CN210838006U - Groove feeding machine for lead-acid storage battery - Google Patents

Abstract

The utility model discloses a lead acid battery groove cutting machine, its structure is including the moulded shell feed mechanism, transfer chain mechanism and the unpowered cylinder line mechanism that set gradually, and transfer chain mechanism is close to moulded shell feed mechanism one end lower part and establishes two sets of lower part jacking positioning mechanism, two sets of fixture mechanism are established at the middle part, one set of upper portion pressing mechanism is established on upper portion, and transfer chain mechanism is close to unpowered cylinder line mechanism one end lower part and establishes lower part jacking alignment mechanism, and the station switches the cylinder and connects drive upper portion pressing mechanism and slide along the guide rail level. The utility model has the advantages that: structural design is reasonable, and electric combination adopts cylinder and motor drive, easily realizes a series of actions such as the automatic feeding of moulding the shell, arranging of utmost point crowd and the transport of entering groove and battery, and easy operation has reduced intensity of labour, has improved production efficiency greatly.

Description

Groove feeding machine for lead-acid storage battery

Technical Field

The utility model relates to a lead-acid storage battery groove entering machine.

Background

In the production process of the lead-acid storage battery in the prior art, the pole group needs to be manually placed into the clamp and then moved into and out of the cast-weld machine, the pole group needs to be repeatedly moved thousands of times every day, and the clamp has heavy weight, so that the labor intensity is high and the production efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model provides a lead acid battery goes into scouring machine, its purpose aims at overcoming the above-mentioned not enough that prior art exists, only needs the manual work to put into the battery that the groove is good on the transfer board that weight is light, moves into/out cast-weld machine, and intensity of labour when realizing reducing the operation improves production efficiency.

The technical solution of the utility model is as follows: a lead-acid storage battery groove entering machine structurally comprises a plastic shell feeding mechanism, a conveying line mechanism and an unpowered roller line mechanism which are sequentially arranged, wherein the lower portion of one end, close to the plastic shell feeding mechanism, of the conveying line mechanism is provided with two sets of lower jacking positioning mechanisms, the middle portion of the conveying line mechanism is provided with two sets of clamp mechanisms, the upper portion of the conveying line mechanism is provided with one set of upper pressing mechanism, the lower portion of one end, close to the unpowered roller line mechanism, of the conveying line mechanism is provided with a lower jacking calibration mechanism, and a station switching cylinder.

Preferably, the plastic shell feeding mechanism comprises a first motor, a first lifting cylinder and a positioning cylinder, wherein the movable end of the positioning cylinder is connected with a profile plate through a transmission mechanism, the movable end of the first lifting cylinder is connected with a plastic shell, the plastic shell is positioned above a first conveying chain, the profile plate is positioned below the first conveying chain, the first motor is in transmission connection with the first conveying chain, a control box is further arranged below the first conveying chain, and the first conveying chain is used for conveying the plastic shell.

Preferably, the conveyor line mechanism comprises a second motor and a second conveyor chain, wherein the second motor is in transmission connection with the second conveyor chain, and the second conveyor chain conveys the plastic shell.

Preferably, lower part jacking positioning mechanism include bottom door board cylinder, first spacing cylinder, the spacing cylinder of second, first die clamping cylinder, second lift cylinder, third lift cylinder, wherein bottom door board cylinder connects the opening and shutting of transmission bottom door board, first die clamping cylinder is established to the door plant below, first spacing cylinder and the spacing cylinder of second are established to first die clamping cylinder both sides, the bottom plate is connected to second lift cylinder expansion end, second lift cylinder stiff end is connected to third lift cylinder stiff end, first spacing cylinder is connected to the expansion end, the mounting panel at the spacing cylinder of second and first die clamping cylinder place, the guide arm is established to both sides between mounting panel and the bottom plate.

Preferably, the fixture mechanism comprises a side cylinder and an end face cylinder, wherein the movable ends of the side cylinder and the end face cylinder are respectively connected with the inner fixture plate at the center in a transmission manner, a polar group is placed between the inner fixture plates, and a square steel limiting plate is further arranged in the middle of the inner fixture plate.

