CN114453533B - Shaping and corner cutting pneumatic device for inductance coil - Google Patents

Abstract

The invention relates to the technical field of coil processing equipment and discloses an inductance coil shaping and corner cutting pneumatic device which comprises a bottom plate, a coil main body and a workbench arranged at the upper end of the bottom plate, wherein a first shaping assembly, a first corner cutting assembly, a second shaping assembly and a second corner cutting assembly are respectively arranged around the workbench, the first shaping assembly and the second shaping assembly are oppositely arranged and mutually matched for shaping a thread end, and the first corner cutting assembly and the second corner cutting assembly are oppositely arranged and mutually matched for cutting the thread end; the upper end of workstation installs the connecting plate, and the upper end of connecting plate is installed and is used for placing coil body place the subassembly and is used for the centre gripping subassembly of centre gripping coil body. According to the invention, by adopting the pair of shaping assemblies and the pair of corner cutting assemblies, the integrated automatic treatment of coil shaping and corner cutting operation can be realized, and meanwhile, the efficiency and the accuracy in the shaping and cutting process are greatly improved.

Description

Shaping and corner cutting pneumatic device for inductance coil

Technical Field

The invention relates to the technical field of coil processing equipment, in particular to an inductance coil shaping and corner cutting pneumatic device.

Background

Inductance coils are widely used in various mechanical devices, and the manufacturing process of the inductance coils comprises winding and corner cutting, and because the coil is provided with more bent wire ends or pins during winding, if the wire ends or pins are not corrected and cut off directly, the lengths of two wire ends or pins of one inductance coil are inconsistent, and therefore the coil needs to be corrected and then corner cut before being used.

The patent with the application number of CN2016208105557 discloses an inductance coil corner cutting machine, which comprises a machine base, wherein a cutter rest, a correction plate, a pressing block and a group of pressing pieces are arranged on the machine base, the inductance coil is pressed on the machine base by the pressing pieces during operation, pins are placed in pin grooves, and a cylinder is used for pushing a cutting knife to cut off the pins. The corner cutting machine is simple and quick to operate, and can ensure that the length of the pins after being cut off is consistent. However, when the structure is used, the pins cannot be shaped to be smooth before cutting, and the pins are required to be manually pulled to the pin grooves in the cutting process and then fixed, so that the automation degree is low and the cutting efficiency is low. The application provides an inductance coil shaping and corner cutting pneumatic device which can automatically perform shaping and cutting processing and improve cutting efficiency.

Disclosure of Invention

The invention aims to provide an inductance coil shaping and corner cutting pneumatic device, which aims to solve the technical problems that coil corner cutting equipment cannot shape coils and cutting efficiency is low in the prior art.

The aim of the invention can be achieved by the following technical scheme:

The utility model provides an inductance coil plastic chamfer pneumatic means, includes bottom plate, coil main part and installs the workstation in the bottom plate upper end, first plastic subassembly, first chamfer subassembly, second plastic subassembly and second chamfer subassembly are installed respectively around the workstation, first plastic subassembly sets up relatively and mutually support with the second plastic subassembly for the end of a thread plastic, first chamfer subassembly sets up relatively and mutually support with the second chamfer subassembly for the end of a thread is cut;

The upper end of workstation is installed the connecting plate, the upper end of connecting plate is installed and is used for placing the subassembly of placing of coil main part and is used for the centre gripping subassembly of centre gripping coil main part.

As a further scheme of the invention: the first shaping assembly comprises a first shaping block, a first shaping sliding seat and a first shaping air cylinder, wherein the first shaping block is fixedly connected to the first shaping sliding seat, and the output end of the first shaping air cylinder is connected with the first shaping sliding seat and pushes the first shaping sliding seat to slide in the workbench.

As a further scheme of the invention: the second shaping assembly comprises a second shaping block, a second shaping sliding seat and a second shaping air cylinder, wherein the second shaping block is fixedly connected to the second shaping sliding seat, the second shaping block and the first shaping block are kept at the same height, and the output end of the second shaping air cylinder is connected with the second shaping sliding seat and pushes the second shaping sliding seat to slide in the workbench.

As a further scheme of the invention: the first corner cutting assembly comprises a first cutter, a first pushing block, a first corner cutting sliding seat and a first corner cutting air cylinder, wherein the first cutter is connected with the first pushing block, the first pushing block is fixedly connected to the first corner cutting sliding seat, and the output end of the first corner cutting air cylinder is connected with the first corner cutting sliding seat and pushes the first corner cutting sliding seat to slide in the workbench.

