CN215047435U - Continuous sheet collecting device for storage battery grid - Google Patents

Abstract

The utility model discloses a piece device is received to battery grid continuous type relates to battery production technical field. The utility model comprises a side supporting beam; a first power conveyer belt and a second power conveyer belt are arranged between the two side supporting beams in parallel; a support beam is arranged between the two side support beams; the lower surface of the supporting beam is fixed with a baffle; a first driving assembly and a second driving assembly are arranged between the two side supporting beams; the output end of the first driving component is provided with a first transmission strip; a bearing strip is fixed on one side surface of the first transmission strip; the output end of the second driving component is provided with a second transmission bar; a support rod is fixed on the upper surface of the second transmission bar; the upper end of the supporting rod is horizontally fixed with a bearing sheet; the bearing sheet corresponds to the bearing strip in position. The utility model discloses a carrier strip carries out first stack to the grid to utilize the carrier sheet to accomplish on the second power conveyer belt after the last stack of grid, thereby can realize the continuous type stack to battery grid, have higher market using value.

Description

Continuous sheet collecting device for storage battery grid

Technical Field

The utility model belongs to the technical field of the battery production, especially, relate to a piece device is received to battery grid continuous type.

Background

The storage battery grid is manufactured by a die and then needs to be subjected to treatment of removing residual paste and the like, the steps are carried out on a conveyer belt, after all the steps are finished, the storage battery grid needs to be collected, and the storage battery grid is often collected together by manpower in production and placed into turnover equipment. The manual sheet collecting mode in the existing production is laggard, only a certain amount of grids can be collected, and the sheet collecting amount cannot be adjusted according to the production amount; and because the grid is made of lead, the grid is easy to damage in the existing sheet collecting mode. Therefore, a continuous sheet collecting device for a battery grid is needed to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a piece device is received to battery grid continuous type, its purpose is in order to solve the problem that proposes among the above-mentioned background art.

In order to solve the technical problem, the utility model discloses a realize through following technical scheme:

the utility model relates to a continuous sheet collecting device for a storage battery grid, which comprises a pair of side supporting beams arranged side by side; a first power conveying belt and a second power conveying belt are arranged between the two side supporting beams in parallel; the first power conveyer belt is used for conveying single-sheet grids; the second power conveyer belt is used for conveying the stacked grids; a supporting beam is erected between the two side supporting beams; the support beam is arranged at the discharge end of the first power conveying belt; a plurality of baffles corresponding to the material conveying stations on the first power conveyor belt are vertically fixed on the lower surface of the supporting beam side by side; a first driving assembly is arranged between the two side supporting beams; the output end of the first driving component is provided with a first transmission strip, and the first driving component can drive the first transmission strip to move according to an □ -shaped track; the first transmission strip is arranged in parallel with the support beam and is arranged on one side of the support beam far away from the first power conveying belt; a plurality of pairs of bearing strips for carrying grids are vertically fixed on one side of the first transmission strip close to the support beam side by side; one end of the bearing strip can be moved between the first power conveying belt and the baffle; a second driving assembly is also arranged between the two side supporting beams; the output end of the second driving assembly is provided with a second transmission strip, and the second driving assembly can drive the second transmission strip to move up and down; the second transmission strip is arranged in parallel with the first transmission strip; the second transmission strip is arranged below the second power conveying belt; a plurality of support rods are vertically fixed on the upper surface of the second transmission strip side by side; a bearing sheet for carrying a grid is horizontally fixed at the upper end of the supporting rod; the bearing sheet corresponds to the bearing strip in position.

Further, the first driving assembly comprises a first power telescopic rod fixed on the upper part of the support beam; the telescopic direction of the first power telescopic rod is perpendicular to the length direction of the supporting beam; a transmission frame is fixed at the output end of the first power telescopic rod; a pair of second power telescopic rods is vertically fixed on the transmission frame; the output end of the second power telescopic rod is connected with the upper surface of the first transmission strip.

Furthermore, the second driving assembly comprises a pair of third power telescopic rods which are respectively vertically arranged on two opposite sides of the first power conveying belt; and the output end of the third power telescopic rod is connected with the upper surface of the second transmission strip.

Furthermore, the third power telescopic rod is fixed in a mounting sleeve; the mounting sleeve is fixed on the output end of a horizontally arranged fourth power telescopic rod; and the fourth power telescopic rod is fixed on the inner side surface of the side supporting beam.

The utility model discloses following beneficial effect has:

the utility model discloses a first power conveyer belt carries a plurality of grids in proper order, the carrier strip carries on slow downstream behind the partial grid, after the upper surface of carrier strip flushes with the upper surface of carrier piece mutually, first drive assembly drives the carrier strip motion, make the one end of carrier strip move to a supporting beam and keep away from one side of first power conveyer belt and make it reset, then second drive assembly drives the carrier piece downstream, and make the upper surface of carrier piece flush with the working face of second hold-in range mutually, thereby accomplish the windrow and defeated material action, not only structural design is reasonable, and convenient to use, and the receipts piece efficiency of grid has been improved effectively, higher market using value has.

