CN220658937U - Fuse film-making device - Google Patents

Abstract

The utility model discloses a fuse sheet-making device, which is characterized in that a thickness detector is used for detecting the thickness of a material belt, and the material belt meeting the thickness requirement of a fuse sheet is conveyed to a punching station; the punching station carries out equidistant punching on the material belt, and the punched material belt is conveyed to the narrow diameter detection station so as to detect whether the size of the aperture meets the fuse requirement or not on line; the cutting station cuts the material belt into molten pieces with equal width; the bending station is used for stamping the fuse piece to be formed through a die, and the fuse piece is fed into the stamping mechanism by rotating by 90 degrees after clamping the central position through clamping jaws of the air cylinder. The error control of thickness, aperture and bending position is carried out on the fuse through the plurality of stations, so that the accumulated error in the fuse manufacturing process is reduced, and the yield of the fuse is improved.

Description

Fuse film-making device

Technical Field

The utility model belongs to the technical field of fuse piece manufacturing, and particularly relates to a fuse piece manufacturing device.

Background

The fuse is a simple and effective protective electric appliance, is mainly used for overload protection and short-circuit protection, and mainly comprises a melt and an insulating tube for installing the melt, when the fuse is used, the melt is connected in a protected circuit in series, when the circuit has a short-circuit fault, the melt is instantaneously fused to break the circuit, so that the protective effect is achieved, for the fuse body, after punching processing is finished, the fuse body is cut according to the model of the fuse body which is actually processed, and the two working procedures are independently processed.

The utility model provides a compound fuse-element cutting equipment that punches a hole (publication No. CN 209829998U), including base, blowing device, material area guide way, guide way horizontal migration mechanism and compound device that cuts that punches a hole, the blowing device includes support frame, servo motor one and material band pulley dish, the support frame sets up perpendicularly on the base, servo motor one is fixed on the support frame, material band pulley dish cover is established on servo motor one's output shaft, the material area guide way sets up on guide way horizontal migration mechanism, and be located the below of material band pulley dish, the discharge end of material area guide way sets up the compound device that cuts that punches a hole, put into blowing mechanism with the fuse-element material area that will process into the material band guide way, cut a hole compound device and carry out the processing of punching a hole to the material band through the material band guide way, the material band that punches a hole is carried into the cutter below the guide way horizontal migration mechanism that cuts a hole after the processing, this patent technology is nevertheless realized punching a hole, cut integrated processing, machining efficiency is high, but when shearing, do not carry out error control to fuse-element position and size, result in appearing in a lot of defective products in the production process.

Disclosure of Invention

The utility model aims to provide a fuse sheet making device which reduces errors in fuse sheet making and improves yield.

In order to solve the problems, the technical scheme of the utility model is as follows:

a fuse slide apparatus comprising: the device comprises a material tape disc, a punching station, a narrow diameter detection station, a cutting station and a bending station;

the material belt disc is used for loading the material belt and conveying the material belt to the punching station;

a thickness detector is arranged in front of the punching station and used for detecting whether the thickness of the material belt meets the fuse piece manufacturing requirement or not, and the material belt meeting the fuse piece thickness requirement is conveyed to the punching station;

the punching station is used for carrying out equidistant punching on the material belt, and the punched material belt is conveyed to the narrow diameter detection station so as to detect whether the size of the aperture meets the fuse requirement or not on line;

the cutting station is used for cutting the material belt into molten pieces with equal width;

the bending station is used for stamping the fuse piece to be formed through a die, the fuse piece is clamped at the central position through clamping jaws of the air cylinder and then is rotated by 90 degrees to be sent into the stamping mechanism, and the central position of the fuse piece is located below the die; after stamping is completed, the clamping jaw of the cylinder clamps the fuse piece to be sent to a finished product stacking position.

