JP6802431B1 - Automatic manufacturing equipment for electronic stamping parts - Google Patents

Abstract

PROBLEM TO BE SOLVED: To disclose an automatic manufacturing apparatus for electronic stamping parts. SOLUTION: The stamping box is included, a stamping operating space is installed in the stamping box, a rotatable pulley shaft is installed in the left and right side walls of the stamping operating space, and a belt is installed in the pulley shaft. The pulleys are installed symmetrically in the front-rear and left-right directions, a belt is connected to the belt pulley, and a chip substrate can be placed on the belt. The stamping mechanism installed inside the invention can automatically press electronic components onto the substrate at high speed, simplifying the machining process and operating procedure, greatly improving the production efficiency of electronic stamping, and making the entire machining work easy. It is easy to operate and does not hurt the worker's body. [Selection diagram] Fig. 1

Description

The present invention relates to the field of manufacturing electronic components, and specifically is an automatic manufacturing device for electronic stamping parts.

Electronic stamping is one of the components in the manufacture of electronic components. It is classified according to the processing technology and can be classified into two main categories, separation process and molding process. The separation process, also called blanking, aims to separate stamped parts from the sheet along a particular contour while ensuring the quality requirements of the separated sections. The purpose of the forming process is to plastically deform the sheet without breaking the blank to produce workpieces of the desired shape and size. Current electronic stamping parts processing equipment has problems such as low processing efficiency and complicated operation. Therefore, we will develop a device that can simplify the stamping process, improve the production efficiency of electronic stamping, and efficiently stamp. There is a need.

Publication No. 108790236 of Chinese Patent Application

Technical problem: Current electronic stamping parts processing equipment has problems such as low processing efficiency and complicated operation.

In order to solve the above problems, the present invention designs an automatic manufacturing apparatus for electronic stamping parts. The automatic manufacturing apparatus for electronic stamping parts of the present invention includes a stamping box, a stamping operating space is installed in the stamping box, and rotatable pulley shafts are installed in the left and right side walls of the stamping operating space. A belt pulley is installed symmetrically in the front-rear and left-right directions on the pulley shaft, a belt is connected to the belt pulley, a chip substrate can be placed on the belt, and the chip substrate can be placed in the left wall of the stamping box. Is equipped with a rotatable rotary disk shaft, a rotary disk is fixedly installed on the rotary disk shaft, and six friction blocks arranged at symmetrical positions are installed in the rotary disk, and the friction A stamping component can be sandwiched between the blocks, a damping spring is elastically connected to one end of the friction block away from the stamping component, and one end of the damping spring away from the stamping component. It is fixedly connected to the turntable, a cam space is installed in the upper wall of the stamping box, a stamping mechanism is installed in the cam space, and a stamping rod is installed in the stamping mechanism. A stamping block is installed at the lower end of the stamping rod, and the stamping mechanism drives the stamping rod and slides it in the vertical direction so that the stamping block presses the stamping component onto the chip substrate. A stamping power space is installed in the right wall of the stamping box, a stamping power mechanism is installed in the stamping power space, and the stamping power mechanism is the belt, the turntable, and the stamping mechanism. A gear space is installed in the lower wall of the stamping power space, a gear setting mechanism is installed in the gear space, and a rotatable power shaft is installed in the stamping power mechanism. Is installed, the lower end of the power shaft extends into the gear space, a rotatable first bevel gear is installed in the gear setting mechanism, and the upper end of the first bevel gear is the power shaft. The stamping power mechanism transmits power to the gear setting mechanism via the power shaft and the first bevel gear, and a rotatable vertical transmission shaft is contained in the stamping power mechanism. The first transmission gear is fixedly installed at the upper end of the vertical transmission shaft, and the second transmission gear is connected to the left end of the first transmission gear so as to mesh with the second transmission gear. A lateral transmission shaft is fixedly installed at the left end of the shaft, a rotatable first connecting gear is installed in the stamping mechanism, and the left end of the lateral transmission shaft is fixedly connected to the first connecting gear. , Power can be transmitted to the stamping mechanism.

To be beneficial, a first spur gear is fixedly installed at the right end of the pulley shaft, and a second spur gear is connected to the lower end of the first spur gear so as to mesh with the shaft of the second spur gear. A connecting shaft is fixedly installed in the core, a first timing gear is fixedly installed at the left end of the connecting shaft, and a second timing gear is connected to the upper end of the first timing gear so as to mesh with each other. The upper end of the second timing gear is fixedly connected to the turntable shaft.

