CN217406370U - Machine shell cooling machine - Google Patents

Abstract

The utility model discloses a machine shell cooling machine, which relates to the technical field of motor automation assembly and comprises a frame, a supporting seat, a plurality of supporting plates for placing the machine shell, a cooling mechanism for cooling the machine shell, a circulating driving mechanism for driving the plurality of supporting plates to circularly and repeatedly feed materials on the supporting seat and a material taking mechanism for moving the cooled machine shell on the supporting plates; the plurality of supporting plates can be circularly and movably positioned on the supporting seat; the circulating driving mechanism is arranged on the supporting seat and feeds materials along the supporting seat; the circular driving mechanism comprises a jacking driving assembly, a feeding driving assembly, a descending driving assembly and a backflow driving assembly which are sequentially distributed around the supporting seat and drive the supporting plate to circularly reciprocate; the cooling, feeding and material taking of the shell are realized automatically by adopting the cooling mechanism, the circulating driving mechanism and the material taking mechanism, the working efficiency is improved, the consistency of the cooling of the shell is ensured, and the cost is reduced.

Description

Machine shell cooling machine

Technical Field

The utility model relates to an automatic equipment field technique of motor especially indicates a machine shell cooler.

Background

Along with economic development, each production factory gradually leads into an automatic production line so as to improve production efficiency and reduce labor cost, a machine shell needs to be heated and assembled firstly and then cooled in the automatic motor assembling process, most of the existing machine shell cooling machines cannot be automatically performed, manual assistance is needed for completion, the labor cost is increased, and the production efficiency is reduced; on the other hand, the existing shell cooling machine has the technical problems of poor cooling precision and low product consistency; therefore, in view of the current situation, it is urgently needed to develop a housing cooler to meet the requirement of practical use.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model discloses to the disappearance that prior art exists, its main purpose is to provide a casing cooler, its cooling, pay-off and the material of having realized the casing through adopting cooling body, circulation actuating mechanism and the feeding agencies automation have improved work efficiency, have guaranteed the refrigerated uniformity of casing, the cost is reduced.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a machine shell cooling machine comprises a machine frame, a supporting seat, a plurality of supporting plates for placing a machine shell, a cooling mechanism for cooling the machine shell, a circulating driving mechanism for driving the plurality of supporting plates to feed materials on the supporting seat in a circulating and reciprocating mode and a material taking mechanism for moving the cooled machine shell on the supporting plates, wherein a workbench for installing the supporting seat and the material taking mechanism is arranged on the machine frame; the plurality of supporting plates can be circularly and movably positioned on the supporting seat; the cooling end of the cooling mechanism faces the shell on the supporting plate; the circulating driving mechanism is arranged on the supporting seat and feeds materials along the supporting seat; the material taking mechanism is positioned beside the supporting seat; the circulating driving mechanism comprises a jacking driving assembly, a feeding driving assembly, a descending driving assembly and a backflow driving assembly which are sequentially distributed around the supporting seat and drive the supporting plate to circularly and reciprocally move.

As a preferred embodiment: the circulating driving mechanism also comprises a first supporting and connecting component for receiving or loosening the supporting plate lifted by the lifting driving component and a second supporting and connecting component for supporting or loosening the supporting plate lowered by the lowering driving component, the first supporting and connecting component and the second supporting and connecting component are both arranged on the supporting seat, and the supporting end of the first supporting and connecting component and the supporting end of the second supporting and connecting component correspond to the feeding end of the feeding driving component.

As a preferred embodiment: the first supporting and connecting assemblies and the second supporting and connecting assemblies are two groups, the two groups of first supporting and connecting assemblies are symmetrically distributed on two sides of the jacking driving assembly, and the two groups of second supporting and connecting assemblies are symmetrically distributed on two sides of the descending driving assembly.

As a preferred scheme: the jacking driving assembly and the descending driving assembly respectively comprise a vertical driving device and a vertical sliding plate, the vertical driving device is vertically arranged on the workbench, the vertical sliding plate is arranged at the output end of the vertical driving device, and the supporting plate is positioned on the vertical sliding plate.