Preferably, upper portion establish upper portion pressing mechanism and include whole ear positioning cylinder, go into groove cylinder, liftout cylinder and whole ear cylinder, wherein whole ear positioning cylinder stiff end is connected and is gone into groove cylinder stiff end, expansion end connection roof, the roof passes through the mounting bracket that the guide arm was connected into the liftout cylinder, goes into the groove cylinder expansion end and connects the expansion end of liftout cylinder, first thimble is connected to liftout cylinder stiff end, whole ear cylinder is established to first thimble tip, whole ear strip is connected to whole ear cylinder expansion end.

Preferably, the lower jacking calibration mechanism comprises a third limiting cylinder, a second clamping cylinder and a fourth lifting cylinder, wherein the fixed end of the fourth lifting cylinder is connected with the base plate, the movable end of the fourth lifting cylinder is connected with the mounting frame of the third limiting cylinder and the second clamping cylinder, the mounting frame is connected with guide rods on two sides of the base plate, the third limiting cylinder and the second clamping cylinder are arranged adjacently, and a second thimble is arranged above the third limiting cylinder and the second clamping cylinder.

Preferably, the unpowered roller line mechanism comprises a material pushing cylinder and a roller line, wherein the end of the roller line is provided with an inductor, and the side surface of the end of the roller line is provided with the material pushing cylinder.

The utility model has the advantages that: structural design is reasonable, and electric combination adopts cylinder and motor drive, easily realizes a series of actions such as the automatic feeding of moulding the shell, arranging of utmost point crowd and the transport of entering groove and battery, and easy operation has reduced intensity of labour, has improved production efficiency greatly.

Drawings

Fig. 1-1 is a schematic structural diagram of the lead-acid storage battery groove-entering machine of the present invention.

Fig. 1-2 is a side view of fig. 1-1.

Fig. 2-1 is a schematic structural view of the plastic case feeding mechanism in fig. 1-1.

Fig. 2-2 is a side view of fig. 2-1.

Fig. 3-1 is a schematic structural view of the conveyor line mechanism in fig. 1-1.

Fig. 3-2 is a side view of fig. 3-1.

Fig. 4-1 is a schematic structural view of the lower jacking-positioning mechanism in fig. 1-1.

Fig. 4-2 is a side view of fig. 4-1.

Fig. 5-1 is a schematic view of the structure of the clamping mechanism of fig. 1-1.

Fig. 5-2 is a side view of fig. 5-1.

Fig. 6-1 is a schematic structural view of the upper press mechanism in fig. 1-1.

Fig. 6-2 is a side view of fig. 6-1.

FIG. 7-1 is a schematic structural view of the lower jacking alignment mechanism of FIG. 1-1.

Fig. 7-2 is a side view of fig. 7-1.

Fig. 8-1 is a schematic structural view of the unpowered roller line mechanism of fig. 1.

Fig. 8-2 is a side view of fig. 8-1.

In the figure, A is a plastic shell feeding mechanism, B is a conveying line mechanism, C is a lower jacking positioning mechanism, D is a clamp mechanism, E is an upper pressing mechanism, F is a lower jacking calibration mechanism, G is an unpowered roller line mechanism, and H is a station switching cylinder; the device comprises a plastic shell 1, a first motor 2, a first conveying chain 3, a control box 4, a first lifting cylinder 5, a positioning cylinder 6, a profile plate 7, a second motor 8, a second conveying chain 9, a bottom door plate cylinder 10, a bottom door plate 11, a first limiting cylinder 12, a second limiting cylinder 13, a first clamping cylinder 14, a second lifting cylinder 15, a third lifting cylinder 16, a side cylinder 17, an end cylinder 18, a limiting plate 19, a pole group 20, a clamp inner plate 21, a whole lug positioning cylinder 22, a groove-in cylinder 23, a material-ejecting cylinder 24, a whole lug cylinder 25, a first ejector pin 26, a whole lug strip 27, a third limiting cylinder 28, a second clamping cylinder 29, a fourth lifting cylinder 30, a second ejector pin 31, a material-pushing cylinder 32, a material-pushing roller line 33 and a sensor 34.

