CN211003069U - Capacitor feeding device - Google Patents

Abstract

A capacitor loading device is characterized by comprising a driving assembly, a capacitor loading transmission assembly and capacitor strips, wherein the upper end of the driving assembly is installed in a stepped protective shell, the protective shell is hollow, the capacitor loading transmission assembly is also installed in the protective shell, a channel for transporting the capacitor strips is arranged at the upper end of the protective shell, the driving assembly is used for driving the capacitor loading transmission assembly, and the capacitor loading transmission assembly drives the capacitor strips to move in the channel; the capacitor loading transmission assembly comprises two first transmission parts with the same structure and two second transmission parts with the same structure, the two first transmission parts and the two second transmission parts are symmetrically arranged inside the protective shell in a bilateral mode, the transmission gear of the first transmission part is meshed with the idler wheel of the second transmission part, and the first transmission part and the second transmission parts are matched to transmit a capacitor strip. The beneficial effects of the utility model reside in that: the labor intensity of workers is reduced, the capacitor feeding efficiency is increased, and the labor cost is saved.

Description

Capacitor feeding device

Technical Field

The utility model relates to an automation equipment field especially relates to an electric capacity loading attachment.

Background

When producing the acoustic magnetic product in the EAS theftproof coil trade at present, the material loading work of electric capacity is accomplished by the manual work, and artifical intensity of labour is big, inefficiency, and has spent more cost of labor. However, at present, no equipment capable of realizing automatic capacitor loading in the EAS anti-theft coil industry exists, and therefore a capacitor loading device is urgently needed to solve the problem.

SUMMERY OF THE UTILITY MODEL

Based on this, the utility model provides an electric capacity loading attachment can carry out the automatic feeding of electric capacity for the in-process of EAS theftproof coil trade production acoustomagnetic product, with electric capacity automatic transportation to the mechanism department of one process down, reduced artifical intensity of labour, increased electric capacity material loading efficiency, practiced thrift the cost of labor.

In order to realize the utility model discloses a purpose, the utility model discloses a following technical scheme:

a capacitor loading device comprises a driving assembly, a capacitor loading transmission assembly and capacitor strips, wherein the upper end of the driving assembly is installed in a stepped protective shell, the protective shell is hollow, the inside of the protective shell is also used for installing the capacitor loading transmission assembly, the driving assembly is connected with the capacitor loading transmission assembly through a synchronous wheel belt, a channel for transporting the capacitor strips is arranged at the upper end of the protective shell, the driving assembly is used for driving the capacitor loading transmission assembly, and the capacitor loading transmission assembly drives the capacitor strips to move in the channel; the capacitor loading transmission assembly comprises two first transmission parts with the same structure and two second transmission parts with the same structure, the two first transmission parts and the two second transmission parts are symmetrically arranged in the protective shell in a bilateral mode, the first transmission parts are arranged right behind the second transmission parts, transmission gears of the first transmission parts are meshed with idler wheels of the second transmission parts, and the first transmission parts and the second transmission parts are matched to be used for transmitting capacitor strips.

Preferably, the drive assembly includes step motor and installs at step motor epaxial second synchronizing wheel, the step motor up end is installed under the protective housing on the terminal surface, the second synchronizing wheel passes through the through-hole that the terminal surface was equipped with under the protective housing stretches into to in the protective housing, still install the synchronizing wheel belt on the second synchronizing wheel, the synchronizing wheel belt still with the first synchronizing wheel of first transmission piece is connected, the synchronizing wheel belt is the triangle-shaped after being connected with first synchronizing wheel and second synchronizing wheel.

Preferably, the first transmission member comprises a first synchronous wheel, a second ball bearing, a transmission gear, a first ball bearing, a first roller and a shaft rod, and the first synchronous wheel, the second ball bearing, the transmission gear, the first ball bearing and the first roller are sequentially arranged on the first shaft rod from bottom to top; the second transmission piece comprises a fourth ball bearing, an idler wheel, a third ball bearing and a second roller wheel, and the fourth ball bearing, the idler wheel, the third ball bearing and the second roller wheel are sequentially arranged on the second shaft lever from bottom to top; the protective housing upper end is equipped with and is used for fixing the through-hole of first driving medium and second driving medium, the shell of the first ball bearing of first driving medium and the shell of the third ball bearing of second driving medium are installed on the through-hole inner wall, and will first driving medium and second driving medium are fixed in the protective housing, first gyro wheel and second gyro wheel stretch out to outside the protective housing.

Preferably, the first shaft lever is in interference fit with the first synchronous wheel, the second ball bearing, the transmission gear, the first ball bearing and the first roller of the first transmission piece; and the second shaft lever is in interference fit with a fourth ball bearing, an idler wheel, a third ball bearing and a second roller of the second transmission piece.