As a preferred embodiment: the feeding driving assembly and the backflow driving assembly respectively comprise a longitudinal driving device and a longitudinal shifting block, the longitudinal driving device is longitudinally arranged on the workbench, the longitudinal shifting block is arranged at the output end of the longitudinal driving device, the longitudinal shifting block can be longitudinally and movably abutted against the outer side wall of the supporting plate, and the longitudinal driving device drives the longitudinal shifting block to drive the supporting plate to move.

As a preferred scheme: the first supporting and connecting assembly and the second supporting and connecting assembly respectively comprise a transverse driving cylinder and a transverse supporting and connecting plate, the transverse driving cylinder is transversely arranged on the side wall of the supporting seat, the transverse supporting and connecting plate is arranged at the shaft end of the transverse driving cylinder, and the transverse supporting and connecting plate can transversely movably support and connect the supporting plate.

As a preferred scheme: the two inner side walls of the supporting seat are provided with a first supporting plate and a second supporting plate which are used for supporting the supporting plate, the first supporting plate is located above the second supporting plate, the first supporting plate is located beside the feeding driving assembly, the second supporting plate is located beside the backflow driving assembly, and the first supporting plate and the second supporting plate are symmetrically arranged.

As a preferred embodiment: the cooling mechanism comprises a blower and a cooling pipe, the blower is arranged in the rack, the blower is connected with the cooling pipe, and the cooling pipe faces the machine shell.

As a preferred embodiment: an air inlet is formed in one end of the cooling pipe in an open mode, the other end of the cooling pipe is arranged in a closed mode, an air outlet is formed in the side wall of the cooling pipe, and the air outlet faces the machine shell.

As a preferred embodiment: the material taking mechanism comprises a support, a transverse moving driving assembly, a lifting driving assembly and a clamping cylinder, wherein the transverse moving driving assembly is transversely arranged on the support, the lifting driving assembly is vertically arranged at the output end of the transverse moving driving assembly, and the clamping cylinder is arranged at the output end of the lifting driving assembly.

Compared with the prior art, the utility model has obvious advantages and beneficial effects, concretely speaking, according to the technical scheme, the cooling, feeding and taking of the casing are realized automatically by adopting the cooling mechanism, the circulating driving mechanism and the material taking mechanism, the working efficiency is improved, the consistency of casing cooling is ensured, and the cost is reduced; the circular reciprocating movement of the supporting plates among the jacking driving assembly, the feeding driving assembly, the descending driving assembly and the backflow driving assembly is realized through the circular driving mechanism, and the shells on the plurality of supporting plates are sequentially moved backwards and longitudinally for feeding; the first supporting and connecting assembly and the second supporting and connecting assembly are adopted to improve the accuracy of the position of the supporting plate, ensure the stability of the position movement of the supporting plate, save the energy consumption of the vertical driving device and reduce the cost.

To illustrate the structural features and functions of the present invention more clearly, the following detailed description is given with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a schematic view of a three-dimensional structure of a cooling machine of a housing of the present invention;

FIG. 2 is a schematic view of the three-dimensional structure of the circulation driving mechanism of the present invention;

fig. 3 is a schematic perspective view of the jacking driving assembly of the present invention;

fig. 4 is a schematic view of a three-dimensional structure of the material taking mechanism of the present invention.

The attached drawings indicate the following:

in the figure: 10. a frame; 11. a work table; 20. a supporting base; 21. a first support plate; 22. a second support plate; 30. a support plate; 40. a cooling mechanism; 41. a blower; 42. a cooling tube; 43. an air inlet; 50. a circulating drive mechanism; 51. a jacking driving component; 511. a vertical drive device; 512. a vertical slide plate; 52. a feed drive assembly; 521. a longitudinal driving device; 522. a longitudinal shifting block; 53. a descent drive assembly; 54. a reflux drive assembly; 55. a first docking assembly; 56. a second docking assembly; 561. a transverse driving cylinder; 562. transversely supporting and connecting the plates; 60. a material taking mechanism; 61. a support; 62. a traverse driving assembly; 621. a transverse driving motor; 622; a transverse screw rod; 623. a transverse slide carriage; 63. a lift drive assembly; 631. a lifting drive motor; 632. a lifting slide seat; 633. and clamping the cylinder.

