CN218224401U - Spring feeding structure applied to battery contact piece riveting equipment - Google Patents

Abstract

The utility model discloses a spring feeding structure applied to battery contact piece riveting equipment, which comprises a processing platform surface, wherein a rotatable rotating disc is arranged on the processing platform surface, a plurality of carriers which are distributed circumferentially at certain scale intervals are arranged on the rotating disc, a workpiece profiling groove is formed on the surface of each carrier, a vertical through hole extending downwards is formed on one side in the workpiece profiling groove, and a sleeve pin column is arranged at the middle position in the vertical through hole; the vibration output end of the spring vibration disk is communicated with a flow channel piece with the bottom extending downwards; an auxiliary plate body is further arranged on the surface of the processing platform, and a material channel penetrating through the upper surface and the lower surface of the auxiliary plate body is formed in the auxiliary plate body. The utility model discloses mainly be in order to realize the good contact of negative pole contact position on spring and the battery contact piece to make things convenient for subsequent riveting work, in order to reduce the cost that artifical pressing spring carries out the location, greatly reduced artifical material resources cost, and can also promote the quality of shaping product.

Description

Spring feeding structure applied to battery contact piece riveting equipment

Technical Field

The utility model belongs to the technical field of the battery fitting technique and specifically relates to a spring loading structure who uses in battery contact piece riveting equipment is related to.

Background

The battery contact piece, also called battery negative plate, is all related to battery application device, such as electronic toy, radio, remote controller and other electronic equipment necessary equipment components, it is generally formed by a pair of metal negative plates with positive and negative contact positions, its positive contact position is generally a projection made by die casting, and its negative contact position is connected to the metal negative plate by means of conductive spring through riveting, high-frequency welding, clamping groove fixing, etc. so as to form the battery contact piece for battery.

Present battery contact riveting production work, generally speaking, the forming die device during operation of one set of battery contact needs the workman manually to fix a position negative pole spring on negative pole contact position, wastes time and energy when fixed, and most of springs adopt cylindrical spring moreover, and this kind of spring takes place horizontal deformation easily when receiving to press, and this is unfavorable for the riveting work between follow-up negative pole spring and the negative pole contact position.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing an use spring material loading structure in battery contact piece riveting equipment guarantees the good contact of spring and negative pole contact position to conveniently carry out the riveting of spring and negative pole contact position.

To achieve the above object, the present invention adopts the following:

the utility model provides an use spring feeding structure in battery contact piece riveting equipment, includes:

the machining platform comprises a machining platform surface, a rotatable rotating disc is arranged on the machining platform surface, a plurality of carriers are circumferentially distributed on the rotating disc at intervals of a certain graduation, a workpiece profiling groove is formed on the surface of each carrier, a vertical through hole extending downwards is formed in one side in the workpiece profiling groove, and a sleeve pin column is arranged in the middle of the vertical through hole;

the vibration output end of the spring vibration disk is communicated with a flow channel piece with the bottom extending downwards;

the processing platform is also provided with an outer frame, a lifting cylinder is arranged above the side wall of the outer frame, the output end of the lifting cylinder is connected with a middle block body, the middle block body is connected with an auxiliary plate body, a material channel penetrating through the upper surface and the lower surface of the auxiliary plate body is formed in the auxiliary plate body, the upper port of the material channel corresponds to the lower port of the flow channel piece, and the lower port of the material channel corresponds to a vertical through hole in the carrier;

the inside of the auxiliary plate body is also movably provided with a transverse dislocation strip so as to separate the material channels, transition through holes corresponding to the material channels are formed in the surface of the dislocation strip, a transverse pull cylinder is arranged on the outer side of the auxiliary plate body, and the output end of the transverse pull cylinder is connected with the dislocation strip through a connecting rod.

As a further technical scheme of the utility model, the upper end of auxiliary plate body is equipped with the last butt joint body that forms the intercommunication with the upper end mouth that the material said, and the lower extreme of auxiliary plate body is equipped with the lower butt joint body that forms the intercommunication with the lower end mouth that the material said.

