CN112548003B

CN112548003B - CNC spring machine

Info

Publication number: CN112548003B
Application number: CN201910849982.4A
Authority: CN
Inventors: 卜常军
Original assignee: Jiangsu Jinli Spring Technology Co ltd
Current assignee: Jiangsu Jinli Spring Technology Co ltd
Priority date: 2019-09-10
Filing date: 2019-09-10
Publication date: 2025-01-21
Anticipated expiration: 2039-09-10
Also published as: CN112548003A

Abstract

The invention relates to a computer numerical control spring machine. The computer numerical control spring machine comprises a wire feeding mechanism, a spring winding host machine, a numerical control platform and a receiving mechanism, wherein the wire feeding mechanism is arranged on one side of the spring winding host machine, the numerical control platform is arranged on the other side of the spring winding host machine and is electrically connected with the spring winding host machine, the receiving mechanism is arranged at the bottom of the spring winding host machine and is used for collecting fallen springs, the receiving mechanism comprises a guide seat, a baffle plate and a collecting seat, the guide seat is arranged at the bottom of the spring winding host machine, a tapered groove is formed in the guide seat, and an inclined guide surface is formed in the side wall of the tapered groove. The computer numerical control spring machine is convenient for collect the arrangement spring, improves the production efficiency of spring.

Description

Computer numerical control spring machine

Technical Field

The invention relates to a computer numerical control spring machine.

Background

The existing spring machine is generally a numerical control spring machine, a main shaft is utilized to drive a steel wire to rotate, and then multiple shafts are utilized to process, so that a spiral spring is formed. The spring is collected by the collecting device. However, the springs collected by the existing collecting device are disordered, which is not beneficial to the arrangement of a large number of springs, and further affects the production efficiency of the springs.

Disclosure of Invention

Based on the above, it is necessary to provide a computer numerical control spring machine which is convenient for sorting springs.

The utility model provides a computer numerical control spring machine, includes wire feeding mechanism, spring coiling host computer, numerical control platform and receipts material mechanism, wire feeding mechanism set up in one side of spring coiling host computer, numerical control platform set up in the opposite side of spring coiling host computer, and with spring coiling host computer electric connection, receipts material mechanism set up in the bottom of spring coiling host computer for collect the spring that falls down, receipts material mechanism includes the guide seat, keeps off and establish board and collection seat, the guide seat set up in the bottom of spring coiling host computer, be provided with the convergent groove on the guide seat, the lateral wall in convergent groove is formed with the slope guide face, the inner chamber size in convergent groove reduces gradually along the direction towards the ground, keep off and establish the board keep off and locate one side in convergent groove, keep off and establish the board with the slope guide face sets up relatively, keep off and establish the board with the distance between the slope guide face reduces gradually along the direction towards the ground, the bottom in convergent groove is provided with the guide pipe, the collection seat is located the below of guide seat, a plurality of collection holes are used for seting up to collecting the guide seat in order.

In one embodiment, the bottom of the inclined guide surface is provided with a vertical surface, and the vertical surface is smoothly connected with the inclined guide surface through an arc surface.

In one embodiment, two opposite sides of the inclined guide surface are convexly provided with two guide side walls, the guide seat is convexly provided with a guide frame, one of the guide side walls is rotatably provided with an inclined baffle plate, and the inclined baffle plate extends to the inclined guide surface.

In one embodiment, the introducing frame comprises a main board and clamping boards protruding from two opposite sides of the main board, and the two clamping boards are respectively connected to the two guiding side walls.

In one embodiment, a clamping gap is formed between the two clamping plates, and the width of the clamping gap is smaller than the diameter of the spring.

In one embodiment, the clamping gap is located at a side far away from the main board, and the bottom of the blocking plate is fixed to the top end of the guide pipe.

In one embodiment, the surface of the main plate is formed with a vertical guide surface, the top end of the inclined guide surface is engaged with the bottom end of the vertical guide surface, and the included angle between the inclined guide surface and the vertical guide surface is 130-150 degrees.

