CN113618284A

CN113618284A - Multi-shaft full-automatic capacitor production equipment

Info

Publication number: CN113618284A
Application number: CN202111180364.9A
Authority: CN
Inventors: 陈锋
Original assignee: Nantong Cheng Sheng Electronic Industries Co ltd
Current assignee: Nantong Cheng Sheng Electronic Industries Co ltd
Priority date: 2021-10-11
Filing date: 2021-10-11
Publication date: 2021-11-09
Anticipated expiration: 2041-10-11
Also published as: CN113618284B

Abstract

The invention discloses multi-shaft full-automatic capacitor production equipment, which relates to the technical field of capacitor processing equipment and comprises a conveying assembly, a capacitor body, a capacitor positioning assembly, a welding assembly and a wire feeding assembly, wherein the conveying assembly is arranged on the capacitor body; the capacitor assemblies are equidistantly arranged on the surface of the conveying assembly and are used for positioning and fixing the capacitor body; the capacitor lead welding equipment in the embodiment of the invention automatically positions and fixes the capacitor before welding, and the capacitor is automatically and intermittently conveyed by the conveying assembly, so that the production and processing efficiency of the capacitor is effectively improved.

Description

Multi-shaft full-automatic capacitor production equipment

Technical Field

The invention relates to the technical field of capacitor processing equipment, in particular to multi-shaft full-automatic capacitor production equipment.

Background

The capacitor is generally called capacitor for short, and the capacitor is 'charged capacitor' as the name implies, and is a device for holding electric charge. The capacitor is one of electronic elements widely used in electronic equipment, and is widely applied to aspects of blocking AC, coupling, bypassing, filtering, tuning loop, energy conversion, control and the like in a circuit. A capacitor is formed between two closely spaced insulated conductors (including conductive wires).

The electric capacity need weld the processing to the lead wire in production and processing process, and current electric capacity lead wire welding equipment simple structure is difficult to carry out the location to the electric capacity, and needs artifical manual line that send to the in-process temperature of welding is very high, is difficult to in time carry out cooling to the electric capacity and handles.

Disclosure of Invention

The invention aims to provide multi-shaft full-automatic capacitor production equipment to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

a multi-shaft full-automatic capacitor production device comprises a conveying assembly, a capacitor body, a capacitor positioning assembly, a welding assembly and a wire feeding assembly;

the capacitor assemblies are equidistantly arranged on the surface of the conveying assembly and are used for positioning and fixing the capacitor body;

the conveying assembly is used for intermittently conveying the positioned and fixed capacitor body;

the welding assembly comprises a welding head and a pushing component, and the pushing component is connected with the welding head and used for conducting lead welding on the capacitor body conveyed to the lower side of the welding head;

the wire feeding assembly is used for conveying a lead to the welding head so as to perform lead welding treatment on the capacitor body.

Conveying assembly includes conveyer belt and the support of relative arrangement in both sides, both sides relative arrangement carries the gear in the conveyer belt, both sides carry the gear to pass through belt drive and connect, conveyer belt inside wall surface sets up the rack, rack and gear engagement, support outside fixed mounting driving motor one, a driving motor output extends fixed connection pinion, pinion and master gear intermittent type nature meshing, master gear one end is connected with the leg joint, the other end and carry gear fixed connection.

The capacitor positioning assembly comprises a mounting plate fixedly connected with the conveying belt, the support is oppositely arranged on the surface of the mounting plate, the support is arranged on two sides of the mounting plate, an elastic clamping component is arranged between the support, and the elastic clamping component is used for clamping and fixing a capacitor body arranged between the support on two sides.

Elastic clamping part includes supporting rod and grip block, supporting rod and support sliding connection, both sides the one end and the handle fixed connection that the supporting rod was kept away from each other, the one end and the grip block fixed connection of handle are kept away from to the supporting rod, supporting rod and support sliding connection, the supporting rod outside sets up expanding spring, expanding spring one end and support fixed connection, the other end and handle fixed connection.

Preferably, the welding assembly further comprises a shell, the shell is fixedly connected with supports on two sides, the surface of the top wall of the shell is provided with a driving motor II, the output end of the driving motor II is fixedly connected with the rotary table, one side of the edge of the surface of the rotary table is provided with a clamping pin, the outer side of the clamping pin is provided with a push plate, a through groove which is movably connected with the clamping pin in a matched mode is formed between the push plates, the push plate faces one side of the shell and is fixedly connected with a push rod, one end, far away from the push plate, of the push rod penetrates through the shell and is fixedly connected with a welding head, and the push rod is connected with the top wall of the shell in a sliding mode.

