KR101690689B1 - Apparatus For Adherence Protecting Of Plate - Google Patents

Abstract

The present invention relates to an apparatus for protecting electrode plates from adhering to each other. The apparatus for protecting electrode plates from adhering to each other comprises: a first alignment part which is installed in a start portion of an entrance to a transfer path, through which a group of electrode plates are transferred, in a battery electrode plate assembly line, lifts the group of electrode plates being transferred from the transfer path, and primarily aligns the individual electrode plates; a waiting part which is installed in a portion of the transfer path corresponding to a predetermined point behind the first alignment part, lifts the group of electrode plates being transferred from the transfer path, and allows the group of electrode plates to wait; and an overturning part which is installed in a portion of the transfer path corresponding to a predetermined point behind the waiting part, lifts the group of electrode plates being transferred from the transfer path, and overturns the group of electrode plates in clockwise and counterclockwise directions, thereby preventing the individual electrode plates from adhering to each other and separating the individual electrode plates. Accordingly, electrode plates of each group can be prevented from adhering to each other, and thus costs required for manufacture of the electrode plates can be reduced and product values of finished electrode plates can be improved.

Description

[0001] Apparatus For Adherence Protecting Of Plate [0002]

More particularly, the present invention relates to an apparatus for preventing sticking of an electrode plate, and more particularly, to an apparatus for preventing sticking of an electrode plate by reversing a process of moving along an assembly line in a state in which a plurality of electrode plates, The present invention relates to an adhesion preventing device for an electrode plate.

Generally, conventionally, in the process of manufacturing the electrode plates of a battery, a plurality of individual electrode plates are moved along the assembly line. In this process, the individual electrode plates are not completely dried, and due to the adhesive substances on the surfaces of the individual electrode plates There is a problem that a phenomenon sticking to each other occurs.

It is difficult to remove the sticking electrode plate if a certain time elapses due to the sticking phenomenon between the electrode plates. If the electrode plate is forcibly separated, problems such as partial loss and damage of the electrode plate falling off partly occur, I lose.

If the product value of the electrode plate is lowered as such, the manufacturing cost of the electrode plate may increase, and the workability of removing the electrode plates due to sticking phenomenon between the electrode plates is increased, It is inevitable that the process efficiency from the assembly process to the finished product of the assembly is reduced.

On the other hand, general techniques related to the manufacture of a battery include those disclosed in Japanese Patent Application Laid-Open Nos. 10-0541227, 10-0541228, 10-0451226, 10-2008-0081315, 1326446, etc. have been disclosed.

Patent No. 10-0541227, Patent No. 10-0541228, Patent No. 10-0451226, Published Japanese Patent Application No. 10-2008-0081315, Patent No. 10-1326446.

An object of the present invention is to provide an apparatus for preventing sticking of an electrode plate, which is constructed on an assembly line of a battery, to prevent a sticking phenomenon between individual electrode plates during movement of the electrode plate group .

In order to achieve the above-described object, the present invention provides a method of manufacturing a battery, comprising the steps of: mounting a pole plate assembly line on a transfer path for transferring a pole plate group, A standby portion which is provided at a conveying path portion corresponding to a certain point rearward of the first aligning portion and waits for the plate group being conveyed to rise in the conveying path; And an inverting unit installed on the conveying path to elevate the group of electrode plates in the conveying path so as to invert the electrode plate group counterclockwise and prevent the individual electrode plates from adhering to each other, In a state in which it is installed in a state of being horizontally extended from a vertical position above the conveying path, And an inverting case for receiving left and right side portions of the electrode plate group while being moved by power.

A second aligning portion provided at a conveying path portion corresponding to a predetermined position rearward of the inverting portion to elevate the group of electrode plates being conveyed in the conveying path to secondary align the individual electrode plates; And a transporting direction changing unit installed on the transporting path to change the transporting direction so that the group of the electrode plates being transported can be transported from the transporting path to the other transporting path.

The first aligning unit, the waiting unit, the inverting unit, and the second aligning unit may further include a lift plate installed at an inner center of the conveying path to elevate and lift the plate group conveying along the conveying path.

The first and second alignment units may further include an alignment member for aligning the side steps of the individual electrode plates of the electrode plate group rising from the transfer path through the lifting plate by the power of the cylinder.

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The polarity reversal is alternately reversed in the counterclockwise direction with the clock, and the polar plate group is reversed as the polarizer plate is rotated, thereby constituting a rim of the external appearance in a trapezoidal shape preventing the adhesion between the individual polar plates, The edge portions of the individual pole plates of the pole plate group are formed by the inclined sides of the left and right sides of the rim of the trapezoidal shape, thereby preventing the adhesion of the individual pole plates to each other .