Detailed Description

The utility model discloses as shown in fig. 1 to fig. 4, a machine shell cooler, including frame 10, supporting seat 20, a plurality of layer board 30 that are used for placing the casing, be used for cooling off the cooling body 40 of casing, be used for driving a plurality of layer boards 30 the circulation actuating mechanism 50 of the reciprocal pay-off of circulation on supporting seat 20 and be used for moving the extracting mechanism 60 who gets the casing that has cooled off on layer board 30, wherein:

a worktable 11 for installing the supporting seat 20 and the material taking mechanism 60 is arranged on the frame 10; the plurality of pallets 30 are circularly and movably positioned on the support base 20; the cooling end of the cooling mechanism 40 faces the enclosure on the pallet 30; the circulating driving mechanism 50 is arranged on the supporting seat 20 and feeds along the supporting seat 20; the material taking mechanism 60 is positioned beside the supporting seat 20; the circulating driving mechanism 50 includes a jacking driving assembly 51, a feeding driving assembly 52, a descending driving assembly 53 and a backflow driving assembly 54 which are sequentially distributed around the supporting base 20 and drive the supporting plate 30 to circularly reciprocate.

The machine shell is placed on the supporting plate 30, the jacking driving component 51 drives the supporting plate 30 to ascend to the position of the feeding driving component 52, the feeding driving component 52 drives the supporting plate 30 to longitudinally move for feeding, the cooling mechanism 40 cools the machine shell on the supporting plate 30, the material taking mechanism 60 takes the cooled machine shell on the rear supporting plate 30 away, the descending driving component 53 drives the supporting plate 30 to descend from the position of the feeding driving component 52 to the position of the backflow driving component 54, the backflow driving component 54 drives the supporting plate 30 to longitudinally move forwards and backflow to the jacking driving component 51, and circulation is performed in sequence, so that the circulating reciprocating movement of the supporting plate 30 among the jacking driving component 51, the feeding driving component 52, the descending driving component 53 and the backflow driving component 54 is realized, and the machine shell on the plurality of supporting plates 30 is longitudinally moved backwards and fed in sequence; the cooling, feeding and taking of the machine shell are automatically realized by adopting the cooling mechanism 40, the circulating driving mechanism 50 and the taking mechanism 60, the working efficiency is improved, the cooling consistency of the machine shell is ensured, and the cost is reduced.

A first supporting plate 21 and a second supporting plate 22 for supporting the supporting plate 30 are arranged on two inner side walls of the supporting seat 20, the first supporting plate 21 is positioned above the second supporting plate 22, the first supporting plate 21 is positioned beside the feeding driving component 52, the second supporting plate 22 is positioned beside the backflow driving component 54, and the first supporting plate 21 and the second supporting plate 22 are symmetrically arranged; the feeding driving assembly 52 drives the supporting plate 30 to move longitudinally on the first supporting plate 21 for feeding, and the backflow driving assembly 54 drives the supporting plate 30 to move longitudinally on the second supporting plate 22 for backflow of the supporting plate 30.

The cooling mechanism 40 includes a blower 41 and a cooling pipe 42, the blower 41 is installed in the frame 10, the blower 41 is connected to the cooling pipe 42, and the cooling pipe 42 faces the cabinet; the mode that adopts air-blower 41 and cooling tube 42 has guaranteed that the bulk temperature is unchangeable, has avoided appearing the comdenstion water and then causing the phenomenon of damage to the casing because of temperature variation.

An air inlet 43 is arranged at an opening of one end of the cooling pipe 42, the other end is arranged in a closed manner, an air outlet is arranged on the side wall of the cooling pipe 42, and the air outlet faces the machine shell; the air of the blower 41 enters the cooling pipe 42 from the air inlet 43, the other end of the cooling pipe 42 is closed to ensure the air outlet efficiency, and the air can only blow to the machine shell from the air outlet.