Preferably, send line subassembly to include the reel, the reel rotates and installs on casing lateral wall surface, the lead wire is wound on the reel surface, reel and driving motor three output end fixed connection, driving motor three is used for driving the reel and rotates in order to carry the lead wire to the soldered connection.

Preferably, the wire feeding assembly further comprises a wire feeding sleeve, the wire feeding sleeve is mounted between side walls of the shell and used for guiding the lead wires on the surface of the wire winding wheel, and the wire feeding assembly further comprises a shearing component, and the shearing component is used for performing equidistant shearing treatment on the lead wires conveyed to the wire feeding sleeve.

Preferably, the shearing part still includes the worm, worm one end and reel fixed connection, worm and turbine meshing, the turbine casing rotates and is connected, turbine other end fixed connection cam, casing inside wall surface opposite arrangement cuts the support, one side it passes through connecting rod and shears sword fixed connection to cut the support, the opposite side set up the release link between the support to cut, release link and shearing support sliding connection, the release link outside sets up reset spring, reset spring one end and shearing support fixed connection, the other end and shearing sword fixed connection, the release link is kept away from one side end and the cam contact of shearing the sword.

Preferably, the casing lateral wall still is provided with the refrigeration box, refrigeration box and casing lateral wall fixed connection, refrigeration box surface mounting refrigerator, set up the air supply end in the refrigeration box, the air supply end is connected with the refrigerator for blow the low temperature air that the refrigerator produced to the capacitor body surface after the lead wire welding.

Preferably, the lower surfaces of the two sides of the support are relatively and fixedly provided with supporting legs, and the supporting legs are used for fixedly supporting the support.

Compared with the prior art, the invention has the beneficial effects that:

(1) the capacitor lead welding equipment in the embodiment of the invention automatically positions and fixes the capacitor before welding, and carries out automatic intermittent conveying on the capacitor through the conveying assembly, so that the processing stability is higher;

(2) the capacitor welded by the lead in the shell is conveyed into the refrigerating box body through the conveying belt, the refrigerating machine blows the refrigerated low-temperature air to the surface of the capacitor body, and then the capacitor body is cooled, cooling equipment does not need to be introduced to cool the capacitor body welded by the lead, in the prior art, a refrigerating procedure is usually required to cool the capacitor welded by the lead, and normal production and processing are seriously reduced;

(3) worm 19 drives cam 30 through meshing with turbine 18 and rotates, cam 30 promotes release link 31 at the pivoted in-process and removes, release link 31 promotes one side and shears sword 28 and remove towards the opposite side shearing sword 28, the tensile elasticity that produces of reset spring 29, through both sides it is inwards close to simultaneously to cut the lead wire to shear to cut sword 28, along with cam 30's rotation, reset spring 29 drives under the effect of elasticity and shears sword 28 and reset, and then accomplishes the shearing of lead wire, does not need the manual work to pre-shear the lead wire, and efficiency is higher, convenient to use.

Drawings

Fig. 1 is a schematic structural diagram of a multi-axis full-automatic capacitor production device.

Fig. 2 is a left-side view structural schematic diagram of a multi-axis full-automatic capacitor production device.

Fig. 3 is a structural schematic diagram of a multi-axis full-automatic capacitor production device viewed from the right.

Fig. 4 is a rear view schematic structural diagram of a multi-axis full-automatic capacitor production device.

Fig. 5 is a schematic structural diagram of a refrigeration box body in the multi-shaft full-automatic capacitor production equipment.

Fig. 6 is a schematic structural diagram of a capacitor positioning assembly in the multi-axis full-automatic capacitor production equipment.

Fig. 7 is a schematic structural view of a turntable in the multi-axis full-automatic capacitor production equipment.

Fig. 8 is a schematic structural view of a cam in the multi-axis full-automatic capacitor manufacturing apparatus.

