodiment can produce a high-quality molded product with a high molding cycle by enabling a large change in mold temperature.
[0038]
The heating means is not a type with a built-in mold, but a type arranged outside the mold, such as the first and second external heating means 31, 32, while the heat source 31b, 32b itself is used. Since a known heat source having a relatively simple configuration, such as an electric heater, can be used, the equipment cost is greatly reduced as compared with the case where an expensive or complicated configuration such as high-frequency induction heating or SSI molding is used. In addition, it is easy to maintain and improve maintainability. Furthermore, since the second external heating means 32 does not directly contact the cavity surface 26a that determines the surface quality of the molded product, it is possible to prevent quality deterioration such as scratches and metal burns due to thermal oxidation, and the product itself. The quality of the can be maintained well.
[0039]
Further, by setting the thickness of the cavity insert 26 to a range of about 0.5 mm to 15 mm at least at the portion corresponding to the cavity face 26 a, the heating of the cavity face 26 a from the back face 26 b side of the cavity insert 26 can be performed more efficiently. This can be done quickly, and the temperature rise of the cavity surface 26a can be further increased. The heating efficiency by heat radiation from the second external heating means 32 is reduced by reducing the gaps d1, d2, d3 between the hot plate 32c of the second external heating means 32 and the cavity surface 26a to about 0.2 mm. Can be increased. As a result, the heating time of the cavity surface 26a can be further shortened, and the entire molding cycle can be further shortened. Furthermore, since the hot plate 31c of the first external heating means 31 is in direct contact with the back surface 26b of the cavity insert 26 that does not affect the quality of the molded product, the quality of the molded product is maintained well, while the cavity surface is maintained. The heating of 26a can be performed more efficiently.
[0040]
Further, since the cavity insert 26 is attached to the fixed main mold 24 via the heat insulating plate 25, the heat stored in the cavity insert 26 can be prevented from being dissipated by the heat insulating plate 25. Further, the heat dissipation from the first and second external heating means 31 and 32 is effectively prevented by configuring the support plates 31a and 32a of the first and second external heating means 31 and 32 with a heat insulating material. In addition, the influence of heat conduction on the first and second moving mechanisms 41 and 42 can be prevented.
[0041]
Next, a second embodiment according to the present invention will be described below. In the present embodiment, only differences from the first embodiment will be described, and the same components as those in the first embodiment will be denoted by the same reference numerals and description thereof will be omitted.
[0042]
FIG. 7 is a cross-sectional view showing a heating state by the heating means of the mold heating / cooling device of the second embodiment of the present invention.
[0043]
In the present embodiment, the shape of the portion corresponding to the hot plate of the second external heating means 51 is different from that of the first embodiment, and other configurations are the same as those of the first embodiment. That is, at least the portion corresponding to the hot plate of the second external heating means 51 is arranged so as to be opposed to the first heating surface 51a facing the cavity surface 26a of the cavity insert 26 with a predetermined gap when the mold is opened. The second heating is extended to the heating surface 51a and contacts the parting surface formed by the left side surface 26d of the cavity insert 26 when the mold is opened, and heats the cavity surface 26a through the parting surface by heat conduction. It has a surface 51b. Similar to the hot plate 32c of the second external heating means 32 of the first embodiment, the first heating surface 51a has a predetermined small gap between it and the cavity surface 26a by thermal radiation. Heat.
[0044]
In the present embodiment, in addition to the same operations and effects as the first embodiment, the cavity surface 26a can be heated more efficiently and in a short time by the second external heating means 51 from the cavity surface 26a side. There is an effect that can be done.
[0045]
By the way, although each said embodiment was concretely demonstrated to the heating-and-cooling apparatus and method of a metal mold | die, when implementing this invention, at least a cavity nest moving means and the 1st or 2nd external heating means You may actualize in the heating apparatus of the metal mold | die which consists of 31,32,51. In addition to the injection mold, the mold may be embodied as one in which preheating of the cavity surface is considered effective.