Of course, it is not necessary for any particular product to achieve all of the above-described advantages at the same time.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of a continuous sheet collecting device for a storage battery grid of the present invention;

fig. 2 is a position relationship diagram of the first power transmission belt, the first driving assembly and the second driving assembly of the present invention;

fig. 3 is a position relationship diagram of the second power transmission belt, the first driving assembly and the second driving assembly of the present invention;

fig. 4 is a position relationship diagram between the first driving assembly and the second driving assembly of the present invention;

fig. 5 is a front view of the structure of fig. 4.

In the drawings, the components represented by the respective reference numerals are listed below:

1-side supporting beam, 2-first power conveying belt, 3-second power conveying belt, 4-supporting beam, 5-baffle, 6-first driving component, 7-first driving strip, 8-bearing strip, 9-second driving component, 10-second driving strip, 11-supporting rod, 12-bearing piece, 601-first power telescopic rod, 602-driving frame, 603-second power telescopic rod, 901-third power telescopic rod, 902-mounting sleeve, 903-fourth power telescopic rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-3, the utility model relates to a continuous sheet collecting device for accumulator grids, which comprises a pair of side supporting beams 1 arranged side by side; a first power conveyer belt 2 and a second power conveyer belt 3 are arranged between the two side supporting beams 1 side by side; the first power conveyer belt 2 is used for conveying single-sheet grids; the first power conveying belt 2 comprises a first driving wheel and a first driven wheel which are arranged side by side; the first driving wheel and the first driven wheel are both rotationally connected with the side supporting beam 1; one end of a wheel shaft of the first driving wheel is connected to an output shaft of a first driving motor; the first driving motor is fixed on the supporting beam 1 on one side; the first driving wheel is in transmission connection with the first driven wheel through a plurality of groups of first synchronous belts; each group of the first synchronous belts is provided with three first synchronous belts which form a material conveying station; the second power conveyer belt 3 is used for conveying the stacked grids; the second power conveyer belt 3 comprises a second driving wheel and a second driven wheel which are arranged side by side; the first driving wheel and the second driven wheel are both rotationally connected with the side supporting beam 1; one end of a wheel shaft of the first driving wheel is connected to an output shaft of a second driving motor; the second driving motor is fixed on the supporting beam 1 at one side; the first driving wheel and the second driven wheel are in transmission connection through a plurality of groups of second synchronous belts; each group of the second synchronous belts is provided with two second synchronous belts which form a material conveying station; the material conveying station of the first power conveyer belt 2 corresponds to the material conveying station of the second power conveyer belt 3 in position;

a supporting beam 4 is arranged on the fixed frame between the supporting beams 1 at the two sides; the support beam 4 is arranged at the discharge end of the first power conveying belt 2; a plurality of baffles 5 corresponding to the material conveying stations on the first power conveyer belt 2 are vertically fixed on the lower surface of the supporting beam 4 side by side; a first driving assembly 6 and a second driving assembly 9 are arranged between the two side supporting beams 1; the output end of the first driving component 6 is provided with a first transmission strip 7, and the first driving component 6 can drive the first transmission strip 7 to move according to the □ -shaped track; the first transmission strip 7 is arranged in parallel with the support beam 4, and the first transmission strip 7 is arranged on one side of the support beam 4 far away from the first power conveying belt 2; a plurality of pairs of bearing strips 8 for carrying grids are vertically fixed on one side of the first transmission strip 7 close to the support beam 4 side by side; one end of the carrying strip 8 can move between the first power conveying belt 2 and the baffle 5; the baffles 5 correspond to the bearing strips 8 one by one, and the baffles 5 are arranged between the two bearing strips 8; the output end of the second driving component 9 is provided with a second transmission strip 10, and the second driving component 9 can drive the second transmission strip 10 to move up and down; the second transmission strip 10 is arranged in parallel with the first transmission strip 7; the second transmission strip 10 is arranged below the second power transmission belt 3; a plurality of support rods 11 are vertically fixed on the upper surface of the second transmission bar 10 side by side; each support rod 11 is arranged between two adjacent material conveying stations of the second power conveying belt 3; a bearing sheet 12 for carrying a grid is horizontally fixed at the upper end of the support rod 11; the carrier sheet 12 corresponds in position to the carrier strip 8.

As shown in fig. 4-5, the first driving assembly 6 comprises a first power expansion rod 601 fixed on the upper part of the support beam 4; the first power telescopic rod 601 adopts a conventional hydraulic cylinder or an electric push rod in the field; the extension direction of the first power telescopic rod 601 is perpendicular to the length direction of the support beam 4; a transmission frame 602 in an i-shaped structure is fixed at the output end of the first power expansion link 601; a pair of second power telescopic rods 603 is vertically fixed on the transmission frame 602; the second power telescopic rod 603 adopts a conventional hydraulic cylinder or an electric push rod in the field; the output end of the second power telescopic rod 603 is connected with the upper surface of the first transmission bar 7.

