JP5839482B2 - Injection molding machine - Google Patents

Description

  The present invention relates to an injection molding machine.

  An injection molding machine manufactures a molded product by filling molten resin into a cavity space of a mold apparatus and solidifying the resin. The mold apparatus includes a fixed mold and a movable mold, and a cavity space is formed between the fixed mold and the movable mold when the mold is clamped. Mold closing, mold clamping, and mold opening of the mold apparatus are performed by a mold clamping apparatus. As a mold clamping device, an apparatus using a linear motor for mold opening / closing operation and an electromagnet for mold clamping operation has been proposed (for example, see Patent Document 1).

  When a direct current is supplied to the coil of the electromagnet, an attracting force is generated between the first block in which the electromagnet is formed and the second block arranged at a distance from the first block, The clamping force is generated by the suction force. A mold clamping force generation mechanism is configured by the first block and the second block.

International Publication No. 2005/090052

  Conventionally, it has been difficult to efficiently control the temperature of the mold clamping force generation mechanism.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide an injection molding machine capable of efficiently adjusting the temperature of the mold clamping force generation mechanism.

In order to solve the above-described problem, an injection molding machine according to one aspect of the present invention includes:
A mold clamping force generation mechanism that includes a first block on which an electromagnet is formed and a second block that is attracted by the electromagnet, and generates a mold clamping force between the first block and the second block. Configured,
A channel pipe for flowing a temperature-controlled fluid is inserted into an insertion part formed in at least one of the first block and the second block, and the channel pipe is fixed to the insertion part ,
The at least one of the first block and the second block has a laminated steel plate composed of a plurality of electromagnetic steel plates,
The said insertion part is formed in the said laminated steel plate, and is extended in the lamination direction of the said laminated steel plate .

  According to the present invention, an injection molding machine capable of efficiently adjusting the temperature of the mold clamping force generation mechanism is provided.

It is a figure which shows the state at the time of mold closing completion of the injection molding machine by 1st Embodiment of this invention. It is a figure which shows the state at the time of the mold opening completion of the injection molding machine by 1st Embodiment of this invention. It is a perspective view which shows the rear platen by 1st Embodiment. It is a figure which shows the structure of the multiple types of electromagnetic steel plate by 1st Embodiment. It is sectional drawing which shows the rear platen by 2nd Embodiment.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. In each of the drawings, the same or corresponding components are denoted by the same or corresponding reference numerals, and description thereof will be omitted. In each drawing, the X direction represents a direction parallel to the mold opening / closing direction, the Y direction represents a direction parallel to the laminating direction of the electromagnetic steel sheets, and the Z direction represents a direction perpendicular to the X direction and the Y direction. Further, a description will be given assuming that the moving direction of the movable platen when performing mold closing is the front and the moving direction of the movable platen when performing mold opening is the rear.

[First Embodiment]
FIG. 1 is a view showing a state at the completion of mold closing of the injection molding machine according to the first embodiment of the present invention. FIG. 2 is a view showing a state when the mold opening of the injection molding machine according to the first embodiment of the present invention is completed.

  In the figure, 10 is an injection molding machine, Fr is a frame of the injection molding machine 10, Gd is a guide composed of two rails laid on the frame Fr, and 11 is a fixed platen (first fixing member). The fixed platen 11 may be provided on a position adjustment base Ba that is movable along a guide Gd that extends in the mold opening / closing direction (left-right direction in the drawing). The fixed platen 11 may be placed on the frame Fr.

  A movable platen (first movable member) 12 is disposed facing the fixed platen 11. The movable platen 12 is fixed on the movable base Bb, and the movable base Bb can run on the guide Gd. Thereby, the movable platen 12 is movable in the mold opening / closing direction with respect to the fixed platen 11.

  A rear platen (second fixing member) 13 is disposed at a predetermined distance from the fixed platen 11 and parallel to the fixed platen 11. The rear platen 13 is fixed to the frame Fr via the leg portion 13a.

  Between the fixed platen 11 and the rear platen 13, four tie bars 14 (only two of the four tie bars 14 are shown in the figure) are installed as connecting members. The fixed platen 11 is fixed to the rear platen 13 via the tie bar 14. A movable platen 12 is disposed along the tie bar 14 so as to freely advance and retract. A guide hole (not shown) for penetrating the tie bar 14 is formed at a position corresponding to the tie bar 14 in the movable platen 12. In addition, you may make it form a notch part instead of a guide hole.

  A screw portion (not shown) is formed at the front end portion (right end portion in the drawing) of the tie bar 14, and the front end portion of the tie bar 14 is fixed to the fixed platen 11 by screwing and tightening a nut n1 to the screw portion. The rear end of the tie bar 14 is fixed to the rear platen 13.

