CN117213282A

CN117213282A - Heat exchanger of injection molding machine

Info

Publication number: CN117213282A
Application number: CN202311370176.1A
Authority: CN
Inventors: 常桂梅; 严秀娟; 杨波
Original assignee: Zhuzhou Linwu Hydraulic Machinery Co ltd
Current assignee: Guangdong Zhenle Toys Co ltd
Priority date: 2023-10-23
Filing date: 2023-10-23
Publication date: 2023-12-12
Anticipated expiration: 2043-10-23
Also published as: CN117213282B

Abstract

The application belongs to the technical field of heat exchangers, in particular to an injection molding temperature machine heat exchanger, which comprises a cylinder body with a pair of supporting legs below and end covers fixed at two ends of the cylinder body, wherein a material pipeline is arranged on the end covers, one material pipeline is a material feeding pipe, the other material pipeline is a material discharging pipe, a pair of refrigerant pipelines are arranged on the circumferential outer wall of the cylinder body in a penetrating way, one refrigerant pipeline is a refrigerant feeding pipe, the other refrigerant pipeline is a refrigerant discharging pipe, a spiral cooling pipe and a pair of discs are arranged in the cylinder body, the two ends of the cooling pipe are respectively fixed in a first circular opening of the corresponding disc, and the discs rotate under the action of a driving assembly so that the cooling pipe and a refrigerant are in uniform contact. In the application, in the process of heat exchange, the disc rotates around the axis of the disc under the action of the driving assembly, and the cooling tube rotates along with the disc, so that the cooling tube is in uniform contact with the refrigerant in the cylinder body, and the cooling efficiency is improved.

Description

Heat exchanger of injection molding machine

Technical Field

The application relates to the technical field of heat exchangers, in particular to an injection molding temperature machine heat exchanger.

Background

The heat exchanger is also called a cooler, the heat exchanger used by the injection molding temperature machine is generally a shell-and-tube cooler, and is divided into a tube side and a shell side, the liquid running path flowing in the tube is the tube side, the liquid running path flowing outside the tube is the shell side, the wall surface of the tube bundle is the heat transfer surface, and when the temperature difference between the tube bundle and the shell exceeds 50 ℃, a corresponding temperature compensation measure is adopted to eliminate or reduce the thermal stress. Typically water-cooled, predominates.

The existing shell and tube cooler generally designs the cooling tube into a spiral structure, so that fluid materials can be fully contacted with the cooling medium for a longer time, but the cooling medium can be directly contacted with the cooling tube in the heat exchange process of the cooling medium, so that the heat exchange efficiency is effective.

Disclosure of Invention

Based on the technical problems existing in the prior art, the application provides an injection molding temperature machine heat exchanger.

The application provides an injection molding temperature machine heat exchanger, which comprises a cylinder body with a pair of supporting legs below and end covers fixed at two ends of the cylinder body, wherein the end covers are provided with material pipelines, one of the material pipelines is a material feeding pipe, the other material pipeline is a material discharging pipe, a pair of refrigerant pipelines penetrate through the circumference outer wall of the cylinder body, one refrigerant pipeline is a refrigerant feeding pipe, the other refrigerant pipeline is a refrigerant discharging pipe, a spiral cooling pipe and a pair of discs are arranged in the cylinder body, two ends of the cooling pipe are respectively fixed in a first circular opening of the corresponding disc, and the discs rotate around the axis of the discs under the action of a driving assembly so as to enable the cooling pipe to be in uniform contact with refrigerant in the cylinder body.

Preferably, the driving assembly comprises a pair of shaft posts and paddles, the shaft posts are fixed on the outer end faces of the corresponding discs, the paddles are fixedly sleeved at the end parts of the shaft posts, the paddles are opposite to the material pipeline, and the directions of the two paddles are the same.