[0046]
Further, as in each of the above embodiments, the first or second external heating means 31 and 32 is not a three-layer structure of the support plates 31a and 32a, the heat sources 31b and 32b, and the heat plates 31c and 32c. Other configurations such as a built-in single layer structure may be used. In this case, in the second external heating means 51 of the second embodiment, at least a hot plate portion is constituted by the first and second heating surfaces 51a and 51b.
[0047]
In each of the above embodiments, the predetermined gaps d1, d2, and d3 are provided between the second external heating means 32 and 51 and the cavity surface 26a. However, the hot plate 32c is made of a copper plate or the like and is harder than the cavity insert 26. In the case of forming with a low material, the second external heating means 32, 51 can be brought into contact with the cavity surface 26a and heated by direct heat conduction. However, in the case of a mold in which a texture pattern is provided on the cavity surface 26a, it is necessary to provide a predetermined gap between the second external heating means 32 and 51 and the cavity surface 26a.
[0048]
Furthermore, in this apparatus and method, at least one of the core surface 14a and the cavity surface 26a forming the molding space S is preheated before injection by the external heating means in a state of being thermally separated from the cooling means. For example, the core surface may be provided on the core insert, and at least one of the core surface and the back surface of the core insert may be heated by an external heating means instead of the cavity surface. In this case, the shape of the hot plate of the external heating means corresponds to the core surface shape and the back surface shape of the core insert. In contrast to the above embodiments, the core surface may be provided not on the movable main mold side but on the fixed main mold side, and the cavity surface may be provided on the movable main mold side. The cooling means is not limited to that of the above embodiment, and other cooling means can be employed.
[0049]
In the present specification, the “mold body” refers to a mold part adjacent to and in contact with the cavity insert 26 or the core insert, and in the above embodiment, the fixed back plate 23. . When the core surface is provided in the core insert and the core insert is heated, the movable back plate adjacent to the core insert becomes the mold body.
[0050]
【The invention's effect】
As above Claim 1 In the mold heating apparatus according to the invention, the back surface of the insert is spatially separated from the mold body provided with the cooling means, and is thermally insulated from the mold, and the forming surface of the insert is externally heated. Therefore, the heating efficiency is improved. Moreover, since the molding surface is heated from the back surface side, it is possible to prevent the possibility of scratches on the molding surface, metal burns due to thermal oxidation, and the like. Furthermore, when the insert is cooled, the external heating means is spatially separated from the mold body, and the molding surface of the insert can be cooled in a state of being substantially thermally insulated, so that the cooling efficiency is improved. . As a result, the mold temperature can be greatly changed, and a high-quality molded product can be produced in a short molding cycle.
[0051]
Claim 2 The mold heating and cooling device according to the invention is such that the back surface of the cavity insert is spatially separated from the mold body provided with the cooling means and is thermally insulated substantially, and the cavity insert by the external heating means. Since the molding surface can be heated, the heating efficiency is improved. Moreover, since the molding surface is heated from the back surface side, it is possible to prevent the possibility of scratches on the molding surface, metal burns due to thermal oxidation, and the like. Furthermore, when cooling the cavity insert, the external heating means is spatially separated from the mold body, and the molding surface of the cavity insert can be cooled in a state of being substantially thermally insulated. improves. As a result, the mold temperature can be greatly changed, and a high-quality molded product can be produced in a short molding cycle.
[0052]
Claim 3 In the mold heating and cooling device according to the invention, the back surface of the cavity insert is spatially separated from the mold body provided with the cooling means, and is thermally insulated from the first and second external parts. Since the heating surface of the cavity insert can be heated by the heating means, the heating efficiency is improved. In addition, the first external heating means is directly brought into contact with the back surface of the cavity insert to indirectly heat the molding surface by heat conduction, thereby preventing the possibility of scratching the molding surface, metal burning due to heat oxidation, etc. And heating efficiency can be raised further. On the other hand, since the second external heating means directly heats the cavity surface by thermal radiation, it is possible to prevent the possibility of scratches on the molding surface, metal burning due to thermal oxidation, and the like, and further increase the heating efficiency. Further, when the cavity insert is cooled, the molding surface of the cavity insert may be cooled in a state where the first and second external heating means are spatially separated from the mold body and thermally insulated. This improves the cooling efficiency. As a result, the mold temperature can be greatly changed, and a high-quality molded product can be produced in a short molding cycle.