As shown in fig. 4-5, the second driving assembly 9 includes a pair of third power extension rods 901 vertically disposed on two opposite sides of the first power transmission belt 2; the third power telescopic rod 901 adopts a conventional hydraulic cylinder or an electric push rod in the field; the output end of the third power telescopic rod 901 is connected with the upper surface of the second transmission bar 10; the third power telescopic rod 901 is fixed in a mounting sleeve 902; the mounting sleeve 902 is fixed on the output end of a horizontally arranged fourth power telescopic rod 903; the fourth power telescopic rod 903 adopts a conventional hydraulic cylinder or an electric push rod in the field; the fourth power telescopic rod 903 is fixed on the inner side surface of the side supporting beam 1.

Before use, the carrier sheet 12 is located at the lower edge of the apron 5, one end of the carrier strip 8 is moved between the first power transmission belt 2 and the support beam 4, and the upper surface of the carrier strip 8 is located slightly lower than the upper section of the first timing belt. When the grid conveying device is used, the first power conveying belt 2 conveys a plurality of grids in sequence, and after the first grid is separated from the first power conveying belt 2 and falls onto the bearing strip 8, the bearing strip 8 slowly moves downwards; when the upper surface of the carrying strip 8 is flush with the upper surface of the carrying sheet 12, the first driving assembly 6 drives the carrying strip 8 to move, so that one end of the carrying strip 8 moves to one side of the supporting beam 4 far away from the first power conveying belt 2 and resets the supporting beam; after carrying strip 8 resets, accomplish the stack of a set of grid on the carrier plate 12, then second drive assembly 9 drives carrier plate 12 downstream, and make the upper surface of carrier plate 12 flush with the working face of second hold-in range mutually, at this moment, fourth power telescopic link 903 drives carrier plate 12 and arranges the material direction motion to second power conveyer belt 2, can help the grid after the stack to stably fall on second power conveyer belt 2, avoid leading to the grid after the stack to scatter because second power conveyer belt 2 gives a direction of motion of grid.

The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims (4)

1. A continuous sheet collecting device for a storage battery grid comprises a pair of side supporting beams (1) which are arranged side by side; a first power conveyer belt (2) and a second power conveyer belt (3) are arranged between the two side supporting beams (1) side by side; the first power conveying belt (2) is used for conveying a single plate grid; the second power conveyer belt (3) is used for conveying the stacked grids; the method is characterized in that:

a supporting beam (4) is erected between the two side supporting beams (1); the supporting beam (4) is arranged at the discharge end of the first power conveying belt (2); a plurality of baffles (5) corresponding to the material conveying stations on the first power conveyer belt (2) are vertically fixed on the lower surface of the supporting beam (4) side by side;

a first driving assembly (6) is arranged between the two side supporting beams (1); the output end of the first driving component (6) is provided with a first transmission strip (7), and the first driving component (6) can drive the first transmission strip (7) to move according to an □ -shaped track; the first transmission strip (7) is arranged in parallel with the supporting beam (4), and the first transmission strip (7) is arranged on one side, far away from the first power conveying belt (2), of the supporting beam (4); a plurality of pairs of carrying strips (8) for carrying grids are vertically fixed on one side surface of the first transmission strip (7) close to the supporting beam (4) side by side; one end of the carrying strip (8) can be moved between the first power conveying belt (2) and the baffle (5);

a second driving assembly (9) is also arranged between the two side supporting beams (1); the output end of the second driving component (9) is provided with a second transmission strip (10), and the second driving component (9) can drive the second transmission strip (10) to move up and down; the second transmission strip (10) and the first transmission strip (7) are arranged in parallel; the second transmission strip (10) is arranged below the second power conveying belt (3); a plurality of support rods (11) are vertically fixed on the upper surface of the second transmission bar (10) side by side; a bearing sheet (12) for carrying a grid is horizontally fixed at the upper end of the supporting rod (11); the bearing sheet (12) corresponds to the bearing strip (8) in position.

2. The continuous accumulator grid take-up device according to claim 1, wherein the first driving assembly (6) comprises a first power telescopic rod (601) fixed on the upper part of the support beam (4); the telescopic direction of the first power telescopic rod (601) is perpendicular to the length direction of the supporting beam (4); a transmission frame (602) is fixed at the output end of the first power telescopic rod (601); a pair of second power telescopic rods (603) is vertically fixed on the transmission frame (602); the output end of the second power telescopic rod (603) is connected with the upper surface of the first transmission strip (7).

3. The continuous accumulator grid take-up device according to claim 1 or 2, wherein the second driving assembly (9) comprises a pair of third power telescopic rods (901) vertically arranged on two opposite sides of the first power conveying belt (2); the output end of the third power telescopic rod (901) is connected with the upper surface of the second transmission bar (10).

4. The continuous accumulator grid take-up device according to claim 3, wherein the third power expansion link (901) is fixed in a mounting sleeve (902); the mounting sleeve (902) is fixed on the output end of a fourth power telescopic rod (903) which is horizontally arranged; and the fourth power telescopic rod (903) is fixed on the inner side surface of the side supporting beam (1).

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