Preferably, the driving assembly comprises a gear ring, a motor and a gear, wherein the gear ring is fixed on the outer end face of one of the discs, the motor is fixed on one end cover adjacent to the gear ring, the gear is fixed on the output shaft of the motor, and the gear are in meshed connection.

Preferably, a pair of ball bearing rings are fixed in the cylinder and positioned between the two discs, and the ball bearing rings are abutted against the inner end surfaces of the discs.

Preferably, a central shaft which is detachably connected to the discs and penetrates through the cooling pipe is arranged between the two discs, a plurality of stirring blades distributed in annular arrays are fixed on the peripheral outer wall of the central shaft, and the central shaft and the stirring blades are synchronously driven to rotate when the discs rotate so as to stir the refrigerant and promote the refrigerant to uniformly contact with the cooling pipe.

Preferably, the two ends of the central shaft are both fixed with connecting plates, the outer end surface of each connecting plate is fixed with a pair of studs, each stud penetrates through a round hole in the disc, and nuts propped against the disc are connected to the studs in a threaded manner.

Preferably, a pair of sealing plates positioned between the two discs are arranged in the cylinder body, two ends of each sealing plate are respectively attached to the discs, the refrigerant pipelines are fixed in a second round opening on the sealing plates, the free ends of the two sealing plates are respectively provided with a first butt joint plate and a second butt joint plate which can be mutually overlapped, a cooling cavity surrounding the cooling pipe is jointly formed between the two sealing plates and the first butt joint plate and the second butt joint plate, and the two refrigerant pipelines are connected through an adjusting assembly and are used for adjusting the volume of the cooling cavity.

Preferably, the adjusting component comprises an adjusting frame and a pair of hanging rods, the adjusting frame is fixed above the cylinder body through a pair of supporting rods, a pair of sliding grooves are formed in the bottom of the adjusting frame, the sliding grooves are slidably connected with sliding blocks, the hanging rods are fixed at the bottoms of the sliding blocks, the refrigerant pipeline is fixed on a third round opening at the bottom end of the hanging rods, the same two-way screw rod is rotatably connected between the two sliding grooves, and one end of the two-way screw rod penetrates through the adjusting frame and is fixedly provided with a handle.

Compared with the prior art, the application provides an injection molding temperature machine heat exchanger, which comprises the following components

The beneficial effects are that:

1. the utility model provides an injection mould temperature machine heat exchanger, through setting up the cooling tube that can rotate, with refrigerant leading-in barrel of refrigerant inlet pipe to flow from refrigerant discharging pipe, with the leading-in barrel of material inlet pipe of fluid material, the fluid material flows into in the cooling tube next, finally flows from the material discharging pipe, in the in-process that carries out the heat exchange, the disc rotates round self axis under drive assembly's effect, at this moment the cooling tube can follow the disc and rotate together, in order to make the refrigerant uniform contact in cooling tube and the barrel, thereby improve cooling efficiency.

2. The injection molding die temperature machine heat exchanger drives one of the paddles to rotate through the flow force when fluid materials flow in from the material feeding pipe through the first driving assembly, and the paddles synchronously drive the shaft column, the disc and the cooling pipe to rotate.

3. The heat exchanger of the injection molding machine is provided with a second driving component, the motor is connected with a power supply, the output shaft of the motor drives the gear to rotate, the gear engagement drives the gear ring to rotate, and the gear ring synchronously drives the disc and the cooling pipe to rotate together.

4. The injection molding machine heat exchanger is characterized in that the ball bearing rings are arranged, so that the positions of the two discs can be stabilized through the two ball bearing rings, friction resistance can be reduced when the discs rotate, and the rotating process is smoother.

5. The heat exchanger of the injection molding temperature machine synchronously drives the central shaft and the stirring fan blades to rotate when the discs are arranged to rotate, so that the refrigerant can be stirred, the refrigerant is prevented from flowing along the directional flow path, the refrigerant is enabled to be in uniform contact with the cooling pipes, heat exchange between the refrigerant and the cooling pipes is promoted, the central shaft is fixedly reinforced between the two discs, and the stress of the connecting part of the cooling pipes and the discs when the discs rotate is effectively relieved.