The stamping power mechanism includes a main motor fixedly installed in the lower wall of the stamping power space, the power shaft is movably connected to the main motor, and a spline shaft is connected to the upper end of the power shaft. Is installed so as to cover, the spline shaft is connected to the power shaft by a spline, and the upper end of the spline shaft can be connected so as to mesh with the vertical transmission shaft, at both left and right ends of the spline shaft. A magnetic slider is symmetrically installed, a spring is connected to the lower end of the magnetic slider so as to have elasticity, and an electromagnet is fixedly installed at the lower end of the spring.

The stamping mechanism includes a camshaft rotatably installed in the cam space, a second connecting gear is fixedly installed on the camshaft, and the right end of the second connecting gear is the first connecting gear. A stamping cam is fixedly installed on the cam shaft, and the stamping cam is located at the rear end of the second connecting gear.

To be beneficial, two shock absorbers are fixedly installed in symmetrical positions on the top wall of the stamping working space, an oil storage space is installed in the shock absorber, and the oil storage space is contained. A piston rod that can slide in the vertical direction is installed, a branch oil pipe is installed at the left end of the oil storage space so as to communicate with the branch oil pipe, and a buffer spring is elastically connected to the lower end of the buffer cylinder. The lower end of the piston rod is fixedly connected to the connecting rod, the lower end of the cushioning spring is elastically connected to the connecting rod, and one end of the connecting rod close to the stamping block is fixed to the stamping rod. Is connected to.

The gear setting mechanism includes a rotatably installed first constant axis in the gear space, a second bevel gear is fixedly installed on the first constant axis, and the upper end of the second bevel gear is fixed. It is connected so as to mesh with the first bevel gear, a fan-shaped gear is fixedly installed on the first constant axis, the fan-shaped gear is located at the rear end of the second bead gear, and is located at the lower end of the fan-shaped gear. The intermittent gears are connected so as to mesh with each other, the second localization shaft is fixedly installed on the axis of the intermittent gear, and the third bevel gear is fixedly installed on the second localization shaft. The bevel gear is located at the rear end of the intermittent gear, the fourth bevel gear is connected to the left end of the third bead gear so as to mesh with the fourth bead gear, and the left end of the fourth bead gear is fixedly connected to the pulley shaft. ing.

The beneficial effects of the present invention are: The present invention is simple to configure, convenient to maintain and use, and the stamping mechanism installed inside the present invention can automatically and quickly press electronic components onto the substrate, processing process. It simplifies the operation procedure, greatly improves the production efficiency of electronic stamping, and the whole processing work is simple and easy to operate, and does not hurt the worker's body.

In order to explain the invention of the present application in detail with reference to FIGS. 1 to 5 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 are the same.

FIG. 1 is a schematic diagram of the overall configuration of the automatic manufacturing apparatus for electronic stamping parts of the present invention. FIG. 2 is an enlarged schematic diagram of A in FIG. FIG. 3 is an enlarged schematic diagram of B in FIG. FIG. 4 is an enlarged schematic diagram of C in FIG. FIG. 5 is an enlarged schematic diagram of D in FIG.

The present invention relates to an automatic manufacturing apparatus for electronic stamping parts, and is mainly used in the field of manufacturing electronic parts. Hereinafter, the present invention will be further described with reference to the drawings of the present invention.