In the figure: 1-a conveyor belt; 2-a conveying gear; 3-supporting legs; 4-a scaffold; 5-a telescopic spring; 6, mounting a plate; 7-a handle; 8-welding a head; 9-a housing; 10-driving a motor II; 11-a turntable; 12-a push plate; 13-a main gear; 14-driving a motor I; 15-half gear; 16-driving a motor III; 17-a reel; 18-a turbine; 19-a worm; 20-a rack plate; 21-a capacitor body; 22-a support; 23-a clamping plate; 24-a clamping bar; 25-a push rod; 26-a shearing support; 27-wire feeding sleeve; 28-a shearing knife; 29-a return spring; 30-a cam; 31-a reset lever; 32-a support; 33-bayonet lock; 34-a refrigerator; 35-refrigeration cabinet.

Detailed Description

The technical solution of the present invention will be described in further detail with reference to specific embodiments.

Referring to fig. 1-8, a multi-axis full-automatic capacitor production apparatus includes a conveying assembly, a capacitor body 21, a capacitor positioning assembly, a welding assembly and a wire feeding assembly, wherein the capacitor assemblies are equidistantly arranged on the surface of the conveying assembly for positioning and fixing the capacitor body 21, the conveying assembly is used for intermittently conveying the capacitor body 21 after being positioned and fixed, the welding assembly includes a welding head 8 and a pushing member, the pushing member is connected with the welding head 8 for performing wire welding on the capacitor body 21 conveyed below the welding head 8, and the wire feeding assembly is used for conveying a wire to the welding head 8 for performing wire welding on the capacitor body 21;

specifically, in this embodiment, the capacitor body 21 is placed on the surface of the capacitor positioning assembly, the capacitor body 21 is positioned, clamped and fixed by the capacitor positioning assembly, the capacitor body 21 positioned and fixed by the capacitor positioning assembly is conveyed towards the direction of the welding assembly by the conveying assembly, when the capacitor body is conveyed to the position right below the welding head 8, the lead to be welded is conveyed to the welding head 8 by the wire conveying assembly, the pushing member pushes the welding head 8 to move towards the direction of the capacitor body 21, and the lead and the capacitor body 21 are welded.

As a further scheme of the embodiment of the present invention, please refer to fig. 1-5, the conveying assembly includes a conveying belt 1 and supports 4 disposed at two sides of the conveying belt 1, conveying gears 2 are disposed at two sides of the conveying belt 1, the conveying gears 2 at two sides are connected by a belt, a rack 20 is disposed on the surface of the inner side wall of the conveying belt 1, the rack 20 is engaged with the gears 2, a first driving motor 14 is fixedly mounted at the outer side of the support 4, an output end of the first driving motor 14 extends to be fixedly connected with a half gear 15, the half gear 15 is intermittently engaged with a main gear 13, one end of the main gear 13 is rotatably connected with the support 4, and the other end of the main gear 13 is fixedly connected with the conveying gears 2;

specifically, in the present embodiment, a first driving motor 14 is started, the first driving motor 14 drives a half gear 15 to rotate, the half gear 15 drives the half gear to rotate by intermittently engaging with a main gear 13, the main gear 13 drives a conveying gear 2 to rotate, and the conveying gear 2 drives a conveying belt 1 to perform intermittent transmission by engaging with a rack 20;

the capacitor positioning assembly comprises a mounting plate 6 fixedly connected with the conveyor belt 1, supports 22 are oppositely arranged on the surface of the mounting plate 6, an elastic clamping component is arranged between the supports 22 on two sides, and the elastic clamping component is used for clamping and fixing the capacitor body 21 arranged between the supports 22 on two sides;

referring to fig. 1 to 8, the elastic clamping member includes a clamping rod 24 and a clamping plate 23, the clamping rod 24 is slidably connected to the support 22, ends of the clamping rods 24 away from each other on both sides are fixedly connected to the handle 7, an end of the clamping rod 24 away from the handle 7 is fixedly connected to the clamping plate 23, the clamping rod 24 is slidably connected to the support 22, an extension spring 5 is disposed on an outer side of the clamping rod 24, one end of the extension spring 5 is fixedly connected to the support 22, and the other end of the extension spring is fixedly connected to the handle 7;

specifically, in this embodiment, through to both sides simultaneous pulling handle 7, handle 7 drives both sides grip block 23 simultaneously and moves towards the outside through supporting rod 24, supporting rod 24 drives the tensile production elasticity of expanding spring 5, will wait to process electric capacity body 21 and arrange in between both sides grip block 23, unclamp handle 7, expanding spring 5 pushes both sides grip block 23 simultaneously and moves towards the inboard fixedly to electric capacity body 21 under the effect of elasticity, and clamping stability is higher, is convenient for carry out lead welding to electric capacity body 21.

