CN214605496U - Semi-automatic stamping device of insulating barrier - Google Patents

Abstract

The utility model provides a semi-automatic stamping device of insulating barrier, include: processing a workpiece; the guide module comprises two guide chutes, and each guide chute is provided with a sliding chute in which a workpiece can slide; the pushing module comprises a pushing cylinder, a pushing plate is fixed at the front end of the pushing cylinder through a fixing block, a plurality of clamping cylinders are arranged on the side edge of the pushing plate, and the clamping cylinders are respectively used for clamping the workpieces in the two sliding grooves; and the stamping module is arranged above the material guide module and is provided with a stamping head for stamping the machined part in the chute. The utility model provides a stamping device can realize the continuous punching press to insulating barrier, and the punching press is efficient, practices thrift the cost.

Description

Semi-automatic stamping device of insulating barrier

Technical Field

The utility model relates to a parts machining equipment field especially relates to a semi-automatic stamping device of insulating barrier.

Background

The insulating material and various non-metal insulating parts have wide application, and are widely used in the fields of electricians, electronics, automobile industry and the like. Currently, insulation products include a number of families, including GPO-3, epoxy, phenolic, and the like. The processing precision of various insulating materials is high, and the requirement is high, so the equipment for producing and processing the insulating materials has higher requirement.

In the process of processing the insulating parts, the insulating parts are often required to be punched to obtain small parts for various insulating purposes. However, the conventional punching operation of the insulating part cannot realize continuous punching operation, and after each punching operation, the insulating part needs to be manually pulled in to perform the next punching operation. The stamping part of the insulating part manufactured by the stamping equipment has the advantages of great waste of the insulating part, low efficiency, incapability of realizing continuous operation and serious limitation on productivity.

SUMMERY OF THE UTILITY MODEL

The utility model provides a semi-automatic stamping device of insulating barrier can effectively solve above-mentioned problem.

The utility model discloses a realize like this: a semi-automatic stamping device of insulating separator includes:

processing a workpiece;

the guide module comprises two guide chutes, and each guide chute is provided with a sliding chute in which a workpiece can slide;

the pushing module comprises a pushing cylinder, a pushing plate is fixed at the front end of the pushing cylinder through a fixing block, a plurality of clamping cylinders are arranged on the side edge of the pushing plate, and the clamping cylinders are respectively used for clamping the workpieces in the two sliding grooves; and

and the stamping module is arranged above the material guide module and is provided with a stamping head for stamping the machined part in the chute.

As a further improvement, a plurality of sliding groove wheels are uniformly arranged on two sides of the sliding groove of the two guide chutes, so that the workpiece slides in a sliding seam in the sliding groove wheels.

As a further improvement, the material guide module further comprises two backing plates, so that the two material guide grooves are respectively fixed on the two backing plates.

As further improvement, the die-casting die further comprises a workbench, the two base plates are fixed on the workbench, and a demolding hole is formed in the middle of the workbench.

As a further improvement, the propulsion cylinder is fixed on the workbench through a cylinder bracket; one side of the material pushing plate is placed on the two base plates, a sliding table is fixed on the lower surface of the other side of the material pushing plate, the sliding table can slide on a guide rail below the sliding table, and the guide rail is fixed on the workbench.

As a further improvement, a bottom plate is arranged between the two backing plates, a concave template is arranged on the bottom plate, a punching hole which is communicated up and down is arranged between the bottom plate and the concave template, and the punching hole is communicated with a demoulding hole which is arranged in the middle of the workbench up and down.

As a further improvement, the cavity plate is provided with a plurality of guide post holes, the stamping module is provided with a plurality of guide posts, and the guide posts are respectively matched with the guide post holes.

As a further improvement, the front end of the clamping cylinder is provided with an upper clamping block and a lower clamping block, and the workpiece slides to the position between the upper clamping block and the lower clamping block in a sliding seam in the sliding groove wheel.

As a further improvement, the side edges of the two guide chutes are provided with grooves, and both ends of the side edge of the material pushing plate extend forwards to the groove edge, so that the clamping cylinder can clamp the workpiece.