The inverting unit may include a motor installed at an upper central point of the frame formed from the left and right outer sides of the conveying path to provide rotational power, First and second shafts rotatable by a rotational power provided from a motor, respective connecting shafts installed in a vertical downward direction in the first and second shafts and rotated by rotational power of the first and second shafts, And the third and fourth shafts installed in the frame parallel to the left and right in the same manner as the first and second shafts at the lower end of the connection shaft and rotated by the rotational power of the respective connection shafts, It is a feature of an anti-stick device of an electrode plate in which operation is implemented.

The inverting unit includes first and second guides installed at upper left and right points of the frame formed from the left and right outer side of the conveying path to the upper and lower sides of the frame and the first and second guides are opened or closed horizontally And the moving operation of the inverting door, which is performed toward the pole plate group raised by the lifting plate, is performed through the moving means, which further includes the moving shafts receiving the first and second shafts and the respective connecting shafts Which is a feature of the anti-sticking device of the electrode plate.

As described above, according to the present invention, it is possible to prevent the adhesion between the electrode plates, thereby eliminating the necessity of separating the attached electrode plates, thereby shortening the process time and improving the process efficiency. .

In addition, the apparatus for preventing sticking of the electrode plate according to the present invention prevents the phenomenon of sticking of the electrode plates in advance to prevent the phenomenon of sticking of the electrode plates, It is possible to reduce the manufacturing cost of the electrode plate because there is no loss of the electrode plate because the commerciality of the electrode plate is not lost.

In addition, according to the present invention, since the problem of adhesion between the electrode plates is solved, the operation of removing the electrode plates from each other is lost, and the operation of removing the electrode plates is not required, It is possible to improve the product value of the electrode plate manufactured by blocking the problem and to maintain the continuity of the merchantability.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of an apparatus for preventing adhesion of an electrode plate according to the present invention,
FIG. 2 is a perspective view showing an enlarged state of the inverting unit shown in FIG. 1,
FIG. 3 is a perspective view of the operating state of the inverting unit shown in FIG. 2,
FIG. 4 is a perspective view of an anti-sticking device of an electrode plate including a loading state of the electrode plate group according to the present invention,
FIG. 5 is a diagram showing the operating motion of the inverting unit in the receiving state of the electrode plate group at the inverting unit shown in FIG. 4,
6 is a view showing a power transmitting means required for operation of the inverter shown in FIG. 4,
Fig. 7 is a view showing the electrode plate accommodating state of the inverting section,
FIG. 8 is a front view of one of the inverted portions of the inverting portion shown in FIG. 7,
FIG. 9 is a view showing a modification of the electrode plate group housed in the inverting portion according to the reversing operation of the reversing portion shown in FIG. 8. FIG.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. And it should be interpreted based on the technical ideas throughout the specification taking into consideration that various modifications are made.

In addition, the present invention should not be construed as being limited to the embodiments described below, but should be construed as a scope of scope including an extended scope interpreted based on the technical content described in the specification.

It is a lead acid battery that is widely used in various fields such as industrial, automobile, communication, UPS, etc., and it is manufactured after the mixing and casting process, followed by the chemical process after the mixing and coating process, .

In the manufacturing process of the battery, a battery is composed of a front electrode, a cover and an electrode plate group, and the front electrode, the cover and the electrode plate group are assembled and assembled in a state of being manufactured through each assembly line built in one station It will then be possible to produce one full battery.

In particular, in each assembly line constructed in one station, the present invention relates to an apparatus for preventing sticking of an electrode plate to an assembly line of electrode plate groups moved in a state in which electrode plates are manufactured, (Sticking) phenomenon between the electrode plates in the process of moving the electrode plate group through the assembly line.

An apparatus for preventing adhesion of an electrode plate according to the present invention will be described in detail with reference to the accompanying drawings.

The apparatus for preventing sticking of the electrode plate according to the present invention is constructed on the assembly line of the electrode plate assemblies, and as shown in FIGS. 1 and 4, the electrode plates PA are connected by a scrach A transporting path TP of the chain means to be transported and a transporting path TP which is transported along the transporting path TP formed vertically upward from the left and right outer sides of the transporting path TP at the entrance of the transporting path TP And a conveying path TP corresponding to a certain point rearward of the first aligning part 10 and being formed in a chamber shape upward from the left and right sides of the conveying path TP, And a transfer path TP corresponding to a certain point rearward of the air bearing portion 20 from an outer side of the transfer path TP to an upper side of the transfer path TP, (PA) that are conveyed along the conveying path (TP) Alternately rotating in a counterclockwise direction is reversed, and is configured to include the inverted portion (30) for preventing the adhesion (sticking) developing between the individual plates of the electrode plate group (PA).