In one embodiment, the distance between the two guide side walls decreases gradually in the direction towards the ground, the guide tube having an inner diameter that is 1.1-1.3 times the outer diameter of the spring.

In one embodiment, the surface of the inclined guide surface is provided with an elastic absorbing layer, and the guide tube is provided with a deflector rod narrow gap, and the deflector rod narrow gap extends along the length direction of the guide tube.

When the computerized numerical control spring machine is used, the collecting seat moves to enable one of the collecting holes to be aligned with the guide pipe, the spring manufactured on the spring winding host machine falls into the tapered groove of the guide seat and descends under the gravity, the tapered groove and the blocking plate guide the spring to be changed into an axial downward direction, then the spring enters the guide pipe, and finally the spring is vertically inserted into the collecting hole of the collecting seat. The collection seat is then advanced to align the other collection aperture with the guide tube in preparation for collecting the spring again. Through the tapering groove with the cooperation of board is established to the fender, can be comparatively geographic along the direction of spring, can be comparatively convenient then with the spring arrangement extremely on the collection seat, improved the collection efficiency and the production efficiency of spring.

Drawings

Fig. 1 is a schematic perspective view of a computer numerical control spring machine according to an embodiment.

Fig. 2 is a schematic perspective view of a receiving mechanism according to an embodiment.

Fig. 3 is a schematic perspective view of a part of a structure of a receiving mechanism in an embodiment.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The invention relates to a computer numerical control spring machine. For example, the computer numerical control spring machine comprises a wire feeding mechanism, a spring winding host, a numerical control platform and a material receiving mechanism, wherein the wire feeding mechanism is arranged on one side of the spring winding host. For example, the numerical control platform is arranged at the other side of the spring winding host machine and is electrically connected with the spring winding host machine, and the material receiving mechanism is arranged at the bottom of the spring winding host machine and is used for collecting fallen springs. For example, the material receiving mechanism comprises a guide seat, a blocking plate and a collecting seat, wherein the guide seat is arranged at the bottom of the spring winding host, a tapered groove is formed in the guide seat, and an inclined guide surface is formed on the side wall of the tapered groove. For example, the size of the inner cavity of the tapered groove gradually decreases along the direction towards the ground, the blocking plate is blocked at one side of the tapered groove, and the blocking plate is arranged opposite to the inclined guide surface of the guide seat. For example, the distance between the blocking plate and the inclined guide surface gradually decreases along the direction towards the ground, the bottom of the tapered groove is provided with a guide tube, and the collecting seat is positioned below the guide seat. For example, the collecting seat is provided with a plurality of collecting holes, and the collecting holes are used for aligning the guide pipes in sequence.

Referring to fig. 1 to 3, a computerized numerical control spring machine 100 includes a wire feeding mechanism, a spring winding host 20, a numerical control platform 30 and a material receiving mechanism 40, the wire feeding mechanism is disposed on one side of the spring winding host 20, the numerical control platform 30 is disposed on the other side of the spring winding host 20 and is electrically connected with the spring winding host 20, the material receiving mechanism 40 is disposed on the bottom of the spring winding host 20 and is used for collecting fallen springs 200, the material receiving mechanism 40 includes a guide seat 41, a blocking plate 42 and a collecting seat 45, the guide seat 41 is disposed on the bottom of the spring winding host 20, a tapered slot 411 is disposed on the guide seat 41, an inclined guide surface 413 is formed on a side wall of the tapered slot 411, the inner cavity size of the tapered slot 411 gradually decreases along a direction towards the ground, the blocking plate 42 is disposed on one side of the tapered slot 411, the blocking plate 42 is disposed opposite to the inclined guide 413 of the guide seat 41, the blocking plate 42 and the inclined guide seat 41 are disposed opposite to each other, the guide seat 45 is disposed between the blocking plate 42 and the inclined guide seat 41 along the inclined guide surface towards the bottom direction 45, and the collecting seat is disposed on the guide seat 45 along the tapered guide seat 45.