According to an embodiment of the utility model, the bending station comprises a clamping mechanism and a stamping mechanism;

the clamping mechanism comprises clamping jaws, an air cylinder jaw, a clamping air cylinder and a rotating mechanism, wherein the clamping jaws are arranged on the air cylinder jaw, and the clamping air cylinder drives the air cylinder jaw to drive the clamping jaws to retract and expand; the clamping cylinder is arranged on the rotating mechanism, and the rotating mechanism drives the cylinder claw head to rotate for 90 degrees once;

the stamping mechanism comprises an air cylinder and a die, and the air cylinder drives the die to press down and reset.

According to one embodiment of the utility model, the rotating mechanism is provided with a plurality of clamping cylinders which are distributed circularly.

According to an embodiment of the utility model, the punching station comprises a first clamping mechanism, a first feeding mechanism and a punching mechanism;

the first feeding mechanism comprises a first servo motor, a first screw rod, a first synchronous belt and a first bracket, wherein the first synchronous belt and the first screw rod are arranged on the upper part of the first bracket, and the first servo motor drives the first screw rod to move through the first synchronous belt;

the first clamping mechanism comprises a first clamping cylinder, and the first clamping cylinder is arranged on the first screw rod;

the punching mechanism is arranged in front of the first clamping cylinder.

According to an embodiment of the present utility model, the first servo motor quantitatively controls the length of the first clamping cylinder for contracting the feeding belt each time.

According to an embodiment of the utility model, the cutting station comprises a second clamping mechanism, a second feeding mechanism and a cutting mechanism;

the second feeding mechanism comprises a second servo motor, a second screw rod, a second synchronous belt and a second bracket, wherein the second synchronous belt and the second screw rod are arranged on the upper part of the second bracket, and the second servo motor drives the second screw rod to move through the second synchronous belt;

the second clamping mechanism comprises a second clamping cylinder, and the second clamping cylinder is arranged on the second screw rod;

the cutting mechanism is arranged in front of the second clamping cylinder.

According to an embodiment of the present utility model, the second servo motor quantitatively controls the width of the second clamping cylinder for contracting the feeding belt each time.

By adopting the technical scheme, the utility model has the following advantages and positive effects compared with the prior art:

according to the fuse sheet-making device in the embodiment of the utility model, the thickness of the material belt is detected by the thickness detector, and the material belt meeting the thickness requirement of the fuse sheet is conveyed to the punching station; the punching station carries out equidistant punching on the material belt, and the punched material belt is conveyed to the narrow diameter detection station so as to detect whether the size of the aperture meets the fuse requirement or not on line; the cutting station cuts the material belt into molten pieces with equal width; the bending station is used for stamping the fuse piece to be formed through a die, and the fuse piece is fed into the stamping mechanism by rotating by 90 degrees after clamping the central position through clamping jaws of the air cylinder. The error control of thickness, aperture and bending position is carried out on the fuse through the plurality of stations, so that the accumulated error in the fuse manufacturing process is reduced, and the yield of the fuse is improved.

Drawings

FIG. 1 is a schematic view of a fuse clip assembly according to one embodiment of the present utility model;

fig. 2 is a schematic diagram of a bending station in an embodiment of the utility model.

Reference numerals illustrate:

1: a material tape reel; 2: a thickness detector; 3: a punching station; 4: a narrow diameter detection station; 5: a cutting station; 6: a bending station; 7: a clamping jaw; 8: a cylinder claw head; 9: clamping cylinder: 10: a rotation mechanism; 11: a fuse piece; 12: a cylinder; 13: a mold; 14: and a finished product stacking station.

Detailed Description

The utility model provides a fuse sheet making device which is further described in detail below with reference to the accompanying drawings and specific embodiments. Advantages and features of the utility model will become more apparent from the following description and from the claims.

