CN217198881U - Battery feed divider - Google Patents

Abstract

The utility model discloses a battery feed divider, which comprises a feed divider and a feed dividing die, wherein the feed divider is arranged in a downward inclination manner and is sequentially divided into a feeding section, a guide section and a feed dividing section, the feeding section is provided with a feeding chute, the guide section is provided with a guide chute and a sliding chute, the guide chute and the sliding chute are alternately arranged, the sliding chute extends to the feed dividing section, the feed dividing section is also provided with a material chute, and the material chute is communicated with the sliding chute; the material distribution die is arranged in the sliding groove in a sliding mode and provided with a plurality of positioning grooves, and the positioning grooves are evenly arranged along the length direction of the material distribution die. The branch material mould removes in the spout, and when the constant head tank moved to the export of baffle box, in the battery got into the constant head tank, along with the lapse of branch material mould, the battery in the baffle box got into in proper order in the constant head tank of branch material mould, when branch material mould removed to the spout bottom, then full battery was deposited in the silo of branch material mould, and the feeder can once get multirow battery like this, improves reinforced speed greatly.

Description

Battery feed divider

Technical Field

The utility model relates to a battery equipment for packing, in particular to button cell feed divider.

Background

The button batteries are placed in the material tray, the button batteries in the material tray are arranged compactly, and the distance between the button batteries needs to be increased according to the sales requirement when the button batteries are packaged, so that material distribution is carried out before packaging, the distance between the button batteries is increased, and the packaging requirement is met; if the materials are not distributed, manual feeding is needed, batteries in the material tray are placed into the bulb shell manually, and therefore manual feeding efficiency is low and cost is high.

The button cell divides the material to adopt that current is independent slide, and the width of slide matches with the external diameter of battery, and the end of slide is the discharge end, and the battery gets into the slide and falls to the discharge end, and the battery is got from the discharge end of slide to the charging means, once can only get one row, consequently reinforced material of need making a round trip to get many times at every turn, influences feed rate.

Disclosure of Invention

In view of the technical problem who exists among the background art, the utility model aims at providing a once provide battery feed divider of multirow material, improve feed rate.

In order to solve the technical problem, the utility model discloses a following technical scheme: this kind of battery feed divider, its characterized in that: comprises that

The material distribution plate is arranged in a downward inclined mode, the material distribution plate is sequentially divided into a feeding section, a guide section and a material distribution section, the feeding section is provided with a feeding chute, the guide section is provided with a guide chute and a sliding chute, the guide chute and the sliding chute are alternately arranged, the guide chute is communicated with the feeding chute, the width of the guide chute is matched with the outer diameter of a material, the sliding chute extends to the material distribution section, the material distribution section is also provided with a material chute, the material chute is communicated with the sliding chute, the width of the material chute is narrower than that of the guide chute, and the inlet of the material chute is communicated with the outlet of the guide chute;

and the material distribution die is arranged in the sliding groove in a sliding manner, a plurality of positioning grooves are formed in the end, adjacent to the trough, of the material distribution die, the positioning grooves are uniformly arranged along the length direction of the material distribution die, and the width sum of the positioning grooves and the trough is matched with the outer diameter of the material.

The utility model discloses a divide the material mould to remove in the spout, when the constant head tank moved to the export of baffle box, in the battery got into the constant head tank, along with the lapse of branch material mould, in the battery in the baffle box got into the constant head tank of branch material mould in proper order, when branch material mould removed to the spout bottom, the silo of branch material mould was then full of batteries, and the charging means can once get multirow battery like this, improves reinforced speed greatly.

Preferably, the positioning groove is arc-shaped and matched with the side surface of the material, so that the battery cannot shake in the positioning groove, the position is accurate, and the charging is facilitated; the inner wall of the joint of the guide chute and the trough is arc-shaped, so that the batteries can conveniently enter the trough and the positioning groove from the guide chute.