As a further scheme of the embodiment of the invention, the welding assembly further comprises a shell 9, the shell 9 is fixedly connected with the brackets 4 at two sides, the surface of the top wall of the shell 9 is provided with a second driving motor 10, the output end of the second driving motor 10 is fixedly connected with a rotary table 11, one side of the surface edge of the rotary table 11 is provided with a bayonet 33, the outer side of the bayonet 33 is provided with a push plate 12, a through groove which is matched and movably connected with the bayonet 33 is arranged between the push plates 12, one side of the push plate 12 facing the shell 9 is fixedly connected with a push rod 25, one end of the push rod 25 far away from the push plate 12 penetrates through the shell 9 to be fixedly connected with a welding head 8, and the push rod 25 is slidably connected with the top wall of the shell 9;

specifically, in this embodiment, the second driving motor 10 is started, the second driving motor 10 drives the rotating disc 11 to rotate, and the rotating disc 11 pushes the soldering head 8 to move towards the capacitor body 21 through the clamping pin 33, the push plate 12 and the push rod 25 during the rotation process.

As a further solution of the embodiment of the present invention, the wire feeding assembly includes a reel 17, the reel 17 is rotatably mounted on the outer side wall surface of the housing 9, the surface of the reel 17 winds the lead wire, the reel 17 is fixedly connected with the output end of a driving motor three 16, the driving motor three 16 is used for driving the reel 17 to rotate so as to feed the lead wire to the welding head 8;

specifically, in the present embodiment, the lead wire to be welded is wound around the surface of the reel 17, the driving motor three 16 is started, the driving motor three 16 drives the reel 17 to rotate, and the reel 17 conveys the lead wire wound around the surface thereof to the welding head 8 during rotation.

As a further solution of the embodiment of the present invention, the wire feeding assembly further includes a wire feeding sleeve 27, the wire feeding sleeve 27 is installed between the side walls of the casing 9 and is used for guiding the lead wire on the surface of the wire winding wheel 17, and the wire feeding assembly further includes a shearing component which is used for performing equidistant shearing processing on the lead wire fed by the wire feeding sleeve 27;

specifically, in the present embodiment, the reel 17 feeds the welding wire on its surface to the wire feeding sleeve 27 during rotation, the wire feeding sleeve 27 guides and feeds the wire to the welding head 8, and the welding wire is subjected to equidistant cutting by the cutting member during feeding.

As a further scheme of the embodiment of the invention, the shearing component further includes a worm 19, one end of the worm 19 is fixedly connected with the reel 17, the worm 19 is meshed with the worm wheel 18, the shell 9 of the worm wheel 18 is rotatably connected, the other end of the worm wheel 18 is fixedly connected with a cam 30, the shearing supports 26 are oppositely arranged on the inner side wall surface of the shell 9, one side of each shearing support 26 is fixedly connected with a shearing knife 28 through a connecting rod, a reset rod 31 is arranged between the other side of the shearing supports 26, the reset rod 31 is slidably connected with the shearing supports 26, a reset spring 29 is arranged outside the reset rod 31, one end of the reset spring 29 is fixedly connected with the shearing supports 26, the other end of the reset rod 31 is fixedly connected with the shearing knife 28, and the tail end of one side, far away from the shearing knife 28, of the reset rod 31 is in contact with the cam 30;

specifically, in this embodiment, the third driving motor 16 drives the worm 19 to rotate in the process of driving the reel 17 to rotate, the worm 19 drives the cam 30 to rotate through meshing with the worm wheel 18, the cam 30 pushes the reset rod 31 to move in the rotating process, the reset rod 31 pushes the shearing knife 28 on one side to move towards the shearing knife 28 on the other side, the reset spring 29 stretches to generate elastic force, the shearing knives 28 are simultaneously and inwards close to the lead to be sheared through two sides, and along with the rotation of the cam 30, the reset spring 29 drives the shearing knife 28 to reset under the action of the elastic force, so that the shearing of the lead is completed.