As a further scheme of the invention: the second corner cutting assembly comprises a second cutter, a second push block, a second corner cutting slide seat and a second corner cutting air cylinder, wherein the second cutter is connected with the second push block, the second cutter and the first cutter are kept at the same height, the second push block is fixedly connected to the second corner cutting slide seat, and the output end of the second corner cutting air cylinder is connected with the second corner cutting slide seat and pushes the second corner cutting slide seat to slide in the workbench.

As a further scheme of the invention: slide rail tables are arranged on the periphery of the workbench, and each slide rail table is in sliding fit with the corresponding first shaping slide seat, second shaping slide seat, first corner cutting slide seat and second corner cutting slide seat.

As a further scheme of the invention: the blanking device is characterized in that a blanking opening is formed in the central position of the workbench, surrounding baffles which are arranged in a hollow mode are integrally connected to the peripheral edges of the blanking opening, springs are arranged on the periphery of the outer sides of the surrounding baffles, and the springs face to the first shaping sliding seat, the second shaping sliding seat, the first corner cutting sliding seat and the second corner cutting sliding seat which are opposite to each other.

As a further scheme of the invention: the lower end four corners of bottom plate equipartition has the supporting legs, the bottom plate upper end is provided with the cylinder mount pad respectively with first plastic cylinder, second plastic cylinder, first corner cut cylinder and the corresponding position of second corner cut cylinder.

As a further scheme of the invention: the coil assembly comprises a first placing block and a second placing block, an arc-shaped groove for placing the coil body is formed between the first placing block and the second placing block, and a discharge outlet for passing through the wire end is formed in the arc-shaped groove in a penetrating mode.

As a further scheme of the invention: the clamping assembly comprises two groups of triangular clamping blocks which are oppositely arranged, the back side of each triangular clamping block is connected with one end of a push rod, the other end of each push rod is rotationally connected with a screw rod, support plates are symmetrically fixed on the connecting plates, screw threads penetrate through the corresponding support plates, a limiting cylinder is connected to the support plates, and the push rods are in sliding fit with the limiting cylinders.

The invention has the beneficial effects that:

(1) According to the invention, the pair of shaping assemblies and the pair of corner cutting assemblies are adopted, after the coil main body is placed, the coil head can be trimmed and regulated through the first shaping block and the second shaping block, and meanwhile, the coil head is cut off through the first cutter and the second cutter, so that the integrated automatic treatment of coil shaping and corner cutting operation is realized, and the efficiency and the accuracy in the shaping and cutting process are greatly improved;

(2) According to the coil body shaping and cutting device, the coil body can be conveniently and quickly positioned by adopting the placement component and the clamping component, and meanwhile, the coil body is clamped and fixed by utilizing the triangular clamping jaws at two sides, so that the stability of the coil body in the shaping and cutting process is improved, and the influence on shaping and cutting quality caused by shaking of the coil body is avoided;

(3) According to the invention, by arranging the surrounding baffle, the blocking buffer effect on the corresponding sliding seat can be realized on the premise of not interfering with shaping and cutting operations, so that excessive movement or too fast movement of the shaping block or the cutter can be avoided, the loss of the shaping block or the cutter due to impact collision is prevented from being aggravated, and the service life is prolonged.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a first shaping assembly according to the present invention;

FIG. 3 is a schematic view of the structure of the workbench before assembly in the invention;

FIG. 4 is a schematic view of the assembled structure of the workbench of the invention;

FIG. 5 is a schematic view of a placement assembly and clamping assembly according to the present invention;

FIG. 6 is a schematic cross-sectional view taken along the direction A-A in FIG. 1;

fig. 7 is a schematic cross-sectional view in the direction B-B of fig. 1.

In the figure: 1. a bottom plate; 2. a work table; 3. a coil main body; 4. a first shaping assembly; 5. a first corner cutting assembly; 6. a second shaping assembly; 7. a second corner cutting assembly; 8. placing the assembly; 9. a clamping assembly; 101. a cylinder mounting seat; 102. supporting feet; 201. a slide rail table; 202. a feed opening; 203. a surrounding baffle; 204. a spring; 401. a first shaping block; 402. a first shaping slide; 403. a first shaping cylinder; 501. a first cutter; 502. a first push block; 503. a first angular slide; 504. a first corner cutting cylinder; 601. a second shaping block; 602. a second shaping slide; 603. a second shaping cylinder; 701. a second cutter; 702. a second push block; 703. a second chamfer slide; 704. a second chamfer cylinder; 801. a first placement block; 802. a second placement block; 803. a discharge port; 804. a connecting plate; 901. triangular clamping blocks; 902. a push rod; 903. a screw; 904. a support plate; 905. and a limiting cylinder.