  A fixed mold 15 is attached to the fixed platen 11, and a movable mold 16 is attached to the movable platen 12. The fixed mold 15 and the movable mold 16 are brought into contact with and separated from each other as the movable platen 12 advances and retreats. Closing, mold clamping and mold opening are performed. As the mold clamping is performed, a cavity space (not shown) is formed between the fixed mold 15 and the movable mold 16, and the cavity space is filled with molten resin. A mold apparatus 19 is configured by the fixed mold 15 and the movable mold 16.

  The suction plate (second movable member) 22 is disposed in parallel with the movable platen 12. The suction plate 22 is fixed to the slide base Sb via the mounting plate 27, and the slide base Sb can travel on the guide Gd. As a result, the suction plate 22 can move back and forth behind the rear platen 13. The adsorption plate 22 may be formed of a soft magnetic material. The attachment plate 27 may not be provided, and in this case, the suction plate 22 is directly fixed to the slide base Sb.

  The rod 39 is connected to the suction plate 22 at the rear end portion and is connected to the movable platen 12 at the front end portion. Therefore, the rod 39 is moved forward as the suction plate 22 moves forward when the mold is closed to move the movable platen 12 forward, and is retracted and moved backward as the suction plate 22 moves back when the mold is opened. Retreat. For this purpose, a through hole 41 for allowing the rod 39 to penetrate is formed in the central portion of the rear platen 13.

  The linear motor 28 is a mold opening / closing drive unit for moving the movable platen 12 forward and backward, and is disposed, for example, between the suction plate 22 connected to the movable platen 12 and the frame Fr. The linear motor 28 may be disposed between the movable platen 12 and the frame Fr.

  The linear motor 28 includes a stator 29 and a mover 31. The stator 29 is formed on the frame Fr in parallel with the guide Gd and corresponding to the movement range of the slide base Sb. The mover 31 is formed at a lower end of the slide base Sb so as to face the stator 29 and over a predetermined range.

  The mover 31 includes a core 34 and a coil 35. The core 34 includes a plurality of magnetic pole teeth 33 that protrude toward the stator 29. The plurality of magnetic pole teeth 33 are arranged at a predetermined pitch in a direction parallel to the mold opening / closing direction. The coil 35 is wound around each magnetic pole tooth 33.

  The stator 29 includes a core (not shown) and a plurality of permanent magnets (not shown) provided on the core. The plurality of permanent magnets are arranged at a predetermined pitch in a direction parallel to the mold opening / closing direction, and the magnetic poles on the side of the mover 31 are alternately magnetized into N and S poles.

  When a predetermined current is supplied to the coil 35 of the mover 31, the mover 31 is advanced and retracted by the interaction between the magnetic field formed by the current flowing through the coil 35 and the magnetic field formed by the permanent magnet. Accordingly, the suction plate 22 and the movable platen 12 are moved back and forth, and the mold closing and mold opening are performed. The linear motor 28 is feedback-controlled based on the detection result of the position sensor 53 that detects the position of the mover 31 so that the position of the mover 31 becomes a target value.

  In the present embodiment, the permanent magnet is disposed on the stator 29 and the coil 35 is disposed on the mover 31, but the coil may be disposed on the stator and the permanent magnet may be disposed on the mover. it can. In this case, since the coil does not move as the linear motor 28 is driven, wiring for supplying power to the coil can be easily performed.

  As the mold opening / closing drive unit, instead of the linear motor 28, a rotary motor, a ball screw mechanism that converts the rotary motion of the rotary motor into a linear motion, or a fluid pressure cylinder such as a hydraulic cylinder or a pneumatic cylinder may be used. .

  The electromagnet unit 37 generates an attracting force between the rear platen 13 and the attracting plate 22. This suction force is transmitted to the movable platen 12 via the rod 39, and a mold clamping force is generated between the movable platen 12 and the fixed platen 11.

  The electromagnet unit 37 includes an electromagnet 49 formed on the rear platen 13 side and a suction portion 51 formed on the suction plate 22 side. The suction portion 51 is formed in a predetermined portion of the suction surface (front end surface) of the suction plate 22, for example, a portion surrounding the rod 39 in the suction plate 22 and facing the electromagnet 49. A coil groove 45 for accommodating the coil 48 of the electromagnet 49 is formed around a predetermined portion of the attracting surface (rear end surface) of the rear platen 13, for example, around the rod 39. A core 46 is formed inside the coil groove 45. A coil 48 is wound around the core 46. The axial direction of the coil 48 is the X direction. A yoke 47 is formed at a portion other than the core 46 of the rear platen 13.