This embodiment provides a fuse film-making device, please refer to fig. 1, and the device includes: the device comprises a material tape disc 1, a thickness detector 2, a punching station 3, a narrow diameter detection station 4, a cutting station 5 and a bending station 6. Wherein the material reel 1 is used for loading the material belt and conveying the material belt to the thickness detector 2. The thickness detector 2 is used for detecting the thickness of the material belt and conveying the material belt meeting the thickness requirement of the fuse piece to the punching station 3. The punching station 3 is used for carrying out equidistant punching on the material belt, and the material belt after punching is conveyed to the narrow diameter detection station 4 so as to detect whether the size of the aperture meets the fuse requirement or not on line. The cutting station 5 is used for cutting the material strip into equal-width fusion pieces. The bending station 6 is used for stamping the fuse piece to be formed through a die, the fuse piece is clamped at the central position through clamping jaws of an air cylinder and then is rotated by 90 degrees to be sent into the stamping mechanism, and the central position of the fuse piece is located below the die. The folded fuse piece is sent to a finished product stacking station 14 after rotating by 90 degrees from the center position of the cylinder clamping jaw.

Specifically, referring to fig. 2, the bending station 6 includes a clamping mechanism and a punching mechanism. The clamping mechanism comprises a clamping jaw 7, an air cylinder jaw 8, a clamping air cylinder 9 and a rotating mechanism 10, wherein the clamping jaw 7 is arranged on the air cylinder jaw 8, and the clamping air cylinder 9 drives the air cylinder jaw 8 to drive the clamping jaw 7 to retract and expand. The clamping cylinder 9 is arranged on the rotating mechanism 10, and the rotating mechanism 10 drives the cylinder claw head 8 to rotate for 90 degrees once.

The clamping jaw 7 is connected to the cylinder jaw 8 through threads, and the cylinder jaw 8 is driven by the clamping cylinder 9 to drive the clamping jaw 7 to retract, clamp or release the fuse piece 11.

The rotation mechanism 10 may be a rotary cylinder, a rotary mechanical arm, or a turntable.

Further, a plurality of clamping cylinders 9 are arranged on the rotating mechanism 10, and the plurality of clamping cylinders 9 are distributed in a circular shape. Thus, the efficiency of fuse clip can be improved.

The stamping mechanism comprises an air cylinder 12 and a die 13, and the air cylinder 12 drives the die 13 to press down and reset.

The cut fuse piece 11 is sent into a stamping mechanism after being clamped by a clamping jaw 7 at the center, the die 13 is driven by an air cylinder 12 to contact the fuse piece 11 downwards until the stamping is completed, and the fuse piece is returned. By clamping the transferring mode of the center position of the fuse piece, the positioning error can be well dispersed, and the accumulated error of fuse piece manufacture is reduced to the minimum.

The die can also take the center position of the fuse piece as a positioning reference in a mode of clamping the center position. Therefore, the die is universal, and the cost is saved.

In one implementation, the thickness detector 2 may detect on-line whether the thickness of the strip meets fuse making requirements.

The punching station 3 comprises a first clamping mechanism, a first feeding mechanism and a punching mechanism. The first feeding mechanism comprises a first servo motor, a first screw rod, a first synchronous belt and a first support, wherein the first synchronous belt and the first screw rod are arranged on the upper portion of the first support, and the first servo motor drives the first screw rod to move through the first synchronous belt. The first clamping mechanism comprises a first clamping cylinder, and the first clamping cylinder is arranged on the first screw rod. The punching mechanism is arranged in front of the first clamping cylinder.

Further, the first servo motor quantitatively controls the length of the first clamping cylinder for contracting the conveying belt each time. Thus, the error of fuse piece manufacture can be reduced.

The narrow diameter detection station 4 is used for detecting the aperture size of the punched material belt, and is provided with an aperture detector which can detect whether the aperture size of the material belt meets the fuse piece manufacturing requirement or not on line. Thus, the error of fuse piece manufacture is further reduced.

The cutting station 5 comprises a second clamping mechanism, a second feeding mechanism and a cutting mechanism. The second feeding mechanism comprises a second servo motor, a second screw rod, a second synchronous belt and a second support, wherein the second synchronous belt and the second screw rod are arranged on the upper portion of the second support, and the second servo motor drives the second screw rod to move through the second synchronous belt. The second clamping mechanism comprises a second clamping cylinder, and the second clamping cylinder is arranged on the second screw rod. The cutting mechanism is arranged in front of the second clamping cylinder.