Preferably, the material distribution die is connected with a driving assembly I for driving the material distribution die to move in the sliding groove; the first driving assembly comprises a sliding seat, a guide rail and a power part, the guide rail is installed on the lower surface of the material distribution plate, the sliding seat is arranged on the guide rail in a sliding mode and connected with the power part, and the material distribution die penetrates through the sliding groove and is connected with the sliding seat. The driving assembly is arranged at the lower end of the material distributing plate, so that the effect above the material distributing plate is not influenced.

Preferably, a material blowing part is arranged above the material guiding section, a gas blowing hole is formed in the material blowing part, and the gas flow of the gas blowing hole faces the moving direction of the material; increasing the power and speed of the battery moving downwards.

Preferably, a limiting piece is arranged at an outlet of the guide chute; the limiting part is a material blocking block, and the material blocking block is connected with a driving assembly II for driving the material blocking block to enter and exit the material guide groove. The next battery that gets into the constant head tank from the baffle block in with the baffle box blocks, and only one battery can get into the constant head tank like this once, avoids the battery crowdedly to cause the jam.

Preferably, the second driving assembly comprises a lifting plate, and the material blocking block is installed on the lifting plate.

Preferably, the feeding section is provided with a material homogenizing member, and the material homogenizing member comprises a moving block moving in the feeding section. The moving block moves at the feed end, so that the materials uniformly enter the guide chute.

Preferably, the moving blocks are provided with a plurality of moving blocks and are arranged on the moving plate which moves transversely in a reciprocating manner; the material distributing plate is provided with a linear guide rail which is transversely arranged, the moving plate is arranged on the linear guide rail in a sliding mode, and the moving plate is connected with the power part.

Preferably, the upper surface of the material distributing plate is provided with a cover plate, and the cover plate can cover the feeding section and the material guiding section to prevent the material from separating from the feeding chute and the material guiding chute; the feeding end of the guide chute becomes gradually larger towards the feeding opening, so that the materials can enter the guide chute conveniently.

Preferably, the feeding groove of the material distributing plate is connected with a conveying belt, and the conveying belt comprises a horizontal section and an inclined section. In the feed chute was sent into by the conveyer belt to the material, the material of the conveyer belt more suitable charging tray of horizontal segment was sent into, and the conveyer belt of slope section then links up with the better branch flitch that the slope set up.

Drawings

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

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

Fig. 3 is a schematic structural diagram 3 of the present invention.

Fig. 4 is a top view of the present invention.

Fig. 5 is a schematic view of the feeding mechanism of the present invention.