As a further technical scheme of the utility model, the cross-sectional area of butt joint body from top to bottom gradually diminishes down.

As a further technical scheme of the utility model, the both sides of auxiliary plate body respectively are equipped with a sensor probe respectively to two sensor probes all transversely run through the inside of getting into auxiliary plate body until aiming at the material way.

As a further technical scheme of the utility model, the rolling disc passes through cam wheel splitter and realizes the ascending rotation of circumferencial direction.

As a further technical solution of the present invention, the bottom end of the rotating disc is provided with a plurality of contact blocks circumferentially distributed at a certain graduation interval, the distribution positions of the plurality of contact blocks are consistent with the distribution positions of the plurality of carriers, and both side portions of the contact blocks form a smooth transition portion; the rotary table is characterized in that a supporting side frame is arranged between the rotary table and the surface of the processing platform, a rotatable supporting roller is arranged at the upper end of the supporting side frame, and the contact block can be in sliding contact with the supporting roller in the process of rotating the rotary table.

The utility model discloses mainly be in order to realize the good contact of negative pole contact position on spring and the battery contact piece in battery contact piece riveting equipment to make things convenient for subsequent riveting work, in order to reduce the cost that artifical pressing spring carries out the location, greatly reduced artifical material resources cost, and can also promote the quality of shaping product.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Fig. 1 shows a schematic structural diagram of a spring feeding structure applied to a battery contact piece riveting device according to an embodiment of the present invention;

fig. 2 is a schematic view of a related structure of a carrier according to an embodiment of the present invention;

FIG. 3 is a schematic view of the supporting side frame and the auxiliary plate thereon according to the embodiment of the present invention;

fig. 4 shows a schematic perspective view of an embodiment of the invention in relation to an auxiliary plate;

in the figures, the various reference numbers are:

10-processing platform surface, 20-rotating disc, 30-carrier, 40-spring vibrating disc, 50-runner piece, 60-outer frame, 70-auxiliary plate body, 80-supporting side frame, 210-cam divider, 220-contact block, 310-workpiece profiling groove, 320-vertical through hole, 330-dowel pin, 610-lifting cylinder, 620-middle block body, 630-transverse pulling cylinder, 640-connecting rod, 710-material channel, 711-upper butt joint pipe body, 712-lower butt joint pipe body, 720-dislocation strip, 721-transition through hole, 730-sensor probe and 810-supporting roller.

Detailed Description

In order to illustrate the invention more clearly, the invention is further described below with reference to preferred embodiments. It is to be understood by persons skilled in the art that the following detailed description is illustrative and not restrictive, and is not to be taken as limiting the scope of the invention.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as being fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood as appropriate by those of ordinary skill in the art.

Referring to fig. 1 to 4, an embodiment of the present invention provides a technical solution of a spring loading structure applied in a battery contact piece riveting device: the machining platform comprises a horizontal machining platform surface 10, a rotatable rotating disc 20 is arranged on the horizontal machining platform surface, in one embodiment, the rotating disc 20 realizes rotating rotation and intermittent motion in the circumferential direction through a cam divider 210, a plurality of carriers 30 which are distributed circumferentially at certain intervals are arranged on the rotating disc 20, such as 6-8 carrier stations, the carriers 30 are distributed in central symmetry with the rotating center of the rotating disc 20, workpiece profiling grooves 310 are formed in the surfaces of the carriers 30, the battery contact pieces can be well embedded in the workpiece profiling grooves 310 in a perfect fit mode according to the appearance shapes of the battery contact pieces, downward extending vertical through holes 320 are formed in one side (corresponding to the positions of negative contact positions) in the workpiece profiling grooves 310, and sleeve pins 330 are arranged in the middle positions in the vertical through holes 320 and serve as carriers for sleeving and fixing springs.

The vibration output end of the spring vibration plate 40 is connected to a flow path member 50 extending downward from the bottom, and the spring vibration plate sends out the stored springs one by one.