The automatic manufacturing apparatus for electronic stamping parts of the present invention includes a stamping box 11, a stamping operating space 100 is installed in the stamping box 11, and the stamping operating space 100 is rotatable in the left and right side walls of the stamping operating space 100. The pulley shaft 31 is installed, the belt pulley 32 is installed symmetrically in the front-rear and left-right directions on the pulley shaft 31, the belt 33 is connected to the belt pulley 32, and the chip substrate 34 is placed on the belt 33. A rotatable rotary disk shaft 26 is installed in the left wall of the stamping box 11, a rotary disk 25 is fixedly installed in the rotary disk shaft 26, and left and right are installed in the rotary disk 25. Six friction blocks 44 arranged at symmetrical positions are installed, a stamping component 47 can be sandwiched between the friction blocks 44, and a damping spring is provided at one end of the friction block 44 away from the stamping component 47. The 45s are connected so as to have elasticity, one end of the damping spring 45 separated from the stamping component 47 is fixedly connected to the turntable 25, and a cam space 13 is provided in the upper wall of the stamping box 11. The stamping mechanism 101 is installed in the cam space 13, the stamping rod 22 is installed in the stamping mechanism 101, and the stamping block 24 is installed at the lower end of the stamping rod 22. The mechanism 101 drives the stamping rod 22 and slides it in the vertical direction so that the stamping block 24 can press the stamping component 47 onto the chip substrate 34, and the stamping component 47 can be pressed into the right wall of the stamping box 11. A stamping power space 200 is installed, a stamping power mechanism 201 is installed in the stamping power space 200, and the stamping power mechanism 201 supplies power to the belt 33, the turntable 25, and the stamping mechanism 101. A gear space 300 is installed in the lower wall of the stamping power space 200, a gear setting mechanism 301 is installed in the gear space 300, and a rotatable power is installed in the stamping power mechanism 201. A shaft 49 is installed, the lower end of the power shaft 49 extends into the gear space 300, and a rotatable first bevel gear 55 is installed in the gear setting mechanism 301. The upper end of 55 is fixedly connected to the power shaft 49, and the stamping power mechanism 201 is in front. Power is transmitted to the gear setting mechanism 301 via the power shaft 49 and the first bevel gear 55, and a rotatable vertical transmission shaft 21 is installed in the stamping power mechanism 201, and the vertical transmission is performed. The first transmission gear 19 is fixedly installed at the upper end of the shaft 21, the second transmission gear 18 is connected to the left end of the first transmission gear 19 so as to mesh with each other, and the second transmission gear 18 is connected to the left end of the second transmission gear 18. The lateral transmission shaft 17 is fixedly installed, a rotatable first connecting gear 16 is installed in the stamping mechanism 101, and the left end of the lateral transmission shaft 17 is fixedly connected to the first connecting gear 16. The power can be transmitted to the stamping mechanism 101.

To be beneficial, the first spur gear 36 is fixedly installed at the right end of the pulley shaft 31, and the second spur gear 35 is connected to the lower end of the first spur gear 36 so as to mesh with the second spur gear 36. A connecting shaft 29 is fixedly installed at the axis of the spur gear 35, a first timing gear 28 is fixedly installed at the left end of the connecting shaft 29, and a second timing gear 28 is fixedly installed at the upper end of the first timing gear 28. The timing gears 27 are connected so as to mesh with each other, and the upper end of the second timing gear 27 is fixedly connected to the turntable shaft 26.

The stamping power mechanism 201 includes a main motor 48 fixedly installed in the lower wall of the stamping power space 200, and the power shaft 49 is movably connected to the main motor 48 so that the power shaft 49 can be transmitted. The spline shaft 54 is installed so as to cover the upper end of the spline shaft 54, the spline shaft 54 is connected to the power shaft 49 by a spline, and the upper end of the spline shaft 54 is connected so as to mesh with the vertical transmission shaft 21. A magnetic slider 53 is symmetrically installed at both left and right ends of the spline shaft 54, a spring 52 is elastically connected to the lower end of the magnetic slider 53, and an electromagnet is attached to the lower end of the spring 52. 51 is fixedly installed.

The stamping mechanism 101 includes a cam shaft 15 rotatably installed in the cam space 13, and a second connecting gear 14 is fixedly installed on the cam shaft 15 at the right end of the second connecting gear 14. Is meshed with the first connecting gear 16, a stamping cam 12 is fixedly installed on the cam shaft 15, and the stamping cam 12 is located at the rear end of the second connecting gear 14.

To be beneficial, two buffer cylinders 37 are fixedly installed in symmetrical positions on the top wall of the stamping operating space 100, and an oil storage space 39 is installed in the buffer cylinder 37 to store the oil. A piston rod 42 slidable in the vertical direction is installed in the space 39, a branch oil pipe 38 is installed at the left end of the oil storage space 39 so as to communicate with the branch oil pipe 38, and a buffer spring 43 is installed at the lower end of the buffer cylinder 37. Is elastically connected, the lower end of the piston rod 42 is fixedly connected to the connecting rod 23, and the lower end of the buffer spring 43 is elastically connected to the connecting rod 23. One end close to the stamping block 24 is fixedly connected to the stamping rod 22.

The gear setting mechanism 301 includes a rotatably installed first constant position shaft 57 in the gear space 300, and a second umbrella gear 56 is fixedly installed on the first constant position shaft 57, and the second gear is fixedly installed. The upper end of the bevel gear 56 is connected so as to mesh with the first bevel gear 55, the fan-shaped gear 58 is fixedly installed on the first constant position shaft 57, and the fan-shaped gear 58 is after the second bead gear 56. The second localization shaft 62 is fixedly installed at the end of the fan-shaped gear 58 so that the intermittent gear 61 meshes with the lower end of the fan-shaped gear 58, and the second localization shaft 62 is fixedly installed at the axis of the intermittent gear 61. A third bevel gear 59 is fixedly installed in the vehicle, the third bead gear 59 is located at the rear end of the intermittent gear 61, and the fourth bevel gear 63 is engaged with the left end of the third bead gear 59. The left end of the fourth bevel gear 63 is fixedly connected to the pulley shaft 31.