Detailed Description

The present invention will be described in further detail with reference to examples and embodiments.

As shown in fig. 1-1 and 1-2, the lead-acid storage battery slot-entering machine structurally comprises a plastic shell feeding mechanism a, a conveying line mechanism B and a powerless roller line mechanism G which are sequentially arranged, wherein the lower part of one end, close to the plastic shell feeding mechanism a, of the conveying line mechanism B is provided with two sets of lower jacking positioning mechanisms C, the middle part of the conveying line mechanism B is provided with two sets of clamp mechanisms D, the upper part of the conveying line mechanism B is provided with one set of upper pressing mechanism E, the lower part of one end, close to the powerless roller line mechanism G, of the conveying line mechanism B is provided with a lower jacking calibration mechanism F.

As shown in fig. 2-1 and 2-2, the plastic casing feeding mechanism a includes a first motor 2, a first lifting cylinder 5 and a positioning cylinder 6, wherein a movable end of the positioning cylinder 6 is connected to a profile plate 7 through a transmission mechanism, a movable end of the first lifting cylinder 5 is connected to the plastic casing 1, the plastic casing 1 is located above the first conveying chain 3, the profile plate 7 is located below the first conveying chain 3, the first motor 2 is connected to the first conveying chain 3 in a transmission manner, a control box 4 is further disposed below the first conveying chain 3, and the first conveying chain 3 conveys the plastic casing 1.

During operation, location cylinder 6 stretches out, and section bar board 7 rises, and the withdrawal of first lift cylinder 5 is moulded the shell 1 and is descended to section bar board 7 face on, and first lift cylinder 5 stretches out, withstands the shell that moulds on the second floor, and the withdrawal of location cylinder 6, section bar board 7 descend, and mould shell 1 and drop to first conveying chain 3 on, first motor 2 drives first conveying chain 3 and will mould shell 1 forward transmission.

As shown in fig. 3-1 and 3-2, the conveyor line mechanism B includes a second motor 8 and a second conveyor chain 9, wherein the second motor 8 is drivingly connected to the second conveyor chain 9, and the second conveyor chain 9 conveys the plastic cases 1.

During operation, the second motor 8 is always in a driving state, and drives the second conveying chain 9 to convey the plastic shell 1 forwards.

As shown in fig. 4-1 and 4-2, the lower jacking positioning mechanism C includes a bottom door plate cylinder 10, a first limiting cylinder 12, a second limiting cylinder 13, a first clamping cylinder 14, a second lifting cylinder 15, and a third lifting cylinder 16, wherein the bottom door plate cylinder 10 is connected to a transmission bottom door plate 11 for opening and closing, the first clamping cylinder 14 is disposed below the door plate 11, the first limiting cylinder 12 and the second limiting cylinder 13 are disposed on two sides of the first clamping cylinder 14, the movable end of the second lifting cylinder 15 is connected to a bottom plate, the fixed end of the third lifting cylinder 16 is connected to the fixed end of the second lifting cylinder 15, the movable end of the third lifting cylinder is connected to a mounting plate where the first limiting cylinder 12, the second limiting cylinder 13, and the first clamping cylinder 14 are located, and guide rods are disposed on two sides between the mounting plate and the bottom plate.

When the plastic shell clamping device works, the bottom door plate cylinder 10 retracts, the bottom door plate 11 is opened, the first limiting cylinder 12 and the second limiting cylinder 13 extend, the second lifting cylinder 15 retracts, the first clamping cylinder 14 extends, the plastic shell 1 is clamped, the first limiting cylinder 12 retracts, the second limiting cylinder 13 retracts, and the third lifting cylinder 16 extends; after the pole group 20 enters the plastic shell 1, the third lifting cylinder 16 retracts, the first clamping cylinder 14 retracts, the second lifting cylinder 15 retracts, and the battery descends onto the second conveying chain 9 to continue to be conveyed forwards.