  In the present embodiment, the electromagnet 49 is formed separately from the rear platen 13 and the attracting part 51 is formed separately from the attracting plate 22, but the electromagnet is part of the rear platen 13 and the attracting part is part of the attracting plate 22. May be formed. Moreover, the arrangement of the electromagnet and the attracting part may be reversed. For example, the electromagnet 49 may be provided on the suction plate 22 side, and the suction portion 51 may be provided on the rear platen 13 side. Moreover, the number of the coils 48 of the electromagnet 49 may be plural.

  When an electric current is supplied to the coil 48 in the electromagnet unit 37, the electromagnet 49 is driven to attract the attracting part 51 and generate a mold clamping force. The rear platen (first block) 13 on which the electromagnet 49 is formed and the suction plate (second block) 22 on which the suction part 51 is formed constitute a mold clamping force generation mechanism.

  The control unit 60 includes, for example, a CPU and a memory, and controls the operation of the linear motor 28 and the operation of the electromagnet 49 by processing a control program recorded in the memory by the CPU. The control unit 60 is connected to a mold clamping force sensor 55 that detects a mold clamping force. Based on the detection result of the mold clamping force sensor 55, the controller 60 applies the coil 48 of the electromagnet 49 to a predetermined mold clamping force. May be set. The mold clamping force sensor 55 may be, for example, a strain sensor that detects distortion (elongation amount) of the tie bar 14 that expands according to the mold clamping force. As the mold clamping force sensor 55, for example, a load sensor such as a load cell that detects a load applied to the rod 39 or a magnetic sensor that detects the magnetic field of the electromagnet 49 can be used. It may be.

  Next, the operation of the injection molding machine 10 configured as described above will be described. Various operations of the injection molding machine 10 are performed under the control of the control unit 60.

  The controller 60 controls the mold closing process. In the state of FIG. 2 (die opening state), the control unit 60 drives the linear motor 28 to advance the movable platen 12. As shown in FIG. 1, the movable mold 16 comes into contact with the fixed mold 15, and the mold closing process is completed. At this time, a gap δ is formed between the rear platen 13 and the suction plate 22, that is, between the electromagnet 49 and the suction portion 51. Note that the force required for mold closing is sufficiently reduced compared to the mold clamping force.

  Subsequently, the control unit 60 controls the mold clamping process. The controller 60 supplies a direct current to the coil 48 of the electromagnet 49 in the state of FIG. If it does so, a magnetic field will arise in the coil 48 with the direct current which flows through the coil 48, the core 46 will be magnetized, and a magnetic field will be strengthened. Then, an attracting force is generated between the electromagnet 49 and the attracting part 51 facing each other with a predetermined gap, and this attracting force is transmitted to the movable platen 12 via the rod 39, and the movable platen 12 and the fixed platen 11 are Clamping force is generated between them. The cavity space of the mold apparatus 19 in the mold-clamped state is filled with molten resin, cooled and solidified to form a molded product.

  Subsequently, the control unit 60 demagnetizes the core 46 of the electromagnet 49. The demagnetization of the core 46 is performed by supplying a direct current in the direction opposite to that at the time of magnetization to the coil 48. In the demagnetization step, the direction of the direct current may be reversed a plurality of times. Due to the demagnetization of the core 46, the waiting time until the mold opening starts is shortened.

  Next, the control unit 60 controls the mold opening process. The control unit 60 supplies current to the coil 35 of the linear motor 28 to move the movable platen 12 backward. The movable mold 16 is retracted and the mold is opened. After the mold opening, an ejector device (not shown) ejects the molded product from the movable mold 16. In this way, a molded product is obtained.

  By the way, when the mold apparatus 19 is replaced, the thickness of the mold apparatus 19 changes, and the gap δ formed between the rear platen 13 and the suction plate 22 changes when the mold closing is completed. When the gap δ changes, the suction force changes and the mold clamping force changes.

  Therefore, the injection molding machine 10 includes a mold thickness adjusting unit 56 that adjusts the distance between the movable platen 12 and the suction plate 22 in accordance with the thickness of the mold apparatus 19. The mold thickness adjusting unit 56 includes a mold thickness adjusting motor 57, a gear 58, a nut 59, and the like. The nut 59 is supported so as to be rotatable with respect to the suction plate 22 and so as not to advance and retract. A screw shaft portion 43 formed at the rear end portion of the rod 39 that penetrates the central portion of the suction plate 22 and a nut 59 are screwed together. The nut 59 and the screw shaft portion 43 constitute a motion direction converting portion, and the rotational motion of the nut 59 is converted into a straight motion of the rod 39 in the motion direction converting portion. A gear (not shown) is formed on the outer peripheral surface of the nut 59, and this gear is engaged with the gear 58 attached to the output shaft 57a of the mold thickness adjusting motor 57. The mold thickness adjusting motor 57 is, for example, a servo motor, and includes an encoder portion 57b that detects the rotational speed of the output shaft 57a.