The processing platform surface 10 is further provided with an outer frame 60, the outer frame 60 is located below the flow channel piece 50, a lifting cylinder 610 is arranged above the side wall of the outer frame 60, the output end of the lifting cylinder 610 is connected with a middle block 620, the middle block 620 is connected with an auxiliary plate body 70, a material channel 710 penetrating through the upper surface and the lower surface of the auxiliary plate body 70 is formed in the auxiliary plate body, the upper port of the material channel 710 corresponds to the lower port of the flow channel piece 50, and the lower port of the material channel 710 corresponds to the vertical through hole 320 in the carrier 30.

Wherein, the inside of the auxiliary plate body 70 is also movably provided with a transverse dislocation strip 720 to separate the material channel 710, the surface of the dislocation strip 720 is provided with a transition through hole 721 corresponding to the material channel 710, the outside of the auxiliary plate body 70 is provided with a transverse pulling cylinder 630, and the output end of the transverse pulling cylinder 630 is connected with the dislocation strip 720 through a connecting rod 640.

When in use: firstly, the rotating disc 20 is driven to rotate, so that a carrier 30 on the rotating disc stops below the auxiliary plate body 70, and the lower port of the material channel 710 is ensured to be right above a vertical through hole 320 on the carrier; in an initial state, the transition through hole 721 on the surface of the dislocated strip 720 in the auxiliary plate body 70 and the material channel 710 are mutually staggered, the lifting cylinder 610 controls the auxiliary plate body 70 to move upwards towards the direction of the flow channel piece 50 until the upper port of the material channel 710 is in butt joint communication with the lower port of the flow channel piece 50, at this time, the spring vibration disc 40 automatically supplies materials, the spring enters the material channel 710 through the lower port of the flow channel piece 50 and the upper port of the material channel 710 and is blocked by the dislocated strip 720, at this time, the dislocated strip 720 is controlled to move outwards by the transverse pulling cylinder 630 until the transition through hole 721 on the surface of the dislocated strip 720 and the material channel 710 are communicated with each other, meanwhile, the lifting cylinder 610 controls the auxiliary plate body 70 to move downwards towards the carrier direction, so that the spring in the material channel 710 falls into the vertical through hole 320 from the lower port of the material channel 710 and is sleeved outside the pin sleeve 330, and finally, the good contact of the negative electrode on the contact piece of the spring and the battery can be easily realized by correspondingly placing the contact piece in the workpiece profiling riveting groove, so as to facilitate the subsequent work; and then, continuously driving the rotating disc to rotate, and repeating the spring loading action on other carriers on the rotating disc.

The upper end of the auxiliary plate 70 is provided with an upper butt-joint pipe 711 communicated with the upper port of the material channel 710, the upper butt-joint pipe is used for better realizing butt joint with the lower port of the flow channel piece, the lower end of the auxiliary plate 70 is provided with a lower butt-joint pipe 712 communicated with the lower port of the material channel 710, and the lower butt-joint pipe is used for better realizing butt joint with the vertical through hole to ensure that the spring can smoothly fall into the vertical through hole.

Further, the cross-sectional area of the lower butt joint pipe body 712 gradually decreases from top to bottom, the workpiece profiling groove is not a regular structural design, and the lower butt joint pipe body designed in this way can be smoothly butted with the upper port of the vertical through hole in the workpiece profiling groove, so that the spring can be ensured to smoothly fall into the vertical through hole.

Two sides of the auxiliary plate body 70 are respectively provided with a sensor probe 730, and the two sensor probes 730 transversely penetrate into the auxiliary plate body 70 until the material channel 710 is aligned, that is, the inside of the auxiliary plate body is provided with an installation slot communicated with the side part of the flow channel, the installation slot is used for arranging the sensor probes, whether a spring flows into the material channel is automatically judged through the sensor probes, and the in-place signal of the spring is fed back to the transverse pulling cylinder.