As a further scheme of the embodiment of the present invention, a refrigeration box 35 is further disposed on a side wall of the housing 9, the refrigeration box 35 is fixedly connected to the side wall of the housing 9, a refrigerator 34 is mounted on a surface of the refrigeration box 35, and an air supply end is disposed in the refrigeration box 35 and connected to the refrigerator 34, and is configured to blow low-temperature air generated by the refrigerator 34 to a surface of the capacitor body 21 after the lead is welded;

specifically, in this embodiment, the capacitor welded to the lead in the housing 9 is conveyed to the refrigeration box 35 through the conveyor belt 1, the refrigerator 34 blows the refrigerated low-temperature air to the surface of the capacitor body 21, and then cools the capacitor body 21.

As a further scheme of the embodiment of the invention, the lower surfaces of the brackets 4 at two sides are relatively and fixedly provided with the supporting legs 3, and the supporting legs 3 are used for fixedly supporting the brackets 4.

The working principle of the invention is as follows: the capacitor body 21 is arranged on the surface of the capacitor positioning component, the handle 7 is pulled towards two sides simultaneously, the handle 7 drives the clamping plates 23 on two sides to move towards the outer side simultaneously through the clamping rod 24, the clamping rod 24 drives the telescopic spring 5 to stretch to generate elastic force, the capacitor body 21 to be processed is arranged between the clamping plates 23 on two sides, the handle 7 is loosened, the telescopic spring 5 pushes the clamping plates 23 on two sides to move towards the inner side simultaneously under the action of the elastic force so as to clamp and fix the capacitor body 21, the driving motor I14 is started, the driving motor I14 drives the half gear 15 to rotate, the half gear 15 drives the half gear to rotate through intermittent meshing with the main gear 13, the main gear 13 drives the conveying gear 2 to rotate, the conveying gear 2 drives the conveying belt 1 to perform intermittent transmission through meshing with the rack 20, when the conveying belt is conveyed to be under the welding head 8, the lead wire to be welded is wound on the surface of the winding wheel 17, the driving motor III 16 is started, the driving motor III 16 drives the reel 17 to rotate, the reel 17 conveys the lead wound on the surface of the reel to the welding head 8 in the rotating process, the pushing component pushes the welding head 8 to move towards the direction of the capacitor body 21 so as to weld the lead and the capacitor body 21, the driving motor III 16 drives the worm 19 to rotate in the rotating process of the reel 17, the worm 19 drives the cam 30 to rotate by meshing with the turbine 18, the cam 30 pushes the reset rod 31 to move in the rotating process, the reset rod 31 pushes the shearing knife 28 on one side to move towards the shearing knife 28 on the other side, the reset spring 29 stretches to generate elastic force, the shearing knives 28 on the two sides simultaneously approach inwards to shear the lead, and the reset spring 29 drives the shearing knives 28 to reset under the action of the elastic force along with the rotation of the cam 30, thereby completing the cutting of the lead.

While the preferred embodiments of the present invention have been described in detail, the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art.

Claims

1. The multi-shaft full-automatic capacitor production equipment comprises a conveying assembly and a capacitor body (21), and is characterized by further comprising a capacitor positioning assembly, a welding assembly and a wire feeding assembly;

the capacitor assemblies are arranged on the surface of the conveying assembly at equal intervals and used for positioning and fixing the capacitor body (21);

the conveying assembly is used for intermittently conveying the positioned and fixed capacitor body (21);

the welding assembly comprises a welding head (8) and a pushing component, and the pushing component is connected with the welding head (8) and is used for conducting lead welding on the capacitor body (21) conveyed to the position below the welding head (8);

the wire feeding assembly is used for conveying a lead wire to a welding head (8) so as to perform lead wire welding treatment on the capacitor body (21);

the conveying assembly comprises a conveying belt (1) and supports (4) which are oppositely arranged on two sides, conveying gears (2) are oppositely arranged on two sides in the conveying belt (1), the conveying gears (2) on two sides are connected through belt transmission, a rack (20) is arranged on the surface of the inner side wall of the conveying belt (1), the rack (20) is meshed with the gears (2), a first driving motor (14) is fixedly installed on the outer side of each support (4), the output end of the first driving motor (14) extends to be fixedly connected with a half gear (15), the half gear (15) is intermittently meshed with a main gear (13), one end of the main gear (13) is rotatably connected with the supports (4), and the other end of the main gear (13) is fixedly connected with the conveying gears (2);