When the computer numerical control spring machine 100 is in use, the collection seat 45 moves to align one of the collection holes 451 with the guide tube 415, the spring 200 made on the spring winding host 20 falls into the tapered slot 411 of the guide seat 41 and descends under gravity, the tapered slot 411 and the baffle plate 42 guide the spring 200 to turn to an axially downward direction, then enter the guide tube 415, and finally vertically insert into the collection hole 451 of the collection seat 45. The collection seat 45 is then advanced to align the other collection aperture 451 with the guide tube 415 in preparation for the spring 200 to be collected again. Through the cooperation of the tapering groove 411 with the fender board 42 can be comparatively geographical along the direction of spring 200, then can comparatively conveniently with spring 200 arrangement to on the collection seat 45, improved spring 200's collection efficiency and production efficiency.

For example, in order to facilitate guiding the spring 200, a bottom of the inclined guide surface 413 is provided with a vertical surface 414, and the vertical surface 414 is smoothly connected to the inclined guide surface 413 through an arc surface. Two guide side walls 416 are convexly provided on opposite sides of the inclined guide surface 413, the guide seat 41 is convexly provided with a guide frame 47, one of the guide side walls 416 is rotatably provided with an inclined baffle 417, and the inclined baffle 417 extends onto the inclined guide surface 413. The introduction frame 47 includes a main plate 471 and clamping plates 473 protruding from opposite sides of the main plate 471, the two clamping plates 473 being respectively connected to the two guide side walls 416. A clamping gap 4135 is formed between the two clamping plates 473, the clamping gap 4135 having a width smaller than the diameter of the spring 200. The clamping gap 4135 is located on a side away from the motherboard 471. By providing the lead-in frame 47, the spring 200 can be collected by the lead-in frame 47. The inclined baffle 417 may block one end of the spring 200, so that the spring 200 does not drop laterally, and one end of the spring 200 is guided to move downward.

For example, to facilitate final centering of the spring 200, the bottom of the stop plate 42 is fixed to the top end of the guide tube 415. The surface of the main plate 471 is formed with a vertical guide surface 4715, the top end of the inclined guide surface 413 is engaged with the bottom end of the vertical guide surface 4715, and the included angle between the inclined guide surface 413 and the vertical guide surface 4715 is 130-150 degrees. The distance between the two guide sidewalls 416 is gradually reduced in a direction toward the ground, and the inner diameter of the guide tube 415 is 1.1-1.3 times the outer diameter of the spring 200. The surface of the inclined guiding surface 413 is provided with an elastic absorbing layer, the guiding tube 415 is provided with a driving lever narrow gap 4155, and the driving lever narrow gap 4155 extends along the length direction of the guiding tube 415. An elastic receiving layer is disposed on the surface of the inclined guiding surface 413, so that after the spring 200 falls along the vertical guiding surface 4715, the spring 200 is impacted on the elastic receiving layer to absorb the elastic force thereof to prevent the spring 200 from being sprung too far, and the blocking plate 42 can block back the spring 200 after the elastic impact, and the spring 200 impacts on the inclined baffle 417 again, so that one end of the spring is downward, and the direction of the spring is initially aligned, after which the spring 200 falls down along the inclined baffle 417 and falls into the guiding tube 415, and the direction of the spring is finally aligned.