The apparatus for preventing sticking of the electrode plate according to the present invention is characterized in that an electrode plate (not shown) which is conveyed along the conveying path (TP) formed in the upper direction from the right and left outer sides of the conveying path The second aligning unit 40 is arranged in such a manner that the second aligning unit 40 is arranged at a predetermined position rearward of the second aligning unit 40 and is connected at the end of the conveying path TP. And a feeding direction changing unit 50 for rapidly changing the feeding direction of the electrode plate group PA conveyed along the feeding direction TP.

The first aligning part 10 is formed on the upper part of the conveying path TP at the early part of the conveying path TP and extends from the right and left outer sides of the conveying path TP to the vertical upper part, (11) extending vertically downward from the upper center of the frame (11) toward the conveying path (TP) and being opened or closed by the power of a cylinder, so that the individual pole plates And a pair of electrode plates PA that are formed at the inner center of the transfer path TP and enter the transfer path TP to be transferred and reach the alignment position of the alignment member 12 And a lifting plate (13) for supporting the lifting plate (13).

That is, the lifting plate 13 is in the standby state at the inner center of the transporting path TP, and when the electrode plate group PA approaching through the transporting path TP arrives, And is stopped when it reaches the position of the alignment member 12 in the upward direction.

The pole plate group PA arriving at the position of the aligning member 12 by the elevating plate 13 is moved by the operation of the aligning member 12 which is opened or closed by the cylinder power, The front and rear sides of the individual electrode plates of the electrode plate group PA in the progressing direction are removed so that the front and rear sides of the electrode plate are aligned in a line. Here, the alignment member 12 is also formed on the front and rear sides of the upper end of the frame 11 for front and rear side alignment of the electrode plates.

When the primary alignment of the electrode plate group PA is performed by the operation of the alignment member 12, the lifting plate 13 is lowered and returned to its original state, so that the plate group PA again feeds the transporting path TP .

The waiting part 20 is formed on the upper part of the conveying path TP corresponding to a certain position rearward of the first aligning part 10. The box frame part 21 And a lifting plate 22 installed at the center of the inner side of the feed path TP to raise the plate group PA primarily aligned through the first aligning portion 10 in the feed path TP .

The lifting plate 22 vertically lifts the plate group PA when the first plate group PA aligned through the first aligning unit 10 is moved while being transported along the transport path TP, Wait in a stopped state. The standby of the lifting plate 22 is required to match the time required for the reversing operation in the reversing unit 30 to be described later.

6, the inverting unit 30 is formed on the transfer path TP corresponding to a certain position rearward of the standby unit 20, TP), first and second guides (32, 32a) fixedly coupled to left and right upper ends of the frame (31), and first and second guides 1 and 2 guides are installed in the form of passing through the central portion of the upper end of the frame 31 and the movable members 33 and 33a in which the upper and lower faces are respectively engaged and opened horizontally by the cylinder power, A first and second shafts (34, 34a) mounted horizontally in parallel on the left and right sides of the motor and rotated by the rotational power of the motor, Installed in a form that is connected to 1,2 shaft and extends to the vertical lower part The first and second shafts are rotatably supported by the first and second shafts. The shafts 36 and 36a are rotated by the rotational power of the first and second shafts. A third and fourth shafts (35, 35a) rotated by the rotational power of the respective connection shafts receiving the rotational power of the first and second shafts, The inverting chambers 37 and 37a installed in the shape of a gap between the inverting chambers 37 and 37a and the inverting chambers 37 and 37a provided at the inner center of the feeding path TP to vertically raise the polar plate group PA passing through the air bearing portion 20, And a lifting plate 39 for lifting the lifting plate 39.

Here, the clockwise and counterclockwise movement of the inverting chambers 37 and 37a is controlled by the rotation of the motor M, the first and second shafts 34 and 34a, the connecting shafts 36 and 36a, And the four shafts 35 and 35a, and the operation of opening and closing the inverting chambers 37 and 37a is performed by connecting the first and second shafts 35 and 35a, 1,2 guides (32, 32a), and angular shifting members (33, 33a) that move horizontally by the first and second guides. Of course, the moving members 33 and 33a can be horizontally moved along the first and second guides 32 and 32a by the cylinder power, and the first and second shafts 34 and 34a and the connecting shafts 36 And 36a so as to protect the first and second shafts 34 and 34a and the connection shafts 36 and 36a from the outside.

The opening and closing operations of the inverting chambers 37 and 37a are performed by the first and second guides 32 and 32a and the moving members 33 and 33a moved by the first and second guides The respective connecting shafts 36 and 36a must be moved together when the moving members 33 and 33a are moved. The movement of the connecting shafts 36 and 36a is transmitted to the first and second shafts 34 and 34, The bevel gears of the first and second shafts 34 and 34a connected to one ends of the connection shafts 36 and 36a can be moved along the separation due to the formation of the separations It is because.