6. The heat exchanger of the injection molding machine is provided with the studs, the round holes on the disc are aligned with the studs in a sleeved mode, and then the nuts are screwed on the studs, so that the central shaft can be conveniently installed on the disc.

7. The heat exchanger of the injection molding machine drives two sliding blocks to move close to or away from each other along the sliding groove by arranging a sealing plate and rotating a bidirectional screw rod through a handle, the sliding blocks synchronously drive a hanging rod and a refrigerant pipeline to move, therefore, the distance between the two refrigerant pipelines is adjusted, and the distance between the two sealing plates is adjusted, so that the volume of the cooling cavity is adjusted, and the heat exchange parameters of the heat exchanger can be conveniently controlled.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a heat exchanger of an injection molding temperature machine according to the present application;

FIG. 2 is a schematic diagram of the internal structure of the heat exchanger of the injection molding temperature machine according to the present application;

FIG. 3 is a schematic view of the mounting structure between the disc and the cooling tube of the heat exchanger of the injection molding machine according to the present application;

fig. 4 is a schematic diagram of a gear ring installation structure of the heat exchanger of the injection molding temperature machine;

FIG. 5 is a schematic view of the mounting structure between the central shaft and the disc of the heat exchanger of the injection molding temperature machine according to the present application;

FIG. 6 is an enlarged schematic view of the heat exchanger of the injection molding temperature machine according to the present application;

FIG. 7 is a schematic view of the mounting structure between the sealing plate and the disc of the heat exchanger of the injection molding temperature machine;

FIG. 8 is a schematic diagram of a mating structure between two sealing plates of an injection molding temperature machine heat exchanger according to the present application;

fig. 9 is a schematic diagram of a sectional structure of an adjusting frame of a heat exchanger of an injection molding machine according to the present application.

In the figure: 1. a cylinder; 2. an end cap; 3. a material pipe; 4. a support leg; 5. a disc; 6. a cooling tube; 7. a first round opening; 8. a refrigerant pipe; 9. a shaft post; 10. a paddle; 11. a gear ring; 12. a motor; 13. a gear; 14. a central shaft; 15. stirring fan blades; 16. a connecting plate; 17. a stud; 18. a nut; 19. a sealing plate; 20. a first butt plate; 21. a second butt plate; 22. an adjusting frame; 23. a support rod; 24. a chute; 25. a slide block; 26. a bidirectional screw; 27. a hanging rod; 28. a handle; 29. a second round port; 30. a third round port; 31. a ball bearing ring; 32. and a round hole.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments.

In the description of the present application, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present application and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

Referring to fig. 1-9, the heat exchanger of the injection molding temperature machine comprises a cylinder body 1 with a pair of supporting legs 4 below and end covers 2 fixed at two ends of the cylinder body 1, wherein a material pipeline 3 is installed on the end covers 2, one material pipeline 3 is a material feeding pipe, the other material discharging pipe is a material discharging pipe, a pair of refrigerant pipelines 8 are arranged on the circumferential outer wall of the cylinder body 1 in a penetrating mode, one refrigerant pipeline 8 is a refrigerant feeding pipe, the other material discharging pipe is a refrigerant discharging pipe, a spiral cooling pipe 6 and a pair of discs 5 are arranged in the cylinder body 1, two ends of the cooling pipe 6 are respectively fixed in a first circular opening 7 of the corresponding disc 5, a refrigerant is led into the cylinder body 1 from the refrigerant feeding pipe and flows out of the refrigerant discharging pipe, a fluid material is led into the cylinder body 1 from the material feeding pipe, then flows into the cooling pipe 6, finally flows out of the material discharging pipe, and in the process of heat exchange, the discs 5 rotate around the axis of the cooling pipe 5 under the action of a driving component, at the moment, the cooling pipe 6 rotates along with the discs 5, so that the cooling pipe 6 is in contact with the refrigerant in the cylinder body 1 uniformly, and cooling efficiency is improved.