  When the mold thickness adjusting motor 57 rotates, the nut 59 rotates, the rod 39 advances and retreats with respect to the suction plate 22, and the distance between the suction plate 22 and the movable platen 12 is adjusted. Therefore, the gap δ at the completion of mold closing can be set to an optimum value. The mold thickness adjusting motor 57 is feedback-controlled based on the detection result of the encoder unit 57b so that the gap δ becomes a desired value.

  Next, the configuration of the rear platen 13 will be described with reference to FIGS. FIG. 3 is a perspective view showing the rear platen according to the first embodiment. FIG. 4 is a diagram showing a configuration of a plurality of types of electrical steel sheets according to the first embodiment.

  The rear platen 13 has a laminated steel plate formed by laminating a plurality of electromagnetic steel plates in order to reduce eddy currents generated when the magnetic field of the electromagnet 49 changes, such as when clamping is started. The electromagnetic steel sheet may be a steel sheet to which silicon is added, for example. An insulating coating is formed on the surface of the electromagnetic steel sheet.

  For example, as shown in FIG. 3, the rear platen 13 includes two outer laminated steel plates 71 and 72 that are spaced apart in the Y direction, and two inner laminated steel plates that are spaced apart in the Z direction. 73, 74. The two outer laminated steel plates 71 and 72 and the two inner laminated steel plates 73 and 74 define a through hole 41 through which the rod 39 of the rear platen 13 passes.

  The outer laminated steel plates 71 and 72 are formed by laminating a plurality of electromagnetic steel plates 81 and 82 in the Y direction. Adjacent electromagnetic steel sheets may be fixed by welding or may be clamped and fixed by a jig. As shown in FIGS. 4A and 4B, the electromagnetic steel plates 81 and 82 are formed with recesses 81 a and 82 a that constitute the coil groove 45. The electromagnetic steel plates 81 and 82 are formed with insertion holes 81b and 82b for inserting the flow path pipe 91 (see FIGS. 1 and 2). The insertion holes 81b and 82b are arranged as far as possible from the attracting surface (rear end surface) of the rear platen 13 so as not to adversely affect the magnetic field formed by the electromagnet 49.

  The inner laminated steel plates 73 and 74 are disposed between the two outer laminated steel plates 71 and 72. The inner laminated steel plates 73 and 74 are each formed by laminating a plurality of electromagnetic steel plates 83 in the Y direction. As shown in FIG. 4C, the electromagnetic steel plate 83 is formed with a recess 83 a that constitutes the coil groove 45. In addition, the electromagnetic steel plate 83 is formed with an insertion hole 83b for inserting the flow path pipe 91 (see FIGS. 1 and 2). The insertion hole 83b is disposed at a position as far as possible from the adsorption surface (rear end surface) of the rear platen 13 so as not to adversely affect the magnetic field formed by the electromagnet 49.

  The channel tube 91 may penetrate the rear platen 13 in the Y direction. The flow channel 91 penetrates either one of the two outer laminated steel plates 71 and 72 and the two inner laminated steel plates 73 and 74 in the laminating direction (Y direction). In order to control the temperature of both the two inner laminated steel plates 73 and 74, at least two flow channel pipes 91 may be provided. The number of flow channel pipes 91 may be appropriately selected according to the number, shape, and arrangement of laminated steel plates.

  The flow path pipe 91 is, for example, a cylindrical pipe, and has a temperature control fluid flow path therein. Since the temperature control fluid flows through the flow path pipe 91, the temperature control fluid does not leak from between the magnetic steel sheets, unlike the case where the through hole penetrating the laminated steel sheet in the stacking direction becomes the flow path. Further, since the temperature control fluid does not directly contact the rear platen 13, corrosion of the rear platen 13 is prevented.

  The temperature control fluid exchanges heat with the rear platen 13 to control the temperature of the rear platen 13. The temperature control fluid may be a coolant such as cooling water or air. The refrigerant cools the rear platen 13 to suppress overheating of the coil 48 of the electromagnet 49. In order to increase the cooling efficiency, the flow path pipe 91 may be disposed on the back side of the coil groove 45 as viewed from the adsorption plate 22 as shown in FIG. The temperature control fluid may be a heat medium such as warm water.

  The flow path pipe 91 may be inserted into the insertion hole 93 of the rear platen 13 and may be fixed to the insertion hole 93 by, for example, cold fitting or shrink fitting. The insertion hole 93 of the rear platen 13 is composed of insertion holes 81b to 83b of the electromagnetic steel plates 81 to 83.