As shown in fig. 5-1 and 5-2, the fixture mechanism D includes a side cylinder 17 and an end cylinder 18, wherein the movable ends of the side cylinder 17 and the end cylinder 18 are respectively connected to a central fixture inner plate 21 in a transmission manner, a pole group 20 is disposed between the fixture inner plates 21, and a square steel limiting plate 19 is further disposed in the middle of the fixture inner plate 21.

When the clamp works, the pole group 20 is manually placed, the side cylinder 17 and the end face cylinder 18 extend out, the clamp inner plate 21 is tightened, and the limiting plate 19 is made of square steel so that the clamp inner plate 21 can be prevented from deforming.

As shown in fig. 6-1 and 6-2, the upper pressing mechanism E includes a lug positioning cylinder 22, a slot-entering cylinder 23, an ejecting cylinder 24 and a lug-adjusting cylinder 25, wherein the fixed end of the lug positioning cylinder 22 is connected to the fixed end of the slot-entering cylinder 23, the movable end of the slot-entering cylinder 23 is connected to the top plate, the top plate is connected to the mounting frame of the ejecting cylinder 24 through a guide rod, the movable end of the slot-entering cylinder 23 is connected to the movable end of the ejecting cylinder 24, the fixed end of the ejecting cylinder 24 is connected to a first ejector pin 26, the lug-adjusting cylinder 25 is arranged at the end of the first ejector pin 26, and the movable end of the lug-adjusting cylinder.

When the automatic lug arranging and feeding device works, the lug arranging positioning cylinder 22 retracts, the lug arranging cylinder 25 repeatedly extends and retracts for 3 times, the lug is arranged in alignment by the lug arranging strips 27, the groove entering cylinder 23 extends out, the pole group 20 is pressed into the plastic shell 1 by the first ejector pin 26, and the ejection cylinder 24 extends out.

As shown in fig. 7-1 and 7-2, the lower jacking calibration mechanism F includes a third limiting cylinder 28, a second clamping cylinder 29 and a fourth lifting cylinder 30, wherein a fixed end of the fourth lifting cylinder 30 is connected to the bottom plate, a movable end of the fourth lifting cylinder is connected to a mounting rack of the third limiting cylinder 28 and the second clamping cylinder 29, the mounting rack is connected to guide rods on two sides of the bottom plate, the third limiting cylinder 28 and the second clamping cylinder 29 are adjacently disposed, and a second thimble 31 is disposed above the third limiting cylinder 28 and the second clamping cylinder 29.

During operation, the third limiting cylinder 28 extends, the second clamping cylinder 29 extends, the fourth lifting cylinder 30 extends, the second ejector pin 31 presses the pole group 20 again (calibration position), the third limiting cylinder 28 retracts, the second clamping cylinder 29 retracts, and the fourth lifting cylinder 30 retracts.

As shown in fig. 8-1 and 8-2, the unpowered roller line mechanism G includes a pushing cylinder 32 and a roller line 33, wherein an inductor 34 is disposed at an end of the roller line 33, and the pushing cylinder 32 is disposed at a side surface of the end of the roller line 33.

The battery is conveyed along the roller line 33, the sensor 34 senses the battery, the pushing cylinder 32 extends out, and the battery is pushed into the next subsequent conveying line.

All the above components are prior art, and those skilled in the art can use any model and existing design that can implement their corresponding functions.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many modifications and improvements can be made without departing from the inventive concept, and all of them belong to the protection scope of the present invention.

Claims (8)

1. A lead-acid storage battery grooving machine is characterized by comprising a plastic shell feeding mechanism (A), a conveying line mechanism (B) and an unpowered roller line mechanism (G) which are sequentially arranged, wherein the conveying line mechanism (B) is provided with two sets of lower jacking positioning mechanisms (C) close to the lower part of one end of the plastic shell feeding mechanism (A), two sets of clamp mechanisms (D) at the middle part, one set of upper pressing mechanism (E) at the upper part, the conveying line mechanism (B) is provided with a lower jacking calibration mechanism (F) close to the lower part of one end of the unpowered roller line mechanism (G), and a station switching cylinder (H) is connected with and drives the upper pressing mechanism (E) to horizontally slide along.