The circulating driving mechanism 50 further comprises a first supporting and connecting component 55 for receiving or releasing the supporting plate 30 lifted by the lifting driving component 51 and a second supporting and connecting component 56 for supporting or releasing the supporting plate 30 lowered by the lowering driving component 53, the first supporting and connecting component 55 and the second supporting and connecting component 56 are both installed on the supporting base 20, and the supporting and connecting end of the first supporting and connecting component 55 and the supporting and connecting end of the second supporting and connecting component 56 both correspond to the feeding end of the feeding driving component 52.

After the first supporting and connecting assembly 55 supports the supporting plate 30 lifted by the lifting and connecting assembly 51, the feeding driving assembly 52 drives the supporting plate 30 to move longitudinally for feeding, after the material taking mechanism 60 takes materials, the second supporting and connecting assembly 56 releases the supporting plate 30, and the descending driving assembly 53 drives the supporting plate 30 to descend, so that the position moving accuracy of the supporting plate 30 is improved.

The first supporting components 55 and the second supporting components 56 are both two groups, the two groups of first supporting components 55 are symmetrically distributed on two sides of the jacking driving component 51, and the two groups of second supporting components 56 are symmetrically distributed on two sides of the descending driving component 53; the balance of the whole structure is improved, and the whole stability is ensured.

The jacking driving assembly 51 and the descending driving assembly 53 each comprise a vertical driving device 511 and a vertical sliding plate 512, the vertical driving device 511 is vertically installed on the workbench 11, the vertical sliding plate 512 is installed at the output end of the vertical driving device 511, and the supporting plate 30 is located on the vertical sliding plate 512; this vertical drive device 511 drives the actuating cylinder for vertical, and this vertical slide 512 is installed in the vertical axle head that drives the actuating cylinder that drives, and this vertical drive drives the lift of vertical slide 512, and the lift of vertical slide 512 drives layer board 30 and goes up and down.

The feeding driving assembly 52 and the backflow driving assembly 54 both include a longitudinal driving device 521 and a longitudinal shifting block 522, the longitudinal driving device 521 is longitudinally mounted on the worktable 11, the longitudinal shifting block 522 is mounted at an output end of the longitudinal driving device 521, the longitudinal shifting block 522 is longitudinally movably abutted against an outer side wall of the supporting plate 30, and the longitudinal driving device 521 drives the longitudinal shifting block 522 to drive the supporting plate 30 to move.

The longitudinal driving device 521 is a longitudinal driving cylinder, the longitudinal shifting block 522 is mounted at the shaft end of the longitudinal driving cylinder, the longitudinal driving cylinder drives the longitudinal shifting block 522 to move longitudinally, and the longitudinal shifting block 522 moves to drive the supporting plate 30 to move longitudinally; specifically, the vertical driving device 511 of the jacking driving assembly 51 drives the vertical sliding plate 512 of the jacking driving assembly 51 to ascend to the position of the feeding driving assembly 52; the longitudinal driving device 521 of the feeding driving assembly 52 drives the longitudinal shifting block 522 of the feeding driving assembly 52 to move backwards and longitudinally, and the plurality of supporting plates 30 move backwards and longitudinally; the cooling mechanism 40 cools the housing on the pallet 30; the material taking mechanism 60 takes the cooled machine shell on the rear side supporting plate 30 away; the vertical driving device 511 of the descending driving assembly 53 drives the vertical sliding plate 512 of the descending driving assembly 53 to descend, so as to lower the pallet 30 from the position of the feeding driving assembly 52 to the position of the backflow driving assembly 54; the longitudinal driving device 521 of the reflow driving assembly 54 drives the longitudinal shifting block 522 of the reflow driving assembly 54 to move forward and longitudinally, so that the pallet 30 taken out of the chassis moves forward and longitudinally and reflows to the lift driving assembly 51; the sequential circulation realizes the cyclic reciprocating movement of the supporting plates 30 among the jacking driving assembly 51, the feeding driving assembly 52, the descending driving assembly 53 and the backflow driving assembly 54, and sequentially moves the machine shell on the plurality of supporting plates 30 backwards and longitudinally for feeding.