[0053]
Claim 4 The mold heating and cooling device according to the invention is Claim 3 In addition to the invention described above, special processing that is normally performed to make the second external heating means correspond to the cavity surface shape is not required, and the cost of parts can be reduced, and a predetermined distance between the second external heating means and the cavity surface can be reduced. The gap can be easily and accurately provided.
[0054]
Claim 5 The mold heating and cooling device according to the invention is Claim 3 In addition to the invention described above, the second heating surface of the second external heating means directly contacts the parting surface of the cavity insert, and efficiently heats the nearest cavity surface by heat conduction. Further, the first heating surface efficiently heats the cavity surface by heat radiation. As a result, the molding cycle can be further shortened.
[0055]
Claim 6 The mold heating and cooling device according to the invention is Claim 2 In addition to the invention described in any one of Items 4 to 4, since the thickness of the cavity nest is sufficiently small, the heat conduction heating from the back side of the cavity nest by the first external heating means can be performed more efficiently. it can.
[0056]
Claim 7 The mold heating method according to the invention is such that the back surface of the insert is spatially separated from the mold main body and is thermally insulated, and the forming surface of the insert is heated by the external heating means. Therefore, the heating efficiency is improved. As a result, the mold temperature can be greatly changed, and a high-quality molded product can be produced in a short molding cycle.
[0057]
Claim 8 In the mold heating and cooling method according to the invention, the back surface of the insert is spatially separated from the mold body provided with the cooling means, and the insert is molded by the external heating means in a state of being substantially thermally insulated. Since the surface can be heated, the heating efficiency is improved. Moreover, since the molding surface is heated from the back surface side, it is possible to prevent the possibility of scratches on the molding surface, metal burns due to thermal oxidation, and the like. Furthermore, when cooling the insert, the external heating means is spatially separated from the mold body, and the molded surface of the insert can be cooled in a state of being substantially thermally insulated, thereby improving the cooling efficiency. To do. As a result, the mold temperature can be greatly changed, and a high-quality molded product can be produced in a short molding cycle.
[Brief description of the drawings]
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is an explanatory diagram showing when a mold is cooled by a mold heating / cooling device according to a first embodiment of the present invention.
FIG. 2 is an explanatory diagram showing heating of a mold by a mold heating / cooling device according to the first embodiment of the present invention.
FIG. 3 is a cross-sectional view showing a heating state by a heating means of the heating / cooling device for the mold according to the first embodiment of the present invention.
FIG. 4 is an enlarged cross-sectional view showing a main part of a heating means of the heating / cooling device for a mold according to the first embodiment of the present invention.
FIG. 5 is a cross-sectional view showing a cooling state by the cooling means of the heating / cooling device for the mold according to the first embodiment of the present invention.
FIG. 6 is a process diagram showing a mold heating and cooling method according to the first embodiment of the present invention.
FIG. 7 is a sectional view showing a heating state by a heating means of a heating / cooling device for a mold according to a second embodiment of the present invention.