Further, the driving assembly comprises a pair of shaft posts 9 and paddles 10, the shaft posts 9 are fixed on the outer end faces of the corresponding discs 5, the paddles 10 are fixedly sleeved at the end parts of the shaft posts 9, the paddles 10 are opposite to the material pipeline 3, the two paddles 10 face the same direction, when fluid materials flow in from the material feeding pipe, one of the paddles 10 is driven to rotate through flow force, the paddles 10 synchronously drive the shaft posts 9, the discs 5 and the cooling pipe 6 to rotate, and when the fluid materials flow out from the material discharging pipe, the other paddle 10 is driven to rotate through flow force, so that the rotating speed of the cooling pipe 6 is larger.

Further, the driving assembly comprises a gear ring 11, a motor 12 and a gear 13, wherein the gear ring 11 is fixed on the outer end face of one of the discs 5, the motor 12 is fixed on one end cover 2 adjacent to the gear ring 11, the gear 13 is fixed on an output shaft of the motor 12, the gear 13 is in meshed connection with the gear ring 11, the motor 12 is powered on, the output shaft of the motor 12 drives the gear 13 to rotate, the gear 13 is meshed to drive the gear ring 11 to rotate, and the gear ring 11 synchronously drives the discs 5 and the cooling tube 6 to rotate together.

Further, a pair of ball bearing rings 31 are fixed in the cylinder body 1 and located between the two discs 5, and the ball bearing rings 31 are propped against the inner end surfaces of the discs 5, so that the positions of the two discs 5 can be stabilized through the two ball bearing rings 31, and friction resistance applied to the discs 5 during rotation can be reduced, and the rotation process is smoother.

Further, a central shaft 14 which is detachably connected to the disc 5 and penetrates through the cooling pipe 6 is arranged between the two discs 5, a plurality of stirring blades 15 distributed in annular arrays are fixed on the peripheral outer wall of the central shaft 14, the central shaft 14 and the stirring blades 15 are synchronously driven to rotate when the disc 5 rotates, so that cooling media can be stirred, the cooling media are prevented from flowing along the directional flow path, the cooling media are enabled to be in uniform contact with the cooling pipe 6, heat exchange between the cooling media and the cooling pipe 6 is promoted, and the central shaft 14 is fixedly reinforced between the two discs 5, so that the stress of the connecting part of the cooling pipe 6 and the discs 5 when the disc 5 rotates is effectively relieved.

Further, connecting plates 16 are fixed at two ends of the central shaft 14, a pair of studs 17 are fixed on the outer end face of the connecting plates 16, the studs 17 penetrate through round holes 32 in the disc 5, nuts 18 propped against the disc 5 are connected to the studs 17 in a threaded mode, the round holes 32 in the disc 5 are aligned with the studs 17 to be sleeved in, and then the nuts 18 are screwed on the studs 17, so that the central shaft 14 can be conveniently mounted on the disc 5.

Further, a pair of sealing plates 19 positioned between the two discs 5 are arranged in the cylinder body 1, two ends of each sealing plate 19 are respectively attached to the discs 5, the refrigerant pipeline 8 is fixed in a second round opening 29 on the sealing plates 19, the free ends of the two sealing plates 19 are respectively provided with a first butt plate 20 and a second butt plate 21 which can be mutually overlapped, a cooling cavity surrounding the cooling pipe 6 is jointly formed between the two sealing plates 19 and the first butt plate 20 and the second butt plate 21, the two refrigerant pipelines 8 are connected through an adjusting component, and the distance between the two refrigerant pipelines 8 is adjusted through the adjusting component, so that the distance between the two sealing plates 19 is adjusted, the volume of the cooling cavity is adjusted, and the heat exchange parameters of the heat exchanger can be conveniently controlled.