Detailed Description

The following description of the embodiments of the present invention 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 invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 and 4, the present invention is an inductance coil shaping and corner cutting pneumatic device, which includes a base plate 1, a coil body 3, and a workbench 2 mounted at the upper end of the base plate 1, wherein a first shaping component 4, a first corner cutting component 5, a second shaping component 6, and a second corner cutting component 7 are respectively mounted around the workbench 2, the first shaping component 4 and the second shaping component 6 are disposed opposite to each other and cooperate with each other for shaping a wire end, and the first corner cutting component 5 and the second corner cutting component 7 are disposed opposite to each other and cooperate with each other for cutting a wire end.

A connection plate 804 is installed at the upper end of the table 2, and a placement member 8 for placing the coil body 3 and a clamping member 9 for clamping the coil body 3 are installed at the upper end of the connection plate 804.

The working principle of the invention is as follows: the staff lays coil main part 3 in placing subassembly 8 to have clamping assembly 9 to carry out the centre gripping fixedly, coil main part 3 extra thread end or pin will stretch into in the workstation 2, and first plastic subassembly 4 matches second plastic subassembly 6 and carries out the correction with extra thread end or pin this moment, then cuts off processing to thread end or pin by first corner cut subassembly 5 cooperation second corner cut subassembly 7. The invention utilizes the mutual coordination of the pair of shaping components and the pair of corner cutting components to realize the automatic processing of coil shaping and corner cutting operation, and simultaneously greatly improves the efficiency and the accuracy in the shaping and cutting process.

As shown in fig. 2 and 7, the first shaping assembly 4 includes a first shaping block 401, a first shaping slide 402, and a first shaping cylinder 403, where the first shaping block 401 is fixedly connected to the first shaping slide 402, and an output end of the first shaping cylinder 403 is connected to the first shaping slide 402 and pushes the first shaping slide 402 to slide in the workbench 2.

Further, the second shaping assembly 6 includes a second shaping block 601, a second shaping slide 602, and a second shaping cylinder 603, where the second shaping block 601 is fixedly connected to the second shaping slide 602, and the second shaping block 601 is kept at the same height as the first shaping block 401, and an output end of the second shaping cylinder 603 is connected to the second shaping slide 602 and pushes the second shaping slide 602 to slide in the workbench 2.

In the specific application of this embodiment, the first shaping cylinder 403 and the second shaping cylinder 603 act synchronously, so as to drive the first shaping block 401 and the second shaping block 601 to move closer to or away from each other synchronously. When the shaping process is performed, the first shaping block 401 and the second shaping block 601 are close to each other, so that the wire ends or pins extending into the workbench 2 are pushed and pressed against the same plane, thereby ensuring the regularity of the wire ends or pins and facilitating the cutting process of the next step.

As shown in fig. 2 and 6, the first corner cutting assembly 5 includes a first cutter 501, a first push block 502, a first corner cutting slide 503, and a first corner cutting cylinder 504, wherein the first cutter 501 is connected to the first push block 502, the first push block 502 is fixedly connected to the first corner cutting slide 503, and an output end of the first corner cutting cylinder 504 is connected to the first corner cutting slide 503 and pushes the first corner cutting slide 503 to slide in the workbench 2.

Further, the second corner cutting assembly 7 includes a second cutter 701, a second push block 702, a second corner cutting slide 703 and a second corner cutting cylinder 704, the second cutter 701 is connected to the second push block 702, the second cutter 701 is kept at the same height as the first cutter 501, the second push block 702 is fixedly connected to the second corner cutting slide 703, and an output end of the second corner cutting cylinder 704 is connected to the second corner cutting slide 703 and pushes the second corner cutting slide 703 to slide in the workbench 2.

In the specific application of this embodiment, the first chamfer cylinder 504 and the second chamfer cylinder 704 act synchronously to drive the opposite first cutter 501 and second cutter 701 to move closer to or farther away from each other synchronously. After the shaping actions of the first shaping cylinder 403 and the second shaping cylinder 603 are finished, the first corner cutting cylinder 504 and the second corner cutting cylinder 704 can push the first cutter 501 and the second cutter 701 to be close to each other, so that the thread ends can be cut off, the thread ends or the pins after cutting off can be kept flush and regular, and the quality of coil shaping corner cutting can be improved.