Preferably, two hollow bulges are arranged on the upper end surface of the protective shell, the bulges are communicated with the protective shell, a channel is formed between the two bulges, the channel is used for a capacitor bar to move in, and the capacitor bar is used for placing a capacitor; the protrusion is also provided with a groove for the first roller of the first transmission piece and the second roller of the second transmission piece to roll in.

Preferably, the distance between the first roller of the first transmission member and the second roller of the second transmission member is smaller than the width of the capacitor strip, the first roller and the second roller are matched to drive the capacitor strip to move, and the first roller and the second roller are rollers made of rubber materials.

Preferably, the upper end of the protective shell is further provided with a first optical fiber, the first optical fiber is mounted on a first optical fiber fixing frame arranged on the upper end face of the protective shell, and the first optical fiber is used for detecting the material shortage state of the capacitor; a second optical fiber support is arranged on the back of the protective shell and used for mounting a second optical fiber, and the second optical fiber is used for detecting the in-place state of the capacitor strip; the first optical fiber and the second optical fiber are respectively connected with a controller.

Preferably, a guide plate is further arranged on the right side of the protective shell and used for guiding the capacitor bars to the next process.

The beneficial effects of the utility model reside in that: the automatic capacitor feeding device can automatically feed the capacitors to the mechanism of the next process for the process of producing acoustic magnetic products in the EAS (electronic article surveillance) coil industry, so that the labor intensity is reduced, the capacitor feeding efficiency is increased, and the labor cost is saved.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural diagram of another view angle of the present invention.

Fig. 3 is a schematic view of the internal structure of the present invention.

In the figure: 1-a step motor; 2-a first roller; 3-a second roller; 4-a first optical fiber; 5-capacitor bars; 6-capacitance; 7-protective shell; 8-bulge; 9-a first ball bearing; 10-a transmission gear; 11-a second ball bearing; 12-a first synchronizing wheel; 13-a third ball bearing; 14-an idler wheel; 15-a fourth ball bearing; 16-a second synchronizing wheel; 17-a timing pulley belt; 18-a first fiber mount; 19-a second fiber mount; 20-a second optical fiber; 21-guide plate.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The 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 "secured 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. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present. As used herein, the terms "vertical," "horizontal," "left," "right," and the like are for illustrative purposes only and do not represent the only embodiments, and as used herein, the terms "upper," "lower," "left," "right," "front," "rear," and the like are used in a positional relationship with reference to the drawings.

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 in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

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

The first embodiment is as follows:

as shown in the figure, the capacitor loading device comprises a driving assembly, a capacitor loading transmission assembly and capacitor strips 5, wherein the upper end of the driving assembly is installed in a stepped protective shell 7, the protective shell 7 is hollow, the protective shell 7 is also used for installing the capacitor loading transmission assembly, the driving assembly is connected with the capacitor loading transmission assembly through a synchronous wheel belt 17, a channel for transporting the capacitor strips 5 is arranged at the upper end of the protective shell 7, the driving assembly is used for driving the capacitor loading transmission assembly, and the capacitor loading transmission assembly drives the capacitor strips 5 to move in the channel; the capacitor loading transmission assembly comprises two first transmission parts with the same structure and two second transmission parts with the same structure, the two first transmission parts and the two second transmission parts are arranged inside the protective shell 7 in a pairwise bilateral symmetry mode, the first transmission parts are arranged right behind the second transmission parts, the transmission gears 10 of the first transmission parts are meshed with the idle gears 14 of the second transmission parts, and the first transmission parts and the second transmission parts are matched for transmitting the capacitor bars 5.

Above-mentioned, drive assembly includes step motor 1 and installs at step motor 1 and change epaxial second synchronizing wheel 16, 1 up end of step motor is installed on the terminal surface under the protective housing 7, second synchronizing wheel 16 passes through the through-hole that the terminal surface was equipped with under the protective housing 7 stretches into to in the protective housing 7, still install synchronizing wheel belt 17 on the second synchronizing wheel 16, synchronizing wheel belt 17 still with the first synchronizing wheel 12 of first transmission piece is connected, synchronizing wheel belt 17 is the triangle-shaped after being connected with first synchronizing wheel 12 and second synchronizing wheel 16.