Further, the adjusting assembly comprises an adjusting frame 22 and a pair of hanging rods 27, the adjusting frame 22 is fixed above the cylinder body 1 through a pair of supporting rods 23, a pair of sliding grooves 24 are formed in the bottom of the adjusting frame 22, sliding blocks 25 are connected in the sliding grooves 24 in a sliding mode, the hanging rods 27 are fixed at the bottoms of the sliding blocks 25, the refrigerant pipeline 8 is fixed on a third round opening 30 in the bottom end of the hanging rods 27, the two sliding grooves 24 are rotatably connected with the same two-way screw 26, the two-way screw 26 is in threaded connection with the sliding blocks 25, one end of the two-way screw 26 penetrates through the adjusting frame 22 and is fixedly provided with a handle 28, the two sliding blocks 25 are driven to move along the sliding grooves 24 in a mutually approaching or separating mode through the handle 28, and the sliding blocks 25 synchronously drive the hanging rods 27 and the refrigerant pipeline 8 to move, so that the distance between the two refrigerant pipelines 8 is adjusted.

Working principle: the refrigerant is led into the cylinder 1 from the refrigerant feeding pipe and flows out from the refrigerant discharging pipe, the fluid material is led into the cylinder 1 from the material feeding pipe, then flows into the cooling pipe 6, finally flows out from the material discharging pipe, when the fluid material flows in from the material feeding pipe in the heat exchange process, one blade 10 is driven to rotate by the flow force, the blade 10 synchronously drives the shaft column 9, the disc 5 and the cooling pipe 6 to rotate, and when the fluid material flows out from the material discharging pipe, the other blade 10 is driven to rotate by the flow force, so that the cooling pipe 6 is uniformly contacted with the refrigerant in the cylinder 1, and the cooling efficiency is improved;

or in the heat exchange process, the motor 12 is connected with a power supply, the output shaft of the motor 12 drives the gear 13 to rotate, the gear 13 is meshed with the gear ring 11 to drive the gear ring 11 to rotate, and the gear ring 11 synchronously drives the disc 5 and the cooling pipe 6 to rotate together;

the disc 5 synchronously drives the central shaft 14 and the stirring fan blades 15 to rotate when rotating, so that the refrigerant can be stirred, and the refrigerant is prevented from flowing directionally along the flow path, so that the refrigerant is enabled to be in uniform contact with the cooling pipe 6, and heat exchange between the refrigerant and the cooling pipe 6 is promoted;

the round hole 32 on the disc 5 is aligned with the stud 17 to be sleeved in, and then the nut 18 is screwed on the stud 17, so that the central shaft 14 can be conveniently installed on the disc 5;

the handle 28 rotates the bidirectional screw 26 to drive the two sliding blocks 25 to move close to or away from each other along the sliding groove 24, and the sliding blocks 25 synchronously drive the hanging rod 27 and the refrigerant pipeline 8 to move, so that the distance between the two refrigerant pipelines 8 is adjusted, the distance between the two sealing plates 19 is adjusted, the volume of the cooling cavity is adjusted, and the heat exchange parameters of the heat exchanger can be conveniently controlled.

The foregoing is only a preferred embodiment of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art, who is within the scope of the present application, should make equivalent substitutions or modifications according to the technical scheme of the present application and the inventive concept thereof, and should be covered by the scope of the present application.