As shown in fig. 2, 3 and 4, the periphery of the workbench 2 is provided with slide rail platforms 201, and each slide rail platform 201 is respectively in sliding fit with a corresponding first shaping slide 402, a second shaping slide 602, a first corner cutting slide 503 and a second corner cutting slide 703.

Further, a blanking opening 202 is provided at the central position of the workbench 2, a surrounding baffle 203 arranged in a hollow manner is integrally connected with the peripheral edge of the blanking opening 202, springs 204 are mounted on the periphery of the outer side of the surrounding baffle 203, and the springs 204 face the first shaping slide seat 402, the second shaping slide seat 602, the first corner cutting slide seat 503 and the second corner cutting slide seat 703 which are opposite.

In the specific application, the height of the enclosure board 203 is flush with the first shaping slide 402, the second shaping slide 602, the first corner cutting slide 503 and the second corner cutting slide 703, and is lower than the heights of the first shaping block 401, the second shaping block 601, the first cutter 501 and the second cutter 701, so that the corresponding slide can be blocked and buffered on the premise of not interfering with the shaping and cutting operation, thereby preventing the shaping block or the cutter from moving excessively or moving excessively fast, avoiding the loss of the shaping block or the cutter due to the excessively large impact, and prolonging the service life.

As shown in fig. 1 and 2, the cylinder mounting seats 101 are respectively arranged at the positions corresponding to the first shaping cylinder 403, the second shaping cylinder 603, the first corner cutting cylinder 504 and the second corner cutting cylinder 704 at the upper end of the base plate 1, and supporting feet 102 are uniformly distributed at four corners of the lower end of the base plate 1.

In the specific application of this embodiment, the height of the bottom plate 1 is increased by the supporting legs 102, so that a certain interval exists between the bottom plate 1 and the ground, and thus, the receiving devices such as the collecting box and the collecting box can be arranged at the position corresponding to the discharging opening 202 below the bottom plate 1, and the cut-off coil pins can automatically fall into the receiving devices, which is beneficial to centralized processing.

As shown in fig. 5, the placement module 8 includes a first placement block 801 and a second placement block 802, an arc-shaped groove for placing the coil body 3 is formed between the first placement block 801 and the second placement block 802, and a discharge opening 803 for passing through the wire end is provided in the arc-shaped groove.

Further, the clamping assembly 9 comprises two sets of triangular clamping blocks 901 which are oppositely arranged, the back side of each triangular clamping block 901 is connected with one end of a push rod 902, the other end of the push rod 902 is rotationally connected with a screw 903, support plates 904 are symmetrically fixed on the connecting plates 804, the screw 903 penetrates through the corresponding support plates 904 in a threaded manner, a limiting cylinder 905 is connected to the support plates 904, and the push rod 902 is in sliding fit with the limiting cylinder 905.

When the embodiment is specifically applied, the coil body 3 is arranged in the arc-shaped groove between the first placing block 801 and the second placing block 802, so that positioning is convenient, meanwhile, the thread end and the pin of the coil body 3 can enter the workbench 2 through the discharging hole 803 to be subjected to shaping and cutting processing, and before shaping and cutting, the coil body 3 is clamped and fixed by pushing the triangular clamping blocks 901 on two sides through the rotating screw 903, so that the coil body 3 is prevented from shaking to influence the shaping and cutting process.

When the shaping device is used, after the coil main body 3 is placed, the first shaping block 401 and the second shaping block 601 can be used for trimming and rectifying the coil head, and meanwhile, the first cutter 501 and the second cutter 701 are used for cutting off the coil head, so that the integrated automatic treatment of coil shaping and corner cutting operation is realized, and the efficiency and the accuracy in the shaping and cutting process are greatly improved;

By adopting the placement component 8 and the clamping component 9, the coil main body 3 can be conveniently and rapidly positioned, and simultaneously, the coil main body 3 is clamped and fixed by utilizing the triangular clamping jaws at two sides, so that the stability of the coil main body 3 in the shaping and cutting process is improved, and the influence of shaking of the coil main body on the shaping and cutting quality is avoided;

through setting up the surrounding baffle 203, can realize the buffering effect that blocks to corresponding slide under the prerequisite that does not hinder plastic cutting operation to can avoid the excessive or too fast removal of plastic piece or cutter, prevent to aggravate the loss of plastic piece or cutter because of the impact collision, thereby increase of service life.

The foregoing describes one embodiment of the present invention in detail, but the description is only a preferred embodiment of the present invention and should not be construed as limiting the scope of the invention. All equivalent changes and modifications within the scope of the present invention are intended to be covered by the present invention.