As a further improvement, the punching holes which are communicated up and down between the bottom plate and the concave template are suitable for the punching head.

The utility model has the advantages that:

one is as follows: the utility model discloses in set up guide module, material pushing module and punching press module, set up the baffle box in the guide module, set up the spout on it, the spout both sides are installed and are slided the sheave, make the machined part can slide smoothly along the spout, guarantee the smoothness nature that the machined part step by step passed; the pushing module enables the pushing cylinder to push the pushing plate to reciprocate back and forth and drives the clamping cylinder to reciprocate back and forth through the matching of the pushing cylinder and the clamping cylinder, so that the workpiece is clamped by the clamping cylinder to move step by step; after the punching processing is finished, the air propelling cylinder drives the clamping cylinder to reset after the air propelling cylinder moves by one step pitch, and the next punching operation is carried out; the utility model discloses simple and practical can realize the continuous stamping operation of insulating spare part, and is efficient.

The second step is as follows: the utility model is provided with a clamping cylinder, the front end of the clamping cylinder is provided with an upper clamping block and a lower clamping block, thereby realizing the clamping effect on the machined part; meanwhile, each punching position point of the workpiece can be accurately controlled by controlling the propelling step distance of the propelling cylinder, the distance of each punching position is minimized, and the phenomenon of material waste caused by incapability of controlling the punching position points when the workpiece is manually moved is avoided; the utility model discloses can avoid extravagant material completely, make full use of machined part practices thrift the cost.

And thirdly: the utility model provides a stamping module is equipped with the guide pillar, and the guide pillar hole that sets up in guide pillar and the die board of below cooperatees, and the guide pillar imbeds the guide pillar hole earlier, then the punching press hole in punching press head imbeds die board and the bottom plate again, and the punching press hole accuracy in punching press head embedding die board and the bottom plate has been guaranteed to the accuracy.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a semi-automatic punching device for an insulating partition provided by an embodiment of the present invention.

Fig. 2 is a schematic view of a material guiding module of a semi-automatic punching device for an insulation partition according to an embodiment of the present invention.

Fig. 3 is a schematic structural view of a material pushing module of the semi-automatic punching device for the insulating partition provided by the embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a stamping module of a semi-automatic stamping device for an insulating partition provided by an embodiment of the present invention.

Fig. 5 is a schematic structural view of a clamping cylinder of the semi-automatic punching device for the insulating partition provided by the embodiment of the present invention.

Fig. 6 is an enlarged schematic view of the partial a structure according to fig. 1.

The figures in the drawings are identified as:

1. processing a workpiece;

2. a material guiding module; 21. a material guide chute; 211. a chute;

212. a groove; 22. a sliding sheave; 23. a base plate;

3. a material pushing module; 31. propelling the cylinder; 32. a material pushing plate;

33. a clamping cylinder; 331. an upper clamping block; 332. a lower clamping block;

34. a cylinder support; 35. a sliding table; 36. a guide rail;

4. a stamping module; 41. punching a head; 42. a guide post;

5. a work table;

6. a base plate;

7. a cavity plate; 71. and (4) a guide pillar hole.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the drawings of the embodiments of the present invention are combined to clearly and completely describe the technical solutions of the embodiments of the present invention, and obviously, the described embodiments are some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention. Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

In the description of the present invention, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying any number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1, the embodiment of the utility model provides a semi-automatic stamping device of insulating barrier includes: the stamping die comprises a machined part 1, a material guide module 2, a material pushing module 3, a stamping module 4, a workbench 5, a bottom plate 6 and a concave die plate 7.

Specifically, the material guiding module 2 is fixed on the workbench 5 end to end through two material guiding grooves 21 and two backing plates 23. The two material guide chutes 21 and the two backing plates 23 are respectively fixed on the two backing plates 23, and the material guide chutes 21 and the backing plates 23 are equal in length. In this embodiment, the bottom plate 6 is disposed between the two tie plates 23, and the bottom plate 6 and the tie plates 23 have the same height. A concave template 7 is arranged between the two material guide grooves 21, and the height of the material guide grooves 21 is equal to that of the concave template 7.