Detailed Description

The following describes details and operational principles of embodiments and examples of the present invention with reference to the drawings. The battery distributing device comprises a distributing plate 1 and a distributing die 6, wherein the distributing plate is arranged in a downward inclined manner, batteries automatically slide downwards by utilizing gravity, the distributing plate is sequentially divided into a feeding section, a guiding section and a distributing section, the feeding section is provided with a feeding chute 2, the guiding section is provided with a guiding chute 3 and a sliding chute 4, the guiding chutes and the sliding chutes are alternately arranged, the guiding chutes 3 and the sliding chutes 4 are not communicated, the guiding chute 3 is communicated with the feeding chute 2, the width of the guiding chute is matched with the outer diameter of the materials, in order to enable the materials in the feeding chute to be uniformly distributed in each guiding chute 3, the feeding section is provided with a material homogenizing piece, the material homogenizing piece comprises a moving block 13 moving on the feeding section 2, the moving block is provided with a plurality of moving blocks and is arranged on a moving plate 14 which transversely reciprocates, the moving blocks are driven to transversely move in the feeding chute, then, the materials in the feeding chute are pushed to be uniformly distributed, and each guide chute 3 is provided with the materials; the material distributing plate 10 is provided with a linear guide rail which is transversely arranged, the moving plate 14 is arranged on the linear guide rail in a sliding manner, the moving plate is connected with a power part, the power part can adopt an air cylinder, and the power part drives the moving plate to transversely move on the linear guide rail; meanwhile, in order to enable the materials to smoothly enter the guide chute, the feeding end of the guide chute is gradually enlarged towards the feeding port, namely the feeding port 23 of the guide chute is horn-shaped, and the feeding port is large and beneficial to the materials to enter the guide chute. The chute 4 extends to the distributing section, the distributing section is also provided with a material groove 5, the material groove is communicated with the chute, the width of the material groove is narrower than that of the guide chute, and the inlet of the material groove 5 is communicated with the outlet of the guide chute 3; the material distribution die 6 is arranged in the sliding groove in a sliding mode, the width of the material distribution die is matched with the sliding groove, a plurality of positioning grooves 7 are formed in the end, adjacent to the material groove 5, of the material distribution die 6, five positioning grooves are formed in the material distribution die in the drawing, the positioning grooves are uniformly arranged along the length direction of the material distribution die, the sum of the widths of the positioning grooves 7 and the material groove 5 is matched with the outer diameter of the material, the material 17 cannot shake left and right in the positioning grooves, the position is accurate, and the material taking by the feeder 19 is facilitated; when the outlet of the guide chute is staggered with the positioning groove 7, the material 17 cannot enter the feed chute due to the narrow width of the feed chute, and only when the positioning groove 7 of the material distribution die is positioned at the outlet of the guide chute 3, the material can enter the positioning groove and the feed chute from the guide chute; therefore, when distributing materials, the material distributing die 6 moves to the feeding section firstly, then the material distributing die moves downwards, the positioning groove at the lowest end of the material distributing die moves to the outlet of the guide chute firstly, materials 17 automatically enter the positioning groove 7, the batteries in the guide chute sequentially enter the positioning groove of the material distributing die along with downward movement of the material distributing die, and when the material distributing die moves to the bottom of the sliding chute, the five troughs of the material distributing die are filled with the batteries, so that the feeder 19 can take five rows of batteries once, the feeding speed is greatly improved, the troughs of the material distributing die can set intervals and quantity according to requirements, and one-time feeding completion is met.

The positioning groove 7 is arc-shaped and is matched with the side surface of the material, so that the battery cannot shake in the positioning groove, the position is accurate, and the charging is facilitated; the inner wall of the joint 18 of the material guide chute 3 and the material groove 5 is arc-shaped, so that the batteries can conveniently enter the material groove and the positioning groove from the material guide chute. In order to increase the downward moving speed of the material, a material blowing part 9 is arranged above the material guiding section, a gas blowing hole is formed in the material blowing part, the airflow of the gas blowing hole faces the moving direction of the material, and the downward sliding speed of the material is accelerated by the wind power of the airflow. Because the upper material has pressure on the lower material, in order to avoid the blockage of the material at the discharge hole of the guide chute, a limiting part is arranged at the outlet of the guide chute; the limiting part is a material blocking block, the material blocking block is connected with a driving assembly II for driving the material blocking block to enter and exit from the guide chute, the material blocking block blocks the next material in the guide chute from the material entering the positioning groove, so that only one material at the outlet can enter the material chute, the material is not stressed, even if a corner is arranged at the joint of the guide chute and the material chute, the material can smoothly slide down to enter the material chute and the positioning groove, and the blockage caused by crowding of the material at the corner is avoided; in addition, when the material distributing die moves towards the material guiding section, the material can be blocked by the material blocking block; the driving assembly II comprises a lifting plate 8, the material blocking block is installed on the lifting plate, the lifting plate vertically moves relative to the material distributing plate, the material blocking block enters and exits the material guide groove from the front face of the material distributing plate, and the lifting plate can be driven by an air cylinder.