For example, it is particularly important that the collecting seat 45 is moved conveniently, the collecting mechanism 40 further includes a conveying frame 46 and a pushing cylinder 48, a conveying channel 461 is formed on the conveying frame 46, a plurality of steel rods 4615 are disposed on a bottom surface of the conveying channel 461, the collecting seat 45 is slidably disposed in the conveying channel 461 and supported on the plurality of steel rods 4615, and the pushing cylinder 48 is disposed at one end of the conveying frame 46 and abuts against the collecting seat 45, so as to push the collecting seat 45 to intermittently move. For example, in order to facilitate slowing down the descent speed of the spring 200 and thus facilitate adjusting the angle of the spring 200, a closed electric control coil is disposed in the guide tube 415, and the electric control coil is electrically connected to a first power source 4158, and the first power source 4158 is used for controlling the on-off of the electric control coil so as to generate a magnetic field. Since the spring 200 is made of steel material, after the spring 200 is rapidly introduced into the guide tube 415, the first power source 4158 generates a magnetic field to attract the spring 200 by the generation or disappearance of the current through the electric control coil, thereby slowing down the descent speed of the spring 200. The presence of the lever slot 4155 on the guide tube 415, however, results in a weaker magnetic field on the side of the magnetic field adjacent the lever slot 4155, such that the spring 200 is attracted to the side of the guide tube 415 remote from the lever slot 4155. For example, the guide tube 415 is disposed coaxially with the collection hole 451, and the central axis of the collection hole 451 forms an angle of 85-88 with respect to the bottom surface of the collection seat 45. By the attraction of the magnetic field to the spring 200, the spring 200 is allowed to move downward at a small speed along the side of the guide tube 415 away from the lever slit 4155 and finally smoothly enter the obliquely arranged collection hole 451. Without ejecting the collection hole 451 or hitting the bottom of the collection hole 451 at an excessively fast speed. For example, the presence of the lever slot 4155 also facilitates the ability to puncture the spring 200 by inserting the lever into the lever slot 4155 when the spring 200 is jammed within the guide tube 415.

For example, in order to prevent the subsequent spring 200 from blocking the guide tube 415 after the spring 200 falls onto the inclined guide surface 413, the end of the inclined guide surface 413 is connected to one of the guide side walls 416, and a holding spring is disposed in the middle of the guide side wall 416, and the end of the holding spring away from the inclined guide surface 413 is connected to the guide side wall 416, and the holding spring holds the inclined baffle 417 at an inclined angle. In order to close the tapered slot 411, a telescopic bag body is arranged in the middle of the supporting spring, the telescopic bag body extends along the central axis of the supporting spring, a disc magnet is arranged at the end of the telescopic bag body, and the disc magnet is adsorbed on the inclined baffle 417 to stretch the telescopic bag body. The abutting spring is wound with an actuating coil adjacent to the distal end of the guiding sidewall 416, and the actuating coil is electrically connected to the second power source. The second power supply is used for powering the actuation coil, so that the actuation coil generates a magnetic field, and forces the disc magnet to pull up the telescopic capsule body and away from the actuation coil, so as to push the inclined baffle 417 to rotate to stop the tapered slot 411 and temporarily stop the descent of the spring 200. Thereafter, the second power supply is stopped, so that the spring 200 is lowered onto the inclined guide surface 413 by gravity, and the blocking action of the inclined baffle 417 is performed, so as to delay the time that the spring 200 reaches the guide tube 415, and avoid the blockage caused by that two springs 200 enter the guide tube 415 at the same time. For example, the actuation coil extends along the spiral of the hold-down spring and the number of turns is greater than the number of turns of the hold-down spring.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above embodiments represent only a few embodiments of the present invention, which are described in more detail and are not to be construed as limiting the scope of the present invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims

1. The computerized numerical control spring machine is characterized by comprising a wire feeding mechanism, a spring winding host, a numerical control platform and a material receiving mechanism, wherein the wire feeding mechanism is arranged on one side of the spring winding host, the numerical control platform is arranged on the other side of the spring winding host and is electrically connected with the spring winding host, the material receiving mechanism is arranged at the bottom of the spring winding host and is used for collecting fallen springs, the material receiving mechanism comprises a guide seat, a blocking plate and a collecting seat, the guide seat is arranged at the bottom of the spring winding host, a tapered groove is arranged on the guide seat, an inclined guide surface is formed on the side wall of the tapered groove, the inner cavity size of the tapered groove gradually decreases along the direction facing the ground, the blocking plate is blocked on one side of the tapered groove, the blocking plate and the inclined guide surface of the guide seat are oppositely arranged, the distance between the blocking plate and the inclined guide surface gradually decreases along the direction facing the ground, a guide pipe is arranged at the bottom of the tapered groove, the collecting seat is positioned below the guide seat, and a plurality of collecting holes are formed on the guide seat and used for collecting the collecting pipes sequentially.