The first supporting and connecting assembly 55 and the second supporting and connecting assembly 56 each include a transverse driving cylinder 561 and a transverse supporting and connecting plate 562, the transverse driving cylinder 561 is transversely installed on the side wall of the supporting base 20, the transverse supporting and connecting plate 562 is installed at the shaft end of the transverse driving cylinder 561, and the transverse supporting and connecting plate 562 can transversely movably support and connect the supporting plate 30.

The transverse driving cylinder 561 drives the transverse supporting plate 562 to move transversely, when the supporting plate 30 needs to be supported and received, the transverse supporting plate 562 extends transversely forwards to support and receive the supporting plate 30, and when the supporting plate 30 goes up and down, the transverse supporting plate 562 retracts transversely backwards to give way for the lifting and moving of the supporting plate 30; although the vertical driving device 511 of the jacking driving assembly 51 can be used for lifting the supporting plate 30 and keeping the supporting plate 30 at the position of the feeding driving assembly 52, and the vertical driving device 511 of the descending driving assembly 53 can be used for keeping the supporting plate 30 at the position of the feeding driving assembly 52 and descending the supporting plate 30 to the position of the backflow driving assembly 54, the first supporting assembly 55 and the second supporting assembly 56 are used for improving the accuracy of the position of the supporting plate 30, ensuring the stability of the position movement of the supporting plate 30, saving the energy consumption of the vertical driving device 511 and reducing the cost.

This feeding agencies 60 includes support 61, sideslip drive assembly 62, lift drive assembly 63 and die clamping cylinder 633, and this sideslip drive assembly 62 is horizontal installs on support 61, and the vertical output that installs in sideslip drive assembly 62 of this lift drive assembly 63, this die clamping cylinder 633 install in the output of lift drive assembly 63.

The transverse moving driving assembly 62 comprises a transverse driving motor 621, a transverse screw rod 622 and a transverse sliding seat 623, the transverse driving motor 621 is transversely mounted on the bracket 61, the transverse screw rod 622 is connected to the shaft end of the transverse driving motor 621, and the transverse screw rod 622 is in rotating fit with the transverse sliding seat 623; the lifting driving assembly 63 comprises a lifting driving motor 631, a lifting screw and a lifting slide 632, wherein the lifting driving motor 631 is mounted on the transverse slide 623, the lifting screw is mounted at the shaft end of the lifting driving motor 631, the lifting screw is in rotating fit with the lifting slide 632, and the clamping cylinder 633 is mounted on the lifting slide 632; the transverse moving driving component 62 drives the lifting driving component 63 to move transversely together with the clamping cylinder 633, and the lifting driving component 63 drives the clamping cylinder 633 to lift; meets the requirement of the position movement of the casing

The use method and the principle of the shell cooler are as follows:

the casing is placed on the layer board, jacking drive assembly drive layer board rises to pay-off drive assembly position, pay-off drive assembly drive layer board longitudinal movement pay-off, cooling body cools off the casing on the layer board, the chassis that has cooled off on the rear side layer board is taken away to the extracting mechanism, decline drive assembly drive layer board is descended to backward flow drive assembly position by pay-off drive assembly position, backward flow drive assembly drive layer board longitudinal movement backward flow to jacking drive assembly forward, circulate in proper order.

The utility model is mainly designed to realize the cooling, feeding and taking of the casing automatically by adopting the cooling mechanism, the circulating driving mechanism and the material taking mechanism, thereby improving the working efficiency, ensuring the consistency of the cooling of the casing and reducing the cost; the circular reciprocating movement of the supporting plates among the jacking driving assembly, the feeding driving assembly, the descending driving assembly and the backflow driving assembly is realized through the circular driving mechanism, and the shells on the plurality of supporting plates are sequentially moved backwards and longitudinally for feeding; the first supporting and connecting assembly and the second supporting and connecting assembly are adopted to improve the accuracy of the position of the supporting plate, ensure the stability of the position movement of the supporting plate, save the energy consumption of the vertical driving device and reduce the cost.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any slight modification, equivalent change and modification made by the technical spirit of the present invention to the above embodiments are all within the scope of the technical solution of the present invention.