The material distribution die 6 is connected with a driving assembly I for driving the material distribution die to move in a sliding chute; drive assembly one including slide 15, guide rail 16 and power spare, in order to give drive assembly two and stepping down, the lower surface at minute flitch 1 is installed to the guide rail, slide 15 slides and sets up on the guide rail, and the slide is connected with power spare, and power spare also can adopt the cylinder, divide material mould 6 to pass spout 4 and be connected with slide 15, power spare drive slide moves on linear guide, and the slide then drives and divides material mould to remove in the spout. The upper surface of branch flitch is equipped with apron 11, and the apron can cover feeding section and guide section, avoids the material to break away from feed chute and baffle box, set up the breach 12 that supplies the refining piece to remove and blow the gas pocket that the material piece was blown and is used on the apron.

The feed chute that divides the flitch links up with conveyer belt 20, the conveyer belt is including horizontal segment 21 and slope section 22, see figure 5, and the conveyer belt of horizontal segment more is fit for the material in the charging tray and sends into, and the conveyer belt of slope section then links up with the branch flitch that the slope set up is better, and the material in the charging tray gets into the conveyer belt of horizontal segment on, and the conveyer belt carries the material forward, and the material is sent into the feed chute through the slope section.

Claims (10)

1. The utility model provides a battery feed divider which characterized in that: comprises that

The material distribution plate is arranged in a downward inclined mode, the material distribution plate is sequentially divided into a feeding section, a guide section and a material distribution section, the feeding section is provided with a feeding chute, the guide section is provided with a guide chute and a sliding chute, the guide chute and the sliding chute are alternately arranged, the guide chute is communicated with the feeding chute, the width of the guide chute is matched with the outer diameter of a material, the sliding chute extends to the material distribution section, the material distribution section is also provided with a material chute, the material chute is communicated with the sliding chute, the width of the material chute is narrower than that of the guide chute, and the inlet of the material chute is communicated with the outlet of the guide chute;

and the material distribution die is arranged in the sliding groove in a sliding manner, a plurality of positioning grooves are formed in the end, adjacent to the trough, of the material distribution die, the positioning grooves are uniformly arranged along the length direction of the material distribution die, and the width sum of the positioning grooves and the trough is matched with the outer diameter of the material.

2. The battery feed divider of claim 1, wherein: the positioning groove is arc-shaped and matched with the side surface of the material; the inner wall of the joint of the guide chute and the material groove is arc-shaped.

3. The battery feed divider of claim 1, wherein: the material distribution die is connected with a driving assembly I for driving the material distribution die to move in the sliding groove; the first driving assembly comprises a sliding seat, a guide rail and a power part, the guide rail is installed on the lower surface of the material distribution plate, the sliding seat is arranged on the guide rail in a sliding mode and connected with the power part, and the material distribution die penetrates through the sliding groove and is connected with the sliding seat.

4. The battery feed divider of claim 1, wherein: and a blowing part is arranged above the material guide section, a blowing hole is formed in the blowing part, and the air flow of the blowing hole faces the moving direction of the material.

5. The battery feed divider of claim 1, wherein: a limiting piece is arranged at an outlet of the guide chute; the limiting part is a material blocking block, and the material blocking block is connected with a driving assembly II for driving the material blocking block to enter and exit the material guide groove.

6. The battery feed divider of claim 5, wherein: the driving assembly II comprises a lifting plate, and the material blocking block is arranged on the lifting plate.

7. The battery feed divider of claim 1, wherein: the feeding section is provided with a material homogenizing piece, and the material homogenizing piece comprises a moving block moving in the feeding section.

8. The battery feed divider of claim 7, wherein: the moving blocks are provided with a plurality of moving blocks and are arranged on the moving plate which moves transversely in a reciprocating manner; the material distribution plate is provided with a linear guide rail which is transversely arranged, the movable plate is arranged on the linear guide rail in a sliding mode, and the movable plate is connected with the power part.

9. The battery feed divider of claim 1, wherein: the upper surface of the material distributing plate is provided with a cover plate; and the feeding end of the guide chute is gradually enlarged towards the feeding port.

10. The battery feed divider of any of claims 1-9, wherein: the feeding groove of the material distributing plate is connected with the conveying belt, and the conveying belt comprises a horizontal section and an inclined section.

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