As shown in fig. 2, in order to make the workpiece 1 smoothly slide in the material guiding grooves 21, in the material guiding module 2, sliding grooves 211 are provided in both of the material guiding grooves 21, and the sliding grooves 211 of both of the material guiding grooves 21 are located in the same direction. The workpiece 1 can slide in the slide grooves 211 of the two guide chutes 21. A plurality of sliding groove wheels 22 are uniformly arranged on both sides of the sliding groove 211 of the two guide chutes 21, and the sliding groove wheels 22 are symmetrically arranged on both sides of the sliding groove 211. As shown in fig. 6, a sliding slot is provided in the middle of each sliding sheave 22, so that the workpiece 1 slides in the sliding slot in the sliding sheave 22. The workpiece 1 can smoothly slide by arranging the sliding groove 211 and the sliding grooved wheel 22, which is beneficial to the continuous stamping operation of the workpiece 1.

As shown in fig. 3, a material pushing module 3 is further provided, and the material pushing module 3 is located at the middle side of the material guiding module. The material pushing module 3 comprises a pushing cylinder 31, a material pushing plate 32 is fixed at the front end of the pushing cylinder 31 through a fixing block, a plurality of clamping cylinders 33 are arranged on the side edge of the material pushing plate 32, and the clamping cylinders 33 are respectively used for clamping the two workpieces 1 in the sliding grooves 211. In the present embodiment, four clamping cylinders 33 are provided, two of which are located on one side of the ejector plate 32 and the other two of which are located on the other side of the ejector plate 32. Every two clamping cylinders 33 are used for clamping the workpieces 1 on the left material guide groove 21, and the other two clamping cylinders 33 are used for clamping the workpieces 1 on the right material guide groove 21. As shown in fig. 5, the front end of the clamping cylinder 33 is provided with an upper clamping block 331 and a lower clamping block 332, the workpiece 1 is located between the upper clamping block 331 and the lower clamping block 332, and the clamping blocks 331 and the lower clamping block 332 can be used for clamping the workpiece 1. The side edges of the two material guiding grooves 21 are provided with grooves 212, and both ends of the side edge of the material pushing plate 32 extend forwards to the edges of the grooves 212, so that the workpiece 1 can be clamped by the upper clamping block 331 and the lower clamping block 332 of the clamping cylinder 33.

The propulsion cylinder 31 is fixed on the workbench 5 through a cylinder bracket 34; one side of the material pushing plate 32 is placed on the two backing plates 23, the lower surface of the other side of the material pushing plate is fixed with a sliding table 35, the sliding table 35 can slide on a guide rail 36 below the sliding table 35, and the guide rail 36 is fixed on the workbench 5. The pushing cylinder 31 is pushed to drive the material pushing plate 32 to slide on the guide rail 36, so that the material pushing plate 32 moves forward and backward and the clamping cylinder 31 moves forward and backward.

As shown in fig. 4, a stamping module 4 is disposed above the material guiding module 2, and the stamping module 4 is provided with a stamping head 41 for stamping the workpiece 1 in the chute 211. The bottom plate 6 is fixed on the workbench 5, the concave template 7 is fixed on the bottom plate 6, a punching hole which is communicated up and down is arranged between the bottom plate 6 and the concave template 7, and the punching hole which is communicated up and down between the bottom plate 6 and the concave template 7 is adaptive to the punching head 41. After the workpiece 1 is punched by the punch 41, the punched insulating part falls through a punch hole provided in the middle of the bottom plate 6 and the cavity plate 7 and then falls out of a die hole in the middle of the table 5.

The cavity plate 7 is provided with a plurality of guide post holes 71, the stamping module 4 is provided with a plurality of guide posts 42, and the guide posts 42 are respectively matched with the guide post holes 71. When the punching module 4 falls, the guide posts 42 on the punching module firstly enter the guide post holes 71 on the cavity plate 7 to position the punching module 4, and the punching head 41 can be accurately aligned with the punching holes which are communicated up and down between the plate 6 and the cavity plate 7.