[Explanation of symbols]
14a Core surface (molded surface)
23 Fixed back plate (mold body)
23d Cooling unit (cooling means)
23e Cooling hole (cooling means)
24 Fixed main mold (nesting movement means, cavity nesting movement means)
25 Insulation plate (nesting movement means, cavity nesting movement means)
26 Cavity nested (nested)
26a Cavity surface (molding surface)
31 First external heating means (external heating means)
32 Second external heating means (external heating means)
51 Second external heating means (external heating means)
51a First heating surface
51b Second heating surface
S Molding space

Claims (8)

Connected to a nest having a molding surface forming a molding space and a back surface opposite to the molding surface, the back surface of the nest is brought into contact with the mold body during mold clamping, and the nest is opened when the mold is opened. Nesting moving means for separating the back surface of the mold body from the mold body and forming a predetermined space between the back surface and the mold body;
Retreating to a position that does not interfere with the insert during mold clamping, and external heating means for heating the molding surface through the back surface by advancing to a position facing the back of the insert during mold opening ,
A mold heating / cooling device, comprising: a cooling unit that is provided in the mold body, abuts against a back surface of the insert during mold clamping, and cools the molding surface through the back surface. It is connected to a cavity insert having a cavity surface that forms a part of the molding space and a back surface located on the opposite side of the cavity surface. At the time of clamping, the back surface of the cavity insert is brought into contact with the mold body. Cavity nesting moving means for separating the back surface of the cavity nesting from the mold body at the time of opening and forming a predetermined space between the back surface and the mold body,
When the mold is clamped, it is retracted to a position where it does not interfere with the cavity insert, and when the mold is opened, it advances to a position that contacts the back surface of the cavity insert and heats the cavity surface via the back surface by heat conduction. Means,
A mold heating / cooling apparatus, comprising: a cooling unit provided in the mold body, contacting a back surface of the cavity insert during mold clamping, and cooling the cavity surface through the back surface. It is connected to a cavity insert having a cavity surface that forms a part of the molding space and a back surface located on the opposite side of the cavity surface. At the time of clamping, the back surface of the cavity insert is brought into contact with the mold body. Cavity nesting moving means for separating the back surface of the cavity nesting from the mold body at the time of opening and forming a predetermined space between the back surface and the mold body,
The mold is retracted to a position that does not interfere with the cavity insert during mold clamping, and is advanced to a position that contacts the back surface of the cavity insert when the mold is opened to heat the cavity surface through the back surface by heat conduction. External heating means,
When the mold is clamped, it is retracted to a position where it does not interfere with the cavity insert, and when the mold is opened, the cavity face is advanced to a position close to and opposed to the cavity face of the cavity insert with a predetermined gap to heat the cavity face by heat radiation. A second external heating means;
A mold heating / cooling apparatus, comprising: a cooling unit provided in the mold body, contacting a back surface of the cavity insert during mold clamping, and cooling the cavity surface through the back surface. 4. The mold heating / cooling device according to claim 3, wherein the second external heating means includes an electric discharge machining electrode obtained by machining a cavity surface of the cavity nest. The second external heating means includes a first heating surface that faces and opposes the cavity surface of the cavity insert with a predetermined gap when the mold is opened, and extends to the first heating surface. 4. The mold heating / cooling device according to claim 3, further comprising a second heating surface that contacts the parting surface of the cavity insert and heats the cavity surface via the parting surface by heat conduction. . The mold heating / cooling device according to any one of claims 2 to 4, wherein a thickness of at least a portion corresponding to the cavity surface of the insert is in a range of 0.5 mm to 15 mm. In a heating method of a mold for heating an insert having a molding surface forming a molding space and a back surface located on the opposite side of the molding surface before injection molding,
A space forming step of forming a predetermined space between the back surface and the mold body by separating the back surface of the insert from the mold body along with the mold opening,
And a heating step of extending an external heating means having a heat source into the space, facing the back surface of the insert and heating the molding surface through the back surface by heat transfer. Mold heating method. In a heating method of a mold for heating an insert having a molding surface forming a molding space and a back surface located on the opposite side of the molding surface before injection molding,
A space forming step of forming a predetermined space between the back surface and the mold body by separating the back surface of the insert from the mold body along with the mold opening,
An external heating means having a heat source is advanced into the space, and the heating step of heating the molding surface through the back surface by heat transfer by disposing it opposite to the back surface of the insert,
A cooling step of retracting the external heating means from the space with mold clamping, contacting a cooling means against the back surface of the insert, and cooling the molding surface through the back surface. Mold heating method.

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