Claims

1. The utility model provides an injection mould temperature machine heat exchanger, has barrel (1) and end cover (2) of fixing at barrel (1) both ends including its below of a pair of landing leg (4), installs material pipeline (3) on end cover (2), and one of them material pipeline (3) are the material inlet pipe, and another is the material discharging pipe, and barrel (1) circumference outer wall runs through and is provided with a pair of refrigerant pipeline (8), and one of them refrigerant pipeline (8) are the refrigerant inlet pipe, and another is the refrigerant discharging pipe, a serial communication port, be provided with spiral cooling tube (6) and a pair of disc (5) in barrel (1), the first round mouth (7) at corresponding disc (5) are fixed respectively at the both ends of cooling tube (6), and disc (5) rotate round self axis under drive assembly's effect to make cooling tube (6) and the interior refrigerant uniform contact of barrel (1).

2. The heat exchanger of an injection molding machine according to claim 1, wherein the driving assembly comprises a pair of shaft posts (9) and paddles (10), the shaft posts (9) are fixed on the outer end surfaces of the corresponding discs (5), the paddles (10) are fixedly sleeved at the end parts of the shaft posts (9), the paddles (10) are opposite to the material pipeline (3), and the directions of the two paddles (10) are the same.

3. The heat exchanger of an injection molding machine according to claim 1, wherein the driving assembly comprises a gear ring (11), a motor (12) and a gear (13), the gear ring (11) is fixed on the outer end surface of one of the discs (5), the motor (12) is fixed on one end cover (2) adjacent to the gear ring (11), the gear (13) is fixed on the output shaft of the motor (12), and the gear (13) is in meshed connection with the gear ring (11).

4. The heat exchanger of an injection molding machine according to claim 1, wherein a pair of ball bearing rings (31) are fixed in the cylinder (1) and are positioned between the two discs (5), and the ball bearing rings (31) are abutted against the inner end surfaces of the discs (5).

5. The heat exchanger of an injection molding temperature machine according to claim 1, wherein a central shaft (14) which is detachably connected to the disc (5) and penetrates through the cooling pipe (6) is arranged between the two discs (5), a plurality of stirring blades (15) distributed in a ring-shaped array are fixed on the circumferential outer wall of the central shaft (14), and the central shaft (14) and the stirring blades (15) are synchronously driven to rotate when the disc (5) rotates so as to stir the refrigerant and promote the refrigerant to uniformly contact with the cooling pipe (6).

6. The heat exchanger of an injection molding temperature machine according to claim 5, wherein connecting plates (16) are fixed at two ends of the central shaft (14), a pair of studs (17) are fixed on the outer end surface of the connecting plates (16), the studs (17) penetrate through round holes (32) in the disc (5), and nuts (18) abutted against the disc (5) are connected to the studs (17) in a threaded mode.

7. The heat exchanger of an injection molding temperature machine according to claim 1, wherein a pair of sealing plates (19) positioned between the two discs (5) are arranged in the cylinder (1), two ends of each sealing plate (19) are respectively attached to the discs (5), the refrigerant pipelines (8) are fixed in second round openings (29) on the sealing plates (19), the free ends of the two sealing plates (19) are respectively provided with a first butt plate (20) and a second butt plate (21) which can be mutually overlapped, a cooling cavity surrounding the cooling pipe (6) is jointly formed between the two sealing plates (19) and the first butt plate (20) and the second butt plate (21), and the two refrigerant pipelines (8) are connected through an adjusting assembly for adjusting the volume of the cooling cavity.

8. The heat exchanger of an injection molding machine according to claim 7, wherein the adjusting assembly comprises an adjusting frame (22) and a pair of hanging rods (27), the adjusting frame (22) is fixed above the cylinder body (1) through a pair of supporting rods (23), a pair of sliding grooves (24) are formed in the bottom of the adjusting frame (22), sliding blocks (25) are slidably connected in the sliding grooves (24), the hanging rods (27) are fixed at the bottom of the sliding blocks (25), the refrigerant pipeline (8) is fixed on a third round opening (30) at the bottom end of the hanging rods (27), the same two-way screw rods (26) are rotatably connected between the two sliding grooves (24), and one ends of the two-way screw rods (26) penetrate through the adjusting frame (22) and are fixedly provided with handles (28).