A plurality of contact blocks 220 are circumferentially distributed at certain graduation intervals at the bottom end of the rotating disc 20, the distribution positions of the contact blocks 220 are consistent with the distribution positions of the carriers 30, and smooth transition parts are formed at two side parts of the contact blocks 220; a supporting side frame 80 is arranged between the rotary disc 20 and the processing platform surface 10, a rotatable supporting roller 810 is arranged at the upper end of the supporting side frame 80, and the contact block 220 can be in sliding contact with the supporting roller 810 in the rotating process of the rotary disc 20. In practical production, the support rollers on the support side frames are used for cooperating with riveting operation of the riveting machine to achieve a certain bearing effect, and after the contact blocks are contacted with the support rollers, the riveting machines on other stations perform corresponding riveting operation on springs and battery contact pieces in the carriers above the contact blocks.

The utility model discloses mainly be in order to realize the good contact of negative pole contact position on spring and the battery contact piece in battery contact piece riveting equipment to make things convenient for subsequent riveting work, in order to reduce the cost that artifical pressing spring carries out the location, greatly reduced artifical material resources cost, and can also promote the quality of shaping product.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and that other variations or modifications of different forms can be made on the basis of the above description for those skilled in the art, and all the embodiments cannot be exhausted here, and all the obvious variations or modifications led out by the technical solutions of the present invention are still in the scope of the present invention.

Claims (6)

1. The utility model provides an use spring feeding structure in battery contact piece riveting equipment which characterized in that includes:

the machining platform comprises a machining platform surface, a rotatable rotating disc is arranged on the machining platform surface, a plurality of carriers are circumferentially distributed on the rotating disc at intervals of a certain graduation, a workpiece profiling groove is formed on the surface of each carrier, a vertical through hole extending downwards is formed in one side in the workpiece profiling groove, and a sleeve pin column is arranged in the middle of the vertical through hole;

the vibration output end of the spring vibration disk is communicated with a flow channel piece with the bottom extending downwards;

the processing platform is characterized in that an outer frame is further arranged on the surface of the processing platform, a lifting cylinder is arranged above the side wall of the outer frame, the output end of the lifting cylinder is connected with a middle block body, an auxiliary plate body is connected onto the middle block body, a material channel penetrating through the upper surface and the lower surface of the auxiliary plate body is formed in the auxiliary plate body, the upper port of the material channel corresponds to the lower port of the flow channel piece, and the lower port of the material channel corresponds to a vertical through hole in the carrier;

the inside of the auxiliary plate body is also movably provided with a transverse dislocation strip so as to separate the material channels, transition through holes corresponding to the material channels are formed in the surface of the dislocation strip, a transverse pull cylinder is arranged on the outer side of the auxiliary plate body, and the output end of the transverse pull cylinder is connected with the dislocation strip through a connecting rod.

2. The spring feeding structure applied to a battery contact piece riveting and pressing device of claim 1, wherein the upper end of the auxiliary plate body is provided with an upper butt-joint tube body communicated with the upper port of the material channel, and the lower end of the auxiliary plate body is provided with a lower butt-joint tube body communicated with the lower port of the material channel.

3. The spring feeding structure applied to the battery contact piece riveting and pressing device according to claim 2, wherein the cross-sectional area of the lower butt joint pipe body gradually decreases from top to bottom.

4. The spring feeding structure applied to the battery contact piece riveting and pressing device as claimed in claim 1, wherein two sides of the auxiliary plate body are respectively provided with a sensor probe, and both sensor probes transversely penetrate into the inner part of the auxiliary plate body until being aligned with the material channel.

5. The spring feeding structure applied to the riveting device for the battery contact piece as claimed in claim 1, wherein the rotating disc is rotated in the circumferential direction by a cam divider.

6. The spring feeding structure applied to the riveting and pressing equipment of the battery contact piece according to claim 1, wherein the bottom end of the rotating disc is provided with a plurality of contact blocks which are circumferentially distributed at certain graduation intervals, the distribution positions of the contact blocks are consistent with the distribution positions of the carriers, and smooth transition parts are formed at two side parts of the contact blocks; the rotary table is characterized in that a supporting side frame is arranged between the rotary table and the surface of the processing platform, a rotatable supporting roller is arranged at the upper end of the supporting side frame, and the contact block can be in sliding contact with the supporting roller in the process of rotating the rotary table.

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