Further, the second servo motor quantitatively controls the width of the second clamping cylinder for contracting the conveying belt each time. Therefore, each time of feeding is accurately controlled, and the width of the cut fuse piece is ensured to be within the range of a required tolerance.

The embodiments of the present utility model have been described in detail with reference to the drawings, but the present utility model is not limited to the above embodiments. Even if various changes are made to the present utility model, it is within the scope of the appended claims and their equivalents to fall within the scope of the utility model.

Claims (7)

1. A fuse slide apparatus, comprising: the device comprises a material tape disc, a punching station, a narrow diameter detection station, a cutting station and a bending station;

the material belt disc is used for loading the material belt and conveying the material belt to the punching station;

a thickness detector is arranged in front of the punching station and used for detecting whether the thickness of the material belt meets the fuse piece manufacturing requirement or not, and the material belt meeting the fuse piece thickness requirement is conveyed to the punching station;

the punching station is used for carrying out equidistant punching on the material belt, and the punched material belt is conveyed to the narrow diameter detection station so as to detect whether the size of the aperture meets the fuse requirement or not on line;

the cutting station is used for cutting the material belt into molten pieces with equal width;

the bending station is used for stamping the fuse piece to be formed through a die, the fuse piece is clamped at the central position through clamping jaws of the air cylinder and then is rotated by 90 degrees to be sent into the stamping mechanism, and the central position of the fuse piece is located below the die; after stamping is completed, the clamping jaw of the cylinder clamps the fuse piece to be sent to a finished product stacking position.

2. The fuse slide assembly of claim 1, wherein the bending station comprises a clamping mechanism and a stamping mechanism;

the clamping mechanism comprises clamping jaws, an air cylinder jaw, a clamping air cylinder and a rotating mechanism, wherein the clamping jaws are arranged on the air cylinder jaw, and the clamping air cylinder drives the air cylinder jaw to drive the clamping jaws to retract and expand; the clamping cylinder is arranged on the rotating mechanism, and the rotating mechanism drives the cylinder claw head to rotate for 90 degrees once;

the stamping mechanism comprises an air cylinder and a die, and the air cylinder drives the die to press down and reset.

3. A fuse slide assembly as recited in claim 2 wherein the rotary mechanism is provided with a plurality of clamping cylinders, the plurality of clamping cylinders being circularly disposed.

4. The fuse slide assembly of claim 1, wherein the punching station comprises a first clamping mechanism, a first feeding mechanism, and a punching mechanism;

the first feeding mechanism comprises a first servo motor, a first screw rod, a first synchronous belt and a first bracket, wherein the first synchronous belt and the first screw rod are arranged on the upper part of the first bracket, and the first servo motor drives the first screw rod to move through the first synchronous belt;

the first clamping mechanism comprises a first clamping cylinder, and the first clamping cylinder is arranged on the first screw rod;

the punching mechanism is arranged in front of the first clamping cylinder.

5. The fuse slide assembly of claim 4 wherein the first servo motor quantitatively controls the length of the first clamping cylinder to retract the feed belt each time.

6. The fuse slide assembly of claim 1, wherein the cutting station comprises a second clamping mechanism, a second feeding mechanism, and a cutting mechanism;

the second feeding mechanism comprises a second servo motor, a second screw rod, a second synchronous belt and a second bracket, wherein the second synchronous belt and the second screw rod are arranged on the upper part of the second bracket, and the second servo motor drives the second screw rod to move through the second synchronous belt;

the second clamping mechanism comprises a second clamping cylinder, and the second clamping cylinder is arranged on the second screw rod;

the cutting mechanism is arranged in front of the second clamping cylinder.

7. The fuse slide assembly of claim 6 wherein the second servo motor quantitatively controls the width of the second clamping cylinder to retract the feed belt each time.