The first transmission piece comprises a first synchronous wheel 12, a second ball bearing 11, a transmission gear 10, a first ball bearing 9, a first roller 2 and a shaft rod, wherein the first synchronous wheel 12, the second ball bearing 11, the transmission gear 10, the first ball bearing 9 and the first roller 2 are sequentially arranged on the first shaft rod from bottom to top; the second transmission piece comprises a fourth ball bearing 15, an idler wheel 14, a third ball bearing 13 and a second roller 3, wherein the fourth ball bearing 15, the idler wheel 14, the third ball bearing 13 and the second roller 3 are sequentially arranged on the second shaft lever from bottom to top; the upper end of the protective shell 7 is provided with a through hole for fixing the first transmission piece and the second transmission piece, the shell of the first ball bearing 9 of the first transmission piece and the shell of the third ball bearing 13 of the second transmission piece are arranged on the inner wall of the through hole, the first transmission piece and the second transmission piece are fixed in the protective shell 7, and the first roller 2 and the second roller 3 extend out of the protective shell 7.

The first shaft lever is in interference fit with the first synchronous wheel 12, the second ball bearing 11, the transmission gear 10, the first ball bearing 9 and the first roller 2 of the first transmission member; the second shaft rod and the fourth ball bearing 15, the idler wheel 14, the third ball bearing 13 and the second roller 3 of the second transmission piece are in interference fit.

The upper end surface of the protective shell 7 is provided with two hollow protrusions 8, the protrusions 8 are communicated with the protective shell 7, a channel is formed between the two protrusions 8, the channel is used for the capacitor bars 5 to move in, and the capacitor bars 5 are used for placing capacitors 6; the protrusion 8 is further provided with a groove for the first roller 2 of the first transmission member and the second roller 3 of the second transmission member to roll therein.

Above, the distance between the first roller 2 of the first transmission member and the second roller 3 of the second transmission member is smaller than the width of the capacitor strip 5, the first roller 2 and the second roller 3 are matched to drive the capacitor strip 5 to move, and the first roller 2 and the second roller 3 are rollers made of rubber materials.

The first optical fiber 4 is further arranged at the upper end of the protective shell 7, the first optical fiber 4 is mounted on a first optical fiber fixing frame 18 arranged on the upper end face of the protective shell, and the first optical fiber 4 is used for detecting the material shortage state of the capacitor 6; a second optical fiber support 19 is arranged on the back of the protective shell, the second optical fiber support 19 is used for installing a second optical fiber 20, and the second optical fiber 20 is used for detecting the in-place state of the capacitor strip 5; the first optical fiber 4 and the second optical fiber 20 are respectively connected with a controller.

Above-mentioned, protective housing 7 right side still establishes deflector 21, deflector 21 is used for leading condenser strip 5 next process department.

When the utility model is used in practice, the stepping motor 1 acts to drive the second synchronizing wheel 16 to rotate, the second synchronizing wheel 16 drives the synchronizing wheel belt 17 meshed with the second synchronizing wheel to rotate, the synchronizing wheel belt 17 drives the first synchronizing wheel 12 to rotate, and after the first synchronizing wheel 12 rotates, the first shaft lever is in interference fit with the first synchronizing wheel to drive the second ball bearing 11, the transmission gear 10, the first ball bearing 9 and the first roller 2 to rotate; after the transmission gear 10 rotates, the idle gear 4 meshed with the transmission gear is driven to rotate, and after the idle gear 4 rotates, the fourth ball bearing 15, the third ball bearing 13 and the second roller 3 are driven to rotate by a second shaft rod in interference fit with the idle gear 4; the rotating directions of the second roller 3 and the first roller 2 are opposite, the capacitor strip 5 is clamped between the second roller 3 and the first roller 1, and the capacitor strip 5 is driven to move after the first roller 1 and the second roller 3 rotate.

Capacitor bar 5 is made by toughness material, makes things convenient for behind capacitor bar 5 moved to deflector 21, and deflector 21 changes capacitor bar 5's moving path and leads capacitor bar 5 next process department.

The first optical fiber 4 can detect whether the capacitor 6 on the capacitor strip 5 is short of material, when the first optical fiber 4 detects that the capacitor 6 is short of material, the information is fed back to the controller, and the controller gives an alarm; the second optical fiber 20 is used for detecting whether the capacitor bar 5 is guided to a correct position, and when the second optical fiber 20 detects that the capacitor bar 5 deviates from a specified position, the information is fed back to the controller, and the controller gives an alarm.

Example two:

can add the cylinder between electric capacity strip 5 and deflector, when electric capacity strip 5 was prepared to get into deflector 21, the piston push rod by the cylinder was earlier released electric capacity strip 5, has certain degree of buckling when making things convenient for electric capacity strip 5 to get into deflector 21, better messenger electric capacity strip 5 removes in deflector 21, is guided to next process department by deflector 21 with electric capacity strip 5.