Two opposite sides of the inclined guide surface are convexly provided with two guide side walls, the guide seat is convexly provided with a guide frame, one of the guide side walls is rotatably provided with an inclined baffle plate, and the inclined baffle plate extends to the inclined guide surface;

The collecting mechanism further comprises a conveying frame and a pushing cylinder, a conveying channel is formed in the conveying frame, a plurality of steel rods are arranged on the bottom surface of the conveying channel, the collecting seat is slidably arranged in the conveying channel and supported on the plurality of steel rods, the pushing cylinder is arranged at one end of the conveying frame and abuts against the collecting seat and is used for pushing the collecting seat to intermittently move, a closed electric control coil is arranged in the guide tube and is electrically connected with a first power supply, the first power supply is used for controlling the on-off of the electric control coil so as to generate a magnetic field, the guide tube and the collecting hole are coaxially arranged, an included angle of 85-88 degrees is formed between the central axis of the collecting hole and the bottom surface of the collecting seat, one end of the inclined guide surface is connected to one of the guide side walls, an abutting spring is arranged at the middle part of the guide side wall and is far away from the inclined guide surface and is connected to the guide side wall, the abutting spring abuts against the inclined guide side wall, the inclined guide spring is arranged at an angle, the electric control coil is electrically connected with a first power supply, the first power supply is used for controlling the on-off of the electric control coil so as to generate a tapered magnetic field, the central axis of the collecting hole forms an included angle of 85-88 degrees with the collecting hole, the magnetic field is opposite to the bottom surface of the collecting seat, the inclined guide side is connected to the guide side wall, the middle part is provided with an abutting spring is provided with an abutting against a supporting spring, and abutting spring far from the inclined guide bag on the inclined guide side, and one end is far from the magnet, and far from the inclined guide side is far from the magnet wire, and is far from the magnet moving magnet, and is used for pushing the magnet. The second power supply stops energizing to enable the spring to descend to the inclined guide surface under the action of gravity, the actuating coil extends along the spiral line of the abutting spring, and the concentration of turns of the actuating coil is larger than that of the abutting spring.

2. The computer numerical control spring machine according to claim 1, wherein the bottom of the inclined guiding surface is provided with a vertical surface, and the vertical surface is smoothly connected with the inclined guiding surface through an arc surface.

3. The computer numerical control spring machine according to claim 2, wherein the introducing frame comprises a main plate and two clamping plates protruding from two opposite sides of the main plate, and the two clamping plates are respectively connected to the two guiding side walls.

4. The computer numerical control spring machine according to claim 3, wherein a clamping gap is formed between the two clamping plates, and the width of the clamping gap is smaller than the diameter of the spring.

5. The computer numerical control spring machine according to claim 4, wherein the clamping gap is located at a side far away from the main board, and the bottom of the blocking plate is fixed at the top end of the guide tube.

6. The computer numerical control spring machine according to claim 5, wherein the surface of the main plate is formed with a vertical guide surface, the top end of the inclined guide surface is engaged with the bottom end of the vertical guide surface, and an included angle between the inclined guide surface and the vertical guide surface is 130-150 degrees.

7. The computer numerical control spring machine according to claim 6, wherein the distance between the two guide side walls gradually decreases in a direction toward the ground, and the inner diameter of the guide tube is 1.1-1.3 times the outer diameter of the spring.

8. The computer numerical control spring machine according to claim 7, wherein the surface of the inclined guide surface is provided with an elastic absorbing layer, the guide tube is provided with a deflector rod slit, and the deflector rod slit extends along the length direction of the guide tube.