the capacitor positioning assembly comprises a mounting plate (6) fixedly connected with the conveying belt (1), supports (22) are oppositely arranged on the surface of the mounting plate (6), an elastic clamping component is arranged between the supports (22) on two sides, and the elastic clamping component is used for clamping and fixing a capacitor body (21) arranged between the supports (22) on two sides;

elasticity clamping part includes supporting rod (24) and grip block (23), supporting rod (24) and support (22) sliding connection, both sides one end and handle (7) fixed connection that keep away from each other supporting rod (24), the one end and grip block (23) fixed connection of handle (7) are kept away from supporting rod (24), supporting rod (24) and support (22) sliding connection, the supporting rod (24) outside sets up expanding spring (5), expanding spring (5) one end and support (22) fixed connection, the other end and handle (7) fixed connection.

2. Multi-axis full automatic capacitor production equipment according to claim 1, the welding assembly further comprises a shell (9), the shell (9) is fixedly connected with the brackets (4) at the two sides, a second driving motor (10) is arranged on the surface of the top wall of the shell (9), the output end of the second driving motor (10) is fixedly connected with a rotary disc (11), a bayonet lock (33) is arranged on one side of the surface edge of the rotary disc (11), a push plate (12) is arranged on the outer side of the bayonet lock (33), a through groove which is matched and movably connected with the clamping pin (33) is arranged between the push plates (12), one side of the push plate (12) facing the shell (9) is fixedly connected with a push rod (25), one end of the push rod (25), which is far away from the push plate (12), penetrates through the shell (9) and is fixedly connected with the welding head (8), and the push rod (25) is connected with the top wall of the shell (9) in a sliding mode.

3. The full-automatic multi-shaft capacitor production equipment according to claim 2, wherein the wire feeding assembly comprises a winding wheel (17), the winding wheel (17) is rotatably mounted on the outer side wall surface of the shell (9), the surface of the winding wheel (17) winds the lead, the winding wheel (17) is fixedly connected with the output end of a driving motor III (16), and the driving motor III (16) is used for driving the winding wheel (17) to rotate so as to feed the lead to the welding head (8).

4. The multi-axis full-automatic capacitor production equipment according to claim 3, wherein the wire feeding assembly further comprises a wire feeding sleeve (27), the wire feeding sleeve (27) is installed between the side walls of the shell (9) and used for guiding the lead on the surface of the wire winding wheel (17), and the wire feeding assembly further comprises a shearing component which is used for performing equidistant shearing treatment on the lead conveyed by the wire feeding sleeve (27).

5. The multi-shaft full-automatic capacitor production equipment according to claim 4, wherein the cutting component further comprises a worm (19), one end of the worm (19) is fixedly connected with the reel (17), the worm (19) is meshed with the worm gear (18), the housing (9) of the worm gear (18) is rotatably connected, the other end of the worm gear (18) is fixedly connected with a cam (30), the inner side wall surface of the housing (9) is oppositely provided with a cutting support (26), one side of the cutting support (26) is fixedly connected with the cutting knife (28) through a connecting rod, the other side of the cutting support (26) is provided with a reset rod (31), the reset rod (31) is slidably connected with the cutting support (26), the outside of the reset rod (31) is provided with a reset spring (29), and one end of the reset spring (29) is fixedly connected with the cutting support (26), the other end of the reset rod is fixedly connected with the shearing knife (28), and the tail end of one side, far away from the shearing knife (28), of the reset rod (31) is in contact with the cam (30).

6. The multi-shaft full-automatic capacitor production equipment according to claim 5, wherein a refrigeration box body (35) is further arranged on the side wall of the housing (9), the refrigeration box body (35) is fixedly connected with the side wall of the housing (9), a refrigerator (34) is installed on the surface of the refrigeration box body (35), and an air supply end is arranged in the refrigeration box body (35), is connected with the refrigerator (34), and is used for blowing low-temperature air generated by the refrigerator (34) to the surface of the capacitor body (21) after lead welding.

7. The multi-shaft full-automatic capacitor production equipment according to claim 6, wherein the lower surfaces of the brackets (4) on two sides are fixedly provided with supporting legs (3), and the supporting legs (3) are used for fixedly supporting the brackets (4).