Claims (10)

1. A housing cooler characterized by; the machine comprises a rack, a supporting seat, a plurality of supporting plates for placing a machine shell, a cooling mechanism for cooling the machine shell, a circulating driving mechanism for driving the plurality of supporting plates to feed materials on the supporting seat in a circulating and reciprocating manner, and a material taking mechanism for taking the cooled machine shell on the supporting plates, wherein a workbench for installing the supporting seat and the material taking mechanism is arranged on the rack; the plurality of supporting plates can be circularly and movably positioned on the supporting seat; the cooling end of the cooling mechanism faces to the shell on the supporting plate; the circulating driving mechanism is arranged on the supporting seat and feeds materials along the supporting seat; the material taking mechanism is positioned beside the supporting seat; the circulating driving mechanism comprises a jacking driving assembly, a feeding driving assembly, a descending driving assembly and a backflow driving assembly which are sequentially distributed around the supporting seat and drive the supporting plate to move circularly and reciprocally.

2. The shell cooler of claim 1, wherein: the circulating driving mechanism also comprises a first supporting and connecting component for receiving or loosening the supporting plate lifted by the lifting driving component and a second supporting and connecting component for supporting or loosening the supporting plate lowered by the lowering driving component, the first supporting and connecting component and the second supporting and connecting component are both arranged on the supporting seat, and the supporting end of the first supporting and connecting component and the supporting end of the second supporting and connecting component correspond to the feeding end of the feeding driving component.

3. The shell cooler of claim 2, wherein: the first supporting and connecting assemblies and the second supporting and connecting assemblies are respectively in two groups, the two groups of first supporting and connecting assemblies are symmetrically distributed on two sides of the jacking driving assembly, and the two groups of second supporting and connecting assemblies are symmetrically distributed on two sides of the descending driving assembly.

4. The cabinet cooler of claim 1, wherein: the jacking driving assembly and the descending driving assembly respectively comprise a vertical driving device and a vertical sliding plate, the vertical driving device is vertically arranged on the workbench, the vertical sliding plate is arranged at the output end of the vertical driving device, and the supporting plate is positioned on the vertical sliding plate.

5. The shell cooler of claim 4, wherein: the feeding driving assembly and the backflow driving assembly respectively comprise a longitudinal driving device and a longitudinal shifting block, the longitudinal driving device is longitudinally arranged on the workbench, the longitudinal shifting block is arranged at the output end of the longitudinal driving device, the longitudinal shifting block can be longitudinally abutted against the outer side wall of the supporting plate in a movable mode, and the longitudinal driving device drives the longitudinal shifting block to drive the supporting plate to move.

6. The shell cooler of claim 2, wherein: the first supporting and connecting assembly and the second supporting and connecting assembly respectively comprise a transverse driving cylinder and a transverse supporting and connecting plate, the transverse driving cylinder is transversely arranged on the side wall of the supporting seat, the transverse supporting and connecting plate is arranged at the shaft end of the transverse driving cylinder, and the transverse supporting and connecting plate can transversely movably support and connect the supporting plate.

7. The cabinet cooler of claim 1, wherein: the two inner side walls of the supporting seat are provided with a first supporting plate and a second supporting plate which are used for supporting the supporting plate, the first supporting plate is located above the second supporting plate, the first supporting plate is located beside the feeding driving assembly, the second supporting plate is located beside the backflow driving assembly, and the first supporting plate and the second supporting plate are symmetrically arranged.

8. The shell cooler of claim 1, wherein: the cooling mechanism comprises a blower and a cooling pipe, the blower is arranged in the rack, the blower is connected with the cooling pipe, and the cooling pipe faces the machine shell.

9. The cabinet cooler of claim 8, wherein: an air inlet is formed in one end of the cooling pipe in an open mode, the other end of the cooling pipe is arranged in a closed mode, an air outlet is formed in the side wall of the cooling pipe, and the air outlet faces the machine shell.

10. The shell cooler of claim 1, wherein: the material taking mechanism comprises a support, a transverse moving driving assembly, a lifting driving assembly and a clamping cylinder, wherein the transverse moving driving assembly is transversely arranged on the support, the lifting driving assembly is vertically arranged at the output end of the transverse moving driving assembly, and the clamping cylinder is arranged at the output end of the lifting driving assembly.

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