  In the cold fitting, the flow path pipe 91 is cooled with a refrigerant such as dry ice or liquid nitrogen, the outer diameter of the flow path pipe 91 is reduced, and the rear platen 13 having a higher temperature (for example, room temperature) than the flow path pipe 91 is inserted. The channel pipe 91 is inserted into the hole 93. Thereafter, when the temperature of the channel tube 91 returns to room temperature, the channel tube 91 swells and the outer wall of the channel tube 91 is fastened by the inner wall of the insertion hole 93.

  In shrink fitting, the rear platen 13 is heated to increase the diameter of the insertion hole 93 of the rear platen 13, and the flow path pipe 91 having a temperature lower than that of the rear platen 13 (for example, room temperature) is inserted into the insertion hole 93. Thereafter, when the temperature of the rear platen 13 returns to room temperature, the diameter of the insertion hole 93 is reduced, and the outer wall of the flow channel tube 91 is tightened by the inner wall of the insertion hole 93.

  The gap between the inner wall of the insertion hole 93 and the outer wall of the flow channel pipe 91 is reduced by the cold fitting or shrink fitting, and the contact thermal resistance is lowered, so that the temperature regulation efficiency of the rear platen 13 is improved. The channel tube 91 may be a cylindrical tube, and the insertion hole 93 may have a circular cross-sectional shape so that the outer wall of the channel tube 91 is uniformly tightened by cold fitting or shrink fitting.

  A metal sheet 95 as a heat transfer member may be interposed between the inner wall of the insertion hole 93 of the rear platen 13 and the outer wall of the flow channel pipe 91. The hardness of the metal sheet 95 is preferably lower (softer) than the hardness of the channel tube 91. The hardness of the metal sheet 95 is measured by an indentation hardness test method before cold fitting or shrink fitting. As the indentation hardness test method, for example, the Brinell hardness test method (JIS Z2243) is used. For example, when the metal forming the flow path pipe 91 is stainless steel, the metal of the metal sheet 95 is copper (Cu), aluminum (Al), tin (Sn), lead (Pb), silver (Ag), indium. (In) or an alloy containing any one or more of these is used. Indium or an indium alloy is particularly preferably used from the viewpoint of softness and cost.

  In the cold fitting, the metal sheet 95 is wound around the outer wall of the flow channel tube 91, and the metal sheet 95 and the flow channel tube 91 are inserted into the insertion hole 93 of the rear platen 13. In the cold fitting, before insertion into the insertion hole 93, at least one of the flow path tube 91 and the metal sheet 95 is cooled with a refrigerant.

  For example, when only the flow path pipe 91 is cooled with the refrigerant before insertion into the insertion hole 93, the temperature of the flow path pipe 91 returns to room temperature after insertion into the insertion hole 93, the flow path pipe 91 expands, and the insertion hole 93. The metal sheet 95 is sandwiched between the inner wall and the outer wall of the flow channel tube 91, and deforms thinly. The deformation of the metal sheet 95 may be elastic deformation or plastic deformation. Since the metal sheet 95 is formed of a softer metal than the flow path pipe 91, the metal sheet 95 is deformed so as to absorb the variation in the gap between the inner wall of the insertion hole 93 and the outer wall of the flow path pipe 91, and the gap is filled. It closely contacts both the inner wall of the insertion hole 93 and the outer wall of the channel tube 91.

  In addition, when only the metal sheet 95 is cooled with the refrigerant before insertion into the insertion hole 93 and the thickness of the metal sheet 95 is reduced, the temperature of the metal sheet 95 returns to room temperature after insertion into the insertion hole 93, The metal sheet 95 is sandwiched between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91. The metal sheet 95 is deformed so as to absorb the variation in the gap between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91 to fill the gap, and the metal sheet 95 is formed between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91. Adhere to both.

  In shrink fitting, the metal sheet 95 is wound around the outer wall of the flow path pipe 91 and the metal sheet 95 and the flow path pipe 91 are inserted into the insertion hole 93 of the heated rear platen 13. Thereafter, when the temperature of the rear platen 13 returns to room temperature, the diameter of the insertion hole 93 is reduced, and the metal sheet 95 is sandwiched between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91. The metal sheet 95 is deformed so as to absorb the variation in the gap between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91 to fill the gap, and the metal sheet 95 is formed between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91. Adhere to both.

  Thus, in both cold fitting and shrink fitting, the metal sheet 95 is deformed so as to absorb the variation in the gap between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91, and the gap is filled and inserted. It is in close contact with both the inner wall of the hole 93 and the outer wall of the channel tube 91. Therefore, the contact thermal resistance is further lowered, and the temperature regulation efficiency of the rear platen 13 is further improved. Further, when absorbing the gap variation, the soft metal sheet 95 is selectively deformed and local deformation of the hard flow channel pipe 91 is suppressed, so that damage to the flow path tube 91 is reduced.