Hereinafter, the procedure for using the automatic manufacturing apparatus for the electronic stamping component of the present invention will be described in detail with reference to FIGS. 1 to 6: In the initial state, the electromagnet 51 is not energized, and the spline shaft 54 and the vertical transmission shaft 21 Is separated, the main motor 48 does not operate, and the stamping block 24 is located at the upper end of the turntable 25.

When the invention of the present application operates, first, the stamping component 47 is placed in the turntable 25, the stamping component 47 is tightly sandwiched between the friction blocks 44, and then the main motor 48 is operated, and the main motor 48 operates the power shaft 49. The power shaft 49 is driven and rotated by the first bevel gear 55 and the second bevel gear 56 to drive and rotate the first constant position shaft 57, and the first constant position shaft 57 is second by the fan-shaped gear 58 and the intermittent gear 61. The localization shaft 62 is driven and rotated, the second localization shaft 62 drives and rotates the pulley shaft 31 by the third gear 59 and the fourth gear 63, and the pulley shaft 31 drives the belt 33 by the belt pulley 32. The belt 33 can transport the chip substrate 34 to the designated position, and at the same time, the pulley shaft 31 drives the connecting shaft 29 by the first spur gear 36 and the second spur gear 35 to rotate the connecting shaft 29. The rotary disk shaft 26 is driven and rotated by the first timing gear 28 and the second timing gear 27, and the rotary disk shaft 26 drives and rotates the rotary disk 25, whereby the stamping component 47 is rotated to the designated position. After that, the intermittent gear 61 and the fan-shaped gear 58 are separated, the belt 33 and the turntable 25 stop rotating, and at the same time, the power shaft 49 drives and rotates the spline shaft 54. At this time, the electromagnet 51 is energized and the electromagnet 51 generates a magnetic force to repel the magnetic slider 53 and slide it upward, the magnetic slider 53 drives the spline shaft 54 and slides it upward, and the spline shaft 54 is connected so as to mesh with the vertical transmission shaft 21. As a result, the power shaft 49 drives and rotates the vertical transmission shaft 21 by the spline shaft 54, and the vertical transmission shaft 21 drives the horizontal transmission shaft 17 by the first transmission gear 19 and the second transmission gear 18. Rotated, the lateral transmission shaft 17 drives and rotates the cam shaft 15 by the first connecting gear 16 and the second connecting gear 14, the cam shaft 15 drives and rotates the stamping cam 12, and the stamping cam 12 drives the stamping rod. 22 is pushed and moved downward, the stamping rod 22 drives the stamping block 24 and slides downward, and the stamping block 24 pushes the stamping component 47 downward and presses it against the chip substrate 34. Is over.

The beneficial effects of the present invention are: The present invention is simple to configure, convenient to maintain and use, and the stamping mechanism installed inside the present invention can automatically and quickly press electronic components onto the substrate, processing process. It simplifies the operation procedure, greatly improves the production efficiency of electronic stamping, and the whole processing work is simple and easy to operate, and does not hurt the worker's body.

The above is merely a specific embodiment of the invention, the scope of protection of the invention is not limited to this, and any changes or replacements that can be conceived without the passage of creative labor are within the scope of protection of the invention. Including inside. Therefore, the scope of protection of the invention should be based on the scope of protection limited to the claims.

Claims (6)