Claims (4)

1. The utility model provides an inductance coil plastic chamfer pneumatic means, includes bottom plate (1), coil main part (3) and installs workstation (2) in bottom plate (1) upper end, its characterized in that, first plastic subassembly (4), first corner cut subassembly (5), second plastic subassembly (6) and second corner cut subassembly (7) are installed respectively around workstation (2), first plastic subassembly (4) and second plastic subassembly (6) set up relatively and mutually support in order to be used for the end of a thread plastic, first corner cut subassembly (5) and second corner cut subassembly (7) set up relatively and mutually support in order to be used for the end of a thread cutting;

A connecting plate (804) is arranged at the upper end of the workbench (2), and a placing component (8) for placing the coil main body (3) and a clamping component (9) for clamping the coil main body (3) are arranged at the upper end of the connecting plate (804);

the placement assembly (8) comprises a first placement block (801) and a second placement block (802), an arc-shaped groove for placing the coil main body (3) is formed between the first placement block (801) and the second placement block (802), and a discharge hole (803) for passing through a wire head is formed in the arc-shaped groove in a penetrating mode;

The clamping assembly (9) comprises two groups of triangular clamping blocks (901) which are oppositely arranged, the back side of each triangular clamping block (901) is connected with one end of a push rod (902), the other end of each push rod (902) is rotationally connected with a screw rod (903), support plates (904) are symmetrically fixed on the connecting plates (804), the screw rods (903) penetrate through the corresponding support plates (904) in a threaded manner, a limiting cylinder (905) is connected to the support plates (904), and the push rods (902) are in sliding fit with the limiting cylinders (905);

The first shaping assembly (4) comprises a first shaping block (401), a first shaping sliding seat (402) and a first shaping air cylinder (403), wherein the first shaping block (401) is fixedly connected to the first shaping sliding seat (402), and the output end of the first shaping air cylinder (403) is connected with the first shaping sliding seat (402) and pushes the first shaping sliding seat (402) to slide in the workbench (2);

The second shaping assembly (6) comprises a second shaping block (601), a second shaping sliding seat (602) and a second shaping air cylinder (603), the second shaping block (601) is fixedly connected to the second shaping sliding seat (602), the second shaping block (601) and the first shaping block (401) keep the same height, and the output end of the second shaping air cylinder (603) is connected with the second shaping sliding seat (602) and pushes the second shaping sliding seat (602) to slide in the workbench (2);

The first corner cutting assembly (5) comprises a first cutter (501), a first pushing block (502), a first corner cutting sliding seat (503) and a first corner cutting air cylinder (504), wherein the first cutter (501) is connected with the first pushing block (502), the first pushing block (502) is fixedly connected to the first corner cutting sliding seat (503), and the output end of the first corner cutting air cylinder (504) is connected with the first corner cutting sliding seat (503) and pushes the first corner cutting sliding seat (503) to slide in the workbench (2);

The second corner cutting assembly (7) comprises a second cutter (701), a second push block (702), a second corner cutting sliding seat (703) and a second corner cutting air cylinder (704), wherein the second cutter (701) is connected with the second push block (702), the second cutter (701) and the first cutter (501) are kept at the same height, the second push block (702) is fixedly connected to the second corner cutting sliding seat (703), and the output end of the second corner cutting air cylinder (704) is connected with the second corner cutting sliding seat (703) and pushes the second corner cutting sliding seat (703) to slide in the workbench (2).

2. An inductor shaping chamfer pneumatic device according to claim 1, characterized in that the periphery of the table (2) is provided with slide rails (201), each slide rail (201) being in sliding fit with a corresponding first shaping slide (402), second shaping slide (602), first chamfer slide (503) and second chamfer slide (703) respectively.

3. The inductance coil shaping and corner cutting pneumatic device according to claim 1, wherein a blanking opening (202) is formed in the central position of the workbench (2), surrounding baffles (203) which are arranged in a hollow mode are integrally connected to the peripheral edges of the blanking opening (202), springs (204) are arranged on the periphery of the outer sides of the surrounding baffles (203), and the springs (204) face against the first shaping sliding seat (402), the second shaping sliding seat (602), the first corner cutting sliding seat (503) and the second corner cutting sliding seat (703) which are opposite to each other.

4. The inductance coil shaping and corner cutting pneumatic device according to claim 1, wherein cylinder mounting seats (101) are respectively arranged at positions corresponding to the first shaping cylinder (403), the second shaping cylinder (603), the first corner cutting cylinder (504) and the second corner cutting cylinder (704) at the upper end of the bottom plate (1), and supporting feet (102) are uniformly distributed at four corners of the lower end of the bottom plate (1).