  In addition, although the heat transfer member of this embodiment is formed with a metal, it should just have thermal conductivity higher than air, and may be formed with resin. Further, the heat transfer member has a sheet shape, but may have a ring shape.

  In addition, although the flow-path pipe 91 of this embodiment is fixed to the insertion hole 93 by cold fitting or shrink fitting, the fixing method is not limited to cold fitting or shrink fitting. For example, there is a method in which the flow path pipe 91 is inserted into the insertion hole 93, the heated molten resin is poured into the gap between the inner wall of the insertion hole 93 and the outer wall of the flow path pipe 91, and the molten resin is cooled and solidified. is there. In this case, a resin layer as a heat transfer member is interposed between the inner wall of the insertion hole 93 and the outer wall of the flow channel pipe 91. The hardness of the resin layer is lower than the hardness of the channel tube 91.

  The insertion hole 93 of the rear platen 13 extends in the laminating direction (Y direction) of the laminated steel plates (for example, the outer laminated steel plates 71), and extends in the laminating direction from one end portion to the other end portion of the laminated steel plates, for example. Therefore, the flow path pipe 91 inserted into the insertion hole 93 of the rear platen 13 can limit displacement of a plurality of electromagnetic steel plates (for example, the electromagnetic steel plates 81 and 82) constituting the laminated steel plate (for example, the outer laminated steel plate 71).

  The insertion hole 93 of the rear platen 13 is formed over a plurality of laminated steel plates (for example, one of the two outer laminated steel plates 71 and 72 and the two inner laminated steel plates 73 and 74). Therefore, the flow path pipe 91 inserted into the insertion hole 93 of the rear platen 13 can limit the displacement of the plurality of laminated steel plates.

  In the present embodiment, the heat transfer member is interposed between the inner wall of the insertion hole 93 and the outer wall of the flow channel tube 91, but the heat transfer member may not be provided. That is, the inner wall of the insertion hole 93 and the outer wall of the flow channel pipe 91 may be in direct contact with each other by cold fitting or shrink fitting.

[Second Embodiment]
The rear platen 13 of the first embodiment has an insertion hole 93 as an insertion portion for inserting the flow channel tube 91, but the rear platen of the present embodiment is different in that it has an insertion groove. Hereinafter, the difference will be mainly described.

  FIG. 5 is a sectional view showing a rear platen according to the second embodiment. The rear platen 113 shown in FIG. 5 is formed with an insertion groove 193 as an insertion portion, and the flow channel pipe 191 is inserted into the insertion groove 193. The insertion groove 193 is formed on a surface (front end surface) or a side surface opposite to the suction surface of the rear platen 113.

  The flow channel pipe 191 is, for example, a rectangular tube, and has a temperature control fluid flow channel therein. Since the temperature control fluid flows inside the flow channel pipe 191, unlike the case where the through hole penetrating the laminated steel plates in the stacking direction becomes the flow channel, the temperature control fluid does not leak between the electromagnetic steel plates. Further, since the temperature control fluid does not directly contact the rear platen 113, the corrosion of the rear platen 113 is prevented.

  The temperature adjusting fluid exchanges heat with the rear platen 113 to adjust the temperature of the rear platen 113. The temperature control fluid may be a coolant such as cooling water or air. The refrigerant cools the rear platen 113 to suppress overheating of the coil 48 of the electromagnet 49. The temperature control fluid may be a heat medium such as warm water.

  The channel pipe 191 is inserted into the insertion groove 193 of the rear platen 113. The channel tube 191 may be fixed to the insertion groove 193 by, for example, cold fitting or shrink fitting.

  In the cold fitting, the flow path pipe 191 is cooled with a refrigerant such as dry ice or liquid nitrogen and contracted, and then inserted into the insertion groove 193 of the rear platen 113 having a temperature higher than that of the flow path pipe 191 (for example, room temperature). Thereafter, when the temperature of the channel tube 191 returns to room temperature, the channel tube 191 swells, and the outer wall of the channel tube 191 is tightened by inner walls (side walls) of the insertion grooves 193 having a rectangular cross section.

  In shrink fitting, the rear platen 113 is heated to widen the groove width of the insertion groove 193 of the rear platen 113, and the flow path pipe 191 having a temperature lower than the rear platen 113 (for example, room temperature) is inserted into the insertion groove 193. Thereafter, when the temperature of the rear platen 113 returns to room temperature, the groove width of the insertion groove 193 becomes narrower, and the flow path pipe 191 is tightened by the mutually opposing inner walls of the insertion groove 193 having a rectangular cross section.