The beneficial effects of the utility model reside in that: the automatic capacitor feeding device can automatically feed the capacitors to the mechanism of the next process for the process of producing acoustic magnetic products in the EAS (electronic article surveillance) coil industry, so that the labor intensity is reduced, the capacitor feeding efficiency is increased, and the labor cost is saved.

The above embodiments are only used for illustrating the present invention, and not for limiting the present invention, and those skilled in the relevant technical field can make various changes and modifications without departing from the spirit and scope of the present invention, so that all equivalent technical solutions also belong to the scope of the present invention, and the protection scope of the present invention should be defined by the claims.

Claims (8)

1. A capacitor loading device is characterized by comprising a driving assembly, a capacitor loading transmission assembly and capacitor strips, wherein the upper end of the driving assembly is installed in a stepped protective shell, the protective shell is hollow, the capacitor loading transmission assembly is also installed in the protective shell, the driving assembly is connected with the capacitor loading transmission assembly through a synchronous wheel belt, a channel for transporting the capacitor strips is arranged at the upper end of the protective shell, the driving assembly is used for driving the capacitor loading transmission assembly, and the capacitor loading transmission assembly drives the capacitor strips to move in the channel; the capacitor loading transmission assembly comprises two first transmission parts with the same structure and two second transmission parts with the same structure, the two first transmission parts and the two second transmission parts are symmetrically arranged in the protective shell in a bilateral mode, the first transmission parts are arranged right behind the second transmission parts, transmission gears of the first transmission parts are meshed with idler wheels of the second transmission parts, and the first transmission parts and the second transmission parts are matched to be used for transmitting capacitor strips.

2. The capacitor loading device according to claim 1, wherein the driving assembly comprises a stepping motor and a second synchronizing wheel mounted on a rotating shaft of the stepping motor, the upper end face of the stepping motor is mounted on the lower end face of the protective shell, the second synchronizing wheel extends into the protective shell through a through hole formed in the lower end face of the protective shell, a synchronizing wheel belt is further mounted on the second synchronizing wheel and is connected with the first synchronizing wheel of the first transmission member, and the synchronizing wheel belt is in a triangular shape after being connected with the first synchronizing wheel and the second synchronizing wheel.

3. The capacitor loading device according to claim 1, wherein the first transmission member comprises a first synchronous wheel, a second ball bearing, a transmission gear, a first ball bearing, a first roller and a shaft rod, and the first synchronous wheel, the second ball bearing, the transmission gear, the first ball bearing and the first roller are sequentially mounted on the first shaft rod from bottom to top; the second transmission piece comprises a fourth ball bearing, an idler wheel, a third ball bearing and a second roller wheel, and the fourth ball bearing, the idler wheel, the third ball bearing and the second roller wheel are sequentially arranged on the second shaft lever from bottom to top; the protective housing upper end is equipped with and is used for fixing the through-hole of first driving medium and second driving medium, the shell of the first ball bearing of first driving medium and the shell of the third ball bearing of second driving medium are installed on the through-hole inner wall, and will first driving medium and second driving medium are fixed in the protective housing, first gyro wheel and second gyro wheel stretch out to outside the protective housing.

4. A capacitor loading apparatus as claimed in claim 3, wherein the first shaft is in interference fit with the first synchronous pulley, the second ball bearing, the transmission gear, the first ball bearing and the first roller of the first transmission member; and the second shaft lever is in interference fit with a fourth ball bearing, an idler wheel, a third ball bearing and a second roller of the second transmission piece.

5. The capacitor loading device according to claim 1, wherein two hollow protrusions are arranged on the upper end surface of the protective shell, the protrusions are communicated with the protective shell, a channel is formed between the two protrusions, the channel is used for a capacitor strip to move in, and the capacitor strip is used for placing a capacitor; the protrusion is also provided with a groove for the first roller of the first transmission piece and the second roller of the second transmission piece to roll in.

6. A capacitor loading apparatus as defined in claim 5, wherein the distance between the first roller of the first transmission member and the second roller of the second transmission member is less than the width of the capacitor strip, the first roller and the second roller are adapted to move the capacitor strip, and the first roller and the second roller are made of rubber.

7. The capacitor feeding device according to claim 1, wherein a first optical fiber is further arranged at the upper end of the protective shell, the first optical fiber is mounted on a first optical fiber fixing frame arranged on the upper end surface of the protective shell, and the first optical fiber is used for detecting the material shortage state of the capacitor; a second optical fiber support is arranged on the back of the protective shell and used for mounting a second optical fiber, and the second optical fiber is used for detecting the in-place state of the capacitor strip; the first optical fiber and the second optical fiber are respectively connected with a controller.

8. The capacitor loading device according to claim 1, wherein a guide plate is further arranged on the right side of the protective shell, and the guide plate is butted with the channel for transporting the capacitor strip.

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