The working steps of this embodiment are:

after the semi-automatic punching device of the insulating partition board is connected with an external power supply and an air supply, the workpiece 1 is gradually fed into the middle of the concave template 7 along the chute wheels 22 at the two sides of the chute 211. At this time, the workpiece 1 is held by the upper holding block 331 and the lower holding block 332 at the front end of the holding cylinder 33, the workpiece 1 is pressed downward by the press head 41, and after the press is completed, the press head 41 is separated from the workpiece 1. At this time, the pushing cylinder 31 is pushed forward, which drives the pushing plate 32 and the clamping cylinder 33 forward, thereby driving the workpiece 1 to be pushed forward by a step. After a step advance, the holding cylinder 33 releases the workpiece 1, and at this time, the advancing cylinder 31 advances backward to reset the material pushing plate 32 and the holding cylinder 33. And the next stamping process is started after resetting, so that continuous stamping process operation is realized, the efficiency is high, and the precision is high.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a semi-automatic stamping device of insulating barrier which characterized in that includes:

a workpiece (1);

the guide module (2) comprises two guide chutes (21), and each guide chute (21) is provided with a sliding chute (211) in which a workpiece (1) can slide;

the pushing module (3) comprises a pushing cylinder (31), a pushing plate (32) is fixed at the front end of the pushing cylinder (31) through a fixing block, a plurality of clamping cylinders (33) are arranged on the side edge of the pushing plate (32), and the clamping cylinders (33) are respectively used for clamping the workpieces (1) in the two sliding grooves (211); and

the stamping module (4) is arranged above the material guide module (2), and the stamping module (4) is provided with a stamping head (41) for stamping the machined part (1) in the sliding groove (211).

2. The semi-automatic punching device of the insulation partition board according to claim 1, wherein a plurality of sliding grooved wheels (22) are uniformly installed on both sides of the sliding groove (211) of the two guide chutes (21), so that the workpiece (1) slides in the sliding seam in the sliding grooved wheels (22).

3. The semi-automatic punching device for the insulating partition plate according to claim 1, wherein the material guiding module (2) further comprises two backing plates (23), so that the two material guiding grooves (21) are respectively fixed on the two backing plates (23).

4. The semi-automatic punching device for the insulating partition plate according to claim 3, further comprising a workbench (5), wherein the two base plates (23) are fixed on the workbench (5), and a demolding hole is formed in the middle of the workbench (5).

5. Semi-automatic punching device for insulating partition boards according to claim 4, characterized in that the propulsion cylinder (31) is fixed on the work table (5) by a cylinder bracket (34); one side of each material pushing plate (32) is placed on the two backing plates (23), a sliding table (35) is fixed on the lower surface of the other side of each material pushing plate, each sliding table (35) can slide on a guide rail (36) below each sliding table, and the guide rails (36) are fixed on the working table (5).

6. The semi-automatic punching device for the insulating partition plate according to claim 4, wherein a bottom plate (6) is arranged between the two backing plates (23), a concave template (7) is arranged on the bottom plate (6), a punching hole which is communicated with the upper part and the lower part is arranged between the bottom plate (6) and the concave template (7), and the punching hole is communicated with a demoulding hole which is arranged in the middle of the workbench (5) from the upper part and the lower part.

7. The semi-automatic punching device for the insulation partition according to claim 6, wherein a plurality of guide post holes (71) are formed on the concave die plate (7), a plurality of guide posts (42) are formed on the punching module (4), and the guide posts (42) are respectively matched with the guide post holes (71).

8. The semi-automatic punching device of the insulating partition according to claim 2, characterized in that the front end of the clamping cylinder (33) is provided with an upper clamping block (331) and a lower clamping block (332), and the workpiece (1) slides in a sliding slot in the sliding sheave (22) to between the upper clamping block (331) and the lower clamping block (332).

9. The semi-automatic punching device for the insulation partition board according to claim 8, wherein the two material guiding grooves (21) are provided with grooves (212) at the side edges, and the two ends of the side edge of the material pushing plate (32) extend forwards to the edges of the grooves (212), so that the clamping cylinder (33) can clamp the workpiece (1).

10. Semi-automatic punching device for insulating partition boards according to claim 6, characterized in that punching holes which are communicated up and down between the bottom plate (6) and the cavity plate (7) are adapted to the punching head (41).

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