  The gap between the inner wall of the insertion groove 193 and the outer wall of the channel tube 191 is reduced by the cold fitting or shrink fitting, and the contact thermal resistance is lowered, so that the temperature regulation efficiency of the rear platen 113 is improved.

  A metal sheet 195 as a heat transfer member may be interposed between the inner wall of the insertion groove 193 and the outer wall of the flow channel pipe 191. The hardness of the metal sheet 195 is preferably lower (softer) than the hardness of the channel tube 191.

  In the cold fitting, the metal sheet 195 is wound around the outer wall of the flow path pipe 191, and the metal sheet 195 and the flow path pipe 191 are inserted into the insertion groove 193 of the rear platen 13. In the cold fitting, at least one of the flow channel pipe 191 and the metal sheet 195 is cooled with a refrigerant before being inserted into the insertion groove 193.

  For example, when only the flow channel 191 is cooled with the refrigerant before insertion into the insertion groove 193, the temperature of the flow channel 91 returns to room temperature after insertion into the insertion groove 193, and the inner wall of the insertion groove 193 and the flow channel 191. The metal sheet 195 is sandwiched between the outer wall and the outer wall of the metal, and deforms thinly. The deformation of the metal sheet 195 may be elastic deformation or plastic deformation. Since the metal sheet 195 is formed of a softer metal than the flow channel pipe 191, the metal sheet 195 is deformed so as to absorb the variation in the gap between the inner wall of the insertion groove 193 and the outer wall of the flow channel pipe 191, and the gap is filled. It is in close contact with both the inner wall of the insertion groove 193 and the outer wall of the channel tube 191.

  Further, when only the metal sheet 195 is cooled with the refrigerant before insertion into the insertion groove 193 and the thickness of the metal sheet 195 is reduced, the temperature of the metal sheet 195 returns to room temperature after insertion into the insertion groove 193, and the metal sheet The thickness of 195 is increased, and the metal sheet 195 is sandwiched between the inner wall of the insertion groove 193 and the outer wall of the flow channel tube 191. The metal sheet 195 is deformed so as to absorb the variation in the gap between the inner wall of the insertion groove 193 and the outer wall of the flow channel pipe 191 to fill the gap, and the inner wall of the insertion groove 193 and the outer wall of the flow channel pipe 91 are Adhere to both.

  In shrink fitting, the metal sheet 195 is wound around the outer wall of the channel tube 191, and the metal sheet 195 and the channel tube 191 are inserted into the insertion groove 193 of the heated rear platen 113. Thereafter, when the temperature of the rear platen 113 returns to room temperature, the groove width of the insertion groove 193 becomes narrow, and the metal sheet 195 is sandwiched between the inner wall of the insertion groove 193 and the outer wall of the flow channel tube 191. The metal sheet 195 is deformed so as to absorb the variation in the gap between the inner wall of the insertion groove 193 and the outer wall of the flow path pipe 191 to fill the gap, and the inner wall of the insertion groove 193 and the outer wall of the flow path pipe 191 Adhere to both.

  Thus, in both cold fitting and shrink fitting, the metal sheet 195 is deformed so as to absorb the variation in the gap between the inner wall of the insertion groove 193 and the outer wall of the flow channel pipe 191, and the gap is filled and inserted. The groove 193 is in close contact with both the inner wall and the outer wall of the channel tube 191. Therefore, the contact thermal resistance is further lowered, and the temperature regulation efficiency of the rear platen 113 is further improved. Further, when the variation in the gap is absorbed, the soft metal sheet 195 is selectively deformed, so that local deformation of the hard channel tube 191 is suppressed, and damage to the channel tube 191 is reduced.

  In addition, although the heat transfer member of this embodiment is formed with a metal, it should just have thermal conductivity higher than air, and may be formed with resin. Further, the heat transfer member has a sheet shape, but may have a ring shape.

  In addition, although the flow path pipe | tube 191 of this embodiment is fixed to the insertion groove 193 by cold fitting or shrink fitting, the fixing method is not limited to cold fitting or shrink fitting. For example, there is a method in which the flow path pipe 191 is inserted into the insertion groove 193, the molten resin is poured into a gap between the inner wall of the insertion groove 191 and the outer wall of the flow path pipe 191, and the molten resin is cooled and solidified. is there. In this case, a resin layer as a heat transfer member is interposed between the inner wall of the insertion groove 193 and the outer wall of the flow channel pipe 191. The hardness of the resin layer is lower than the hardness of the channel tube 191.