A stamping working space is installed in the stamping box including a stamping box, rotatable pulley shafts are installed in the left and right side walls of the stamping working space, and belt pulleys are mounted on the pulley shafts in front, back, left and right. Installed symmetrically, a belt is connected to the belt pulley, and a chip substrate can be placed on the belt.
A rotatable rotating disk shaft is installed in the left wall of the stamping box, a rotating disk is fixedly installed on the rotating disk shaft, and six are arranged symmetrically in the rotating disk. Two friction blocks are installed, a stamping component can be sandwiched between the friction blocks, and a damping spring is elastically connected to one end of the friction block away from the stamping component. One end away from the stamping component is fixedly connected to the turntable, a cam space is installed in the upper wall of the stamping box, a stamping mechanism is installed in the cam space, and the stamping is performed. A stamping rod is installed in the mechanism, a stamping block is installed at the lower end of the stamping rod, and the stamping mechanism drives the stamping rod and slides it in the vertical direction so that the stamping block becomes the stamping component. Can be pressed onto the chip substrate
A stamping power space is installed in the right wall of the stamping box, a stamping power mechanism is installed in the stamping power space, and the stamping power mechanism powers the belt, the turntable, and the stamping mechanism. A gear space is installed in the lower wall of the stamping power space, a gear setting mechanism is installed in the gear space, and a rotatable power shaft is installed in the stamping power mechanism. The lower end of the power shaft extends into the gear space, a rotatable first bevel gear is installed in the gear setting mechanism, and the upper end of the first bevel gear is fixed to the power shaft. The stamping power mechanism transmits power to the gear setting mechanism via the power shaft and the first bevel gear.
A rotatable vertical transmission shaft is installed in the stamping power mechanism, a first transmission gear is fixedly installed at the upper end of the vertical transmission shaft, and a second transmission gear is installed at the left end of the first transmission gear. The transmission gears are connected so as to mesh with each other, a lateral transmission shaft is fixedly installed at the left end of the second transmission gear, a rotatable first connecting gear is installed in the stamping mechanism, and the lateral transmission shaft is installed. An automatic manufacturing apparatus for electronic stamping parts, characterized in that the left end of the gear is fixedly connected to the first connecting gear and power can be transmitted to the stamping mechanism. A first spur gear is fixedly installed at the right end of the pulley shaft, a second spur gear is connected to the lower end of the first spur gear so as to mesh with each other, and a connecting shaft is connected to the axis of the second spur gear. Is fixedly installed, the first timing gear is fixedly installed at the left end of the connecting shaft, and the second timing gear is connected to the upper end of the first timing gear so as to mesh with the second timing gear. The automatic manufacturing apparatus for electronic stamping parts according to claim 1, wherein the upper end of the gear is fixedly connected to the rotating disk shaft. The stamping power mechanism includes a main motor fixedly installed in the lower wall of the stamping power space, the power shaft is movably connected to the main motor, and a spline shaft is connected to the upper end of the power shaft. Is installed so as to cover, the spline shaft is connected to the power shaft by a spline, and the upper end of the spline shaft can be connected so as to mesh with the vertical transmission shaft, at both left and right ends of the spline shaft. 1. The magnetic slider is symmetrically installed, a spring is connected to the lower end of the magnetic slider so as to have elasticity, and an electromagnet is fixedly installed at the lower end of the spring. An automatic manufacturing device for electronic stamping parts as described in. The stamping mechanism includes a camshaft rotatably installed in the cam space, a second connecting gear is fixedly installed on the camshaft, and the right end of the second connecting gear is the first connecting gear. The automatic manufacturing apparatus for electronic stamping parts according to claim 3, wherein a stamping cam is fixedly installed on the cam shaft, and the stamping cam is located at the rear end of the second connecting gear. .. Two buffer cylinders are fixedly installed on the top wall of the stamping operating space at symmetrical positions, an oil storage space is installed in the buffer cylinder, and slides in the vertical direction in the oil storage space. possible piston rod is installed, the left end of the oil storage space is disposed to branch oil pipe are communicated, the the lower end of the shock absorbing cylinder is connected to the buffer spring has a resilient, the lower end of the piston rod It is fixedly connected to the connecting rod , the lower end of the buffer spring is elastically connected to the connecting rod, and one end of the connecting rod close to the stamping block is fixedly connected to the stamping rod. The automatic manufacturing apparatus for electronic stamping parts according to claim 4. The gear setting mechanism includes a rotatably installed first constant axis in the gear space, a second bevel gear is fixedly installed on the first constant axis, and the upper end of the second bevel gear is fixed. It is connected so as to mesh with the first bevel gear, a fan-shaped gear is fixedly installed on the first constant axis, the fan-shaped gear is located at the rear end of the second bead gear, and is located at the lower end of the fan-shaped gear. The intermittent gears are connected so as to mesh with each other, the second localization shaft is fixedly installed on the axis of the intermittent gear, and the third bevel gear is fixedly installed on the second localization shaft. The bevel gear is located at the rear end of the intermittent gear, the fourth bevel gear is connected to the left end of the third bead gear so as to mesh with the fourth bead gear, and the left end of the fourth bead gear is fixedly connected to the pulley shaft. The automatic manufacturing apparatus for electronic stamping parts according to claim 3, wherein the electronic stamping parts are manufactured.

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