2. The lead-acid storage battery grooving machine according to claim 1, wherein the plastic casing feeding mechanism (a) comprises a first motor (2), a first lifting cylinder (5) and a positioning cylinder (6), wherein a movable end of the positioning cylinder (6) is connected with a profile plate (7) through a transmission mechanism, a movable end of the first lifting cylinder (5) is connected with the plastic casing (1), the plastic casing (1) is located above the first conveying chain (3), the profile plate (7) is located below the first conveying chain (3), the first motor (2) is in transmission connection with the first conveying chain (3), a control box (4) is further arranged below the first conveying chain (3), and the first conveying chain (3) conveys the plastic casing (1).

3. The lead-acid storage battery grooving machine according to claim 1, wherein the conveyor line mechanism (B) comprises a second motor (8) and a second conveyor chain (9), wherein the second motor (8) is in transmission connection with the second conveyor chain (9), and the second conveyor chain (9) conveys the plastic case (1).

4. The lead-acid storage battery slot-inserting machine according to claim 1, characterized in that the lower jacking-positioning mechanism (C) comprises a bottom door plate cylinder (10), a first limit cylinder (12), a second limit cylinder (13), a first clamping cylinder (14), a second lifting cylinder (15) and a third lifting cylinder (16), wherein the bottom door plate cylinder (10) is connected with a transmission bottom door plate (11) for opening and closing, the first clamping cylinder (14) is arranged below the door plate (11), the first limit cylinder (12) and the second limit cylinder (13) are arranged on two sides of the first clamping cylinder (14), the movable end of the second lifting cylinder (15) is connected with a bottom plate, the fixed end of the third lifting cylinder (16) is connected with the fixed end of the second lifting cylinder (15), the movable end is connected with the first limit cylinder (12), the second limit cylinder (13) and a mounting plate where the first clamping cylinder (14) is located, guide rods are arranged on two sides between the mounting plate and the bottom plate.

5. The lead-acid storage battery grooving machine according to claim 1, wherein the clamp mechanism (D) comprises a side cylinder (17) and an end cylinder (18), movable ends of the side cylinder (17) and the end cylinder (18) are respectively in transmission connection with clamp inner plates (21) of a center, a pole group (20) is placed between the clamp inner plates (21), and a square steel limiting plate (19) is further arranged in the middle of each clamp inner plate (21).

6. The lead-acid storage battery groove-entering machine of claim 1, characterized in that the upper pressing mechanism (E) is arranged on the upper portion and comprises a lug-adjusting positioning cylinder (22), a groove-entering cylinder (23), a material-ejecting cylinder (24) and a lug-adjusting cylinder (25), wherein the fixed end of the lug-adjusting positioning cylinder (22) is connected with the fixed end of the groove-entering cylinder (23), the movable end of the groove-entering cylinder (23) is connected with the top plate, the top plate is connected with the mounting frame of the material-ejecting cylinder (24) through a guide rod, the movable end of the groove-entering cylinder (23) is connected with the movable end of the material-ejecting cylinder (24), the fixed end of the material-ejecting cylinder (24) is connected with a first ejector pin (26), the end of the first ejector pin (26) is provided.

7. The lead-acid storage battery grooving machine according to claim 1, wherein the lower jacking calibration mechanism (F) comprises a third limiting cylinder (28), a second clamping cylinder (29) and a fourth lifting cylinder (30), wherein the fixed end of the fourth lifting cylinder (30) is connected with the bottom plate, the movable end of the fourth lifting cylinder is connected with a mounting rack of the third limiting cylinder (28) and the second clamping cylinder (29), the mounting rack is connected with guide rods on two sides of the bottom plate, the third limiting cylinder (28) and the second clamping cylinder (29) are adjacently arranged, and a second thimble (31) is arranged above the third limiting cylinder (28) and the second clamping cylinder (29).

8. The lead-acid storage battery slot-entering machine as claimed in claim 1, wherein the unpowered roller line mechanism (G) comprises a material-pushing cylinder (32) and a roller line (33), wherein the end of the roller line (33) is provided with a sensor (34), and the side surface of the end of the roller line (33) is provided with the material-pushing cylinder (32).

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