  The insertion groove 193 of the rear platen 113 extends in the stacking direction (Y direction) of the laminated steel plates (for example, the outer laminated steel plate 71 shown in FIG. 3), and extends in the stacking direction from one end portion to the other end portion of the laminated steel plates, for example. . Therefore, the flow path pipe 191 inserted into the insertion groove 193 of the rear platen 113 can limit the displacement of a plurality of electromagnetic steel plates (for example, the electromagnetic steel plates 81 and 82) constituting the laminated steel plate (for example, the outer laminated steel plate 71).

  The insertion groove 193 of the rear platen 113 is formed over a plurality of laminated steel plates (for example, one of the two outer laminated steel plates 71 and 72 and the two inner laminated steel plates 73 and 74 shown in FIG. 3). Therefore, the flow path pipe 191 inserted into the insertion groove 193 of the rear platen 113 can limit the positional deviation of the plurality of laminated steel plates.

  In addition, although the flow path pipe 191 of this embodiment is an integrated object, it is composed of a bowl-shaped member in which a flow path groove is formed and a lid member fixed to a surface on which the flow path groove of the bowl-shaped member is formed. It may be configured. In this case, after fixing the hook member to the insertion groove 193, the lid member may be fixed to the hook member, or after fixing the lid member to the hook member, the hook member is fixed to the insertion groove 193. May be. A seal member that prevents leakage of the temperature control fluid may be interposed between the bowl-shaped member and the lid member.

  In the present embodiment, the heat transfer member is interposed between the inner wall of the insertion groove 193 and the outer wall of the flow channel tube 191, but the heat transfer member may not be provided. That is, the inner wall of the insertion groove 193 and the outer wall of the flow channel tube 191 may be in direct contact with each other by cold fitting or shrink fitting.

  Although the first and second embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the gist of the present invention described in the claims. Can be modified or replaced.

  For example, although the flow path pipes 91 and 191 of the above embodiment are inserted into the insertion portions 93 and 193 of the rear platens 13 and 113, the present invention may be applied to the suction plate. That is, the channel tubes 91 and 191 may be inserted into the insertion portion of the suction plate 22.

  Moreover, although the flow-path pipes 91 and 191 of the said embodiment are a cylindrical pipe or a rectangular tube, a double pipe may be sufficient. The double pipe is composed of an inner pipe and an outer pipe, and a space between the inner pipe and the outer pipe is a forward path for the temperature control fluid, and an inner space of the inner pipe is a return path for the temperature control fluid. A lid is provided at the tip of the double pipe so as to communicate the forward path and the backward path.

  In addition, the rear platens 13 and 113 of the above embodiment have laminated steel plates formed by laminating a plurality of electromagnetic steel plates, but may not have laminated steel plates, for example, even if cut out from one soft magnetic plate. Good. In this case, since it is not necessary to prevent displacement of the plurality of electromagnetic steel plates, the flow path pipes 91 and 191 do not need to penetrate the rear platens 13 and 113. For example, the flow path pipes 91 and 191 are configured by the above-described double pipes. It can be interrupted.

10 Injection Molding Machine 11 Fixed Platen (First Fixed Member)
12 Movable platen (first movable member)
13 Rear platen (first block, second fixing member)
DESCRIPTION OF SYMBOLS 15 Fixed mold 16 Movable mold 19 Mold apparatus 22 Suction plate (2nd block, 2nd movable member)
23 Through-hole 41 in adsorption plate Rear-plate through-hole 45 Coil groove 46 Core 48 Coil 49 Electromagnets 71-74 Laminated steel plates 81-83 Magnetic steel plate 91 Channel tube 93 Rear platen insertion hole 95 Metal sheet

Claims (4)

A mold clamping force generation mechanism that includes a first block on which an electromagnet is formed and a second block that is attracted by the electromagnet, and generates a mold clamping force between the first block and the second block. Configured,
A channel pipe for flowing a temperature-controlled fluid is inserted into an insertion part formed in at least one of the first block and the second block, and the channel pipe is fixed to the insertion part ,
The at least one of the first block and the second block has a laminated steel plate composed of a plurality of electromagnetic steel plates,
The insertion part is formed in the laminated steel sheet and extends in a lamination direction of the laminated steel sheet .   The injection molding machine according to claim 1, wherein a heat transfer member is interposed between an inner wall of the insertion portion and an outer wall of the flow channel tube. The injection molding machine according to claim 2 , wherein the hardness of the heat transfer member is lower than the hardness of the channel tube. A first fixing member to which a fixed mold is attached;
A first movable member to which a movable mold is attached;
A second movable member that moves with the first movable member;
A second fixed member disposed between the first movable member and the second movable member ;
Of the second movable member and the second fixing member, one is the first block, the injection molding of the other according to any one of claims 1 to 3 which is the second block Machine.

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