Here, the connection between the shaft of the motor M and one end of the first and second shafts 34 and 34a, the connection between the first and second shafts 34 and 36a and one ends of the connection shafts 36 and 36a, As shown in FIG. 6, the connection between the other ends of the connection shafts 36 and 36a and the third and fourth shafts 35 and 35a is connected to the bevel gear, The rotation of the connection shaft 36 after the rotation of the first and second shafts 34 and 34a by the rotation of the third and fourth shafts 35 and 35a, Clockwise and counterclockwise rotation operation of the first and second rotating bodies 37a and 37a is enabled.

The inverting chambers 37 and 37a alternately rotate in counterclockwise direction when the motor is driven through the connection structure between the motor, the first and second shafts, the connection shafts, and the third and fourth shafts, At this time, the electrode plates PA are reversed at the same time and rotated, thereby preventing the adhesion between the individual electrode plates.

The inversion enclosures 37 and 37a are disposed on the right and left sides of the pole plate group PA in such a manner that the left and right side surface portions of the pole plate group PA are received through a moving operation, The polarity of the polar plate group PA is reversed simultaneously to prevent the adhesion between the individual polar plates 37 and 37a, The edge portion 38 corresponding to the outer appearance has a trapezoidal shape.

As shown in FIGS. 5 to 6, the trapezoidal shape of the inverted case 37, 37a is a trapezoidal shape of the rim 38 corresponding to the outer appearance, as shown in FIGS. 7 to 9, The left and right side portions of the pole plate group PA are alternately inverted in a clockwise and counterclockwise direction while the left and right side portions of the pole plate group PA are rotated, The edge of the individual electrode plate is generated due to the fact that it is located on the left side or the right side in the rim portion 38, so that the problem of adhesion between the individual electrode plates can be solved.

That is, since the left side and the right side in the frame portion 38 are inclined, when reversing the clockwise or counterclockwise direction (37, 37a), as shown in FIG. 9, One of the side faces is located on the right side in the rim 38 and the step difference between the individual electrode plates is caused by the inclination factor of the right side together with the self weight of the electrode plate group PA so that the adhesion between the individual electrode plates can be prevented have.

The second aligning unit 40 is disposed above the conveying path TP corresponding to a predetermined position behind the inverting unit 30 and includes a frame 41 composed of an upper part of the conveying path TP, An aligning member 42 and 42a which is configured in a shape similar to the aligning member 12 of the first aligning unit 10 at the upper center of the frame and a take-up plate 42 ).

The alignment members 42 and 42a are also arranged on the front side and the rear side of the frame 41 so as to be capable of performing an operation of being opened or closed by the cylinder power in the form of facing the upper center of the frame 41 And aligns the front and rear sides of the rising plate group PA through the lifting plate 43 in a straight line.

Lastly, the transport direction changing unit 50 is connected to the end of the transport path TP, and is provided with a plate group TP (TP) that is transported along the transport path TP through the second aligning unit 40, The feed direction changing unit TP includes a roller assembly 51 so that a plurality of individual rollers 52 can be tilted into a single lump.

Therefore, when the electrode plate group TP transferred to the end of the conveying path TP reaches the roller assembly 51 of the conveying direction changing unit 50, the roller assembly 51 is tilted in one direction And is conveyed along another conveyance path in accordance with the driving of the individual rollers 52. [

As described above, the electrode plate anti-sticking device according to the present invention is constructed in an assembly and assembly line of an electrode plate and prevents the adhesion between the individual electrode plates of the electrode plate group by reversal operation of the reversing operation through primary alignment and atmospheric transfer in the process of transferring the plate groups. By including the second sorting and then another conveying path through the other conveying path, it is possible to solve the sticking problem between the individual electrode plates, and it is possible to expect the improvement and maintenance of the product value of the manufactured electrode plate group. Can be saved.

10:
20: a base portion 21: a frame chamber
30: Inverse 32,32a: First and second guides
33, 33a: Movable member M: Motor
34, 34a: first and second shafts 35, 35a: third and fourth shafts
36,36a: connection axis 37,37a: inverted
38:
40:
50: Feed direction changing section
PA: plate group TP: transport path

Claims (7)

A first aligning unit installed at an initial position of a conveying path for conveying the electrode plate group in a state of being built in an electrode plate assembly line of the battery and lifting the electrode plate group being conveyed in the conveying line to primarily align the individual electrode plates; A standby portion installed at a conveying path portion corresponding to a certain position rearward of the first aligning portion and waiting for the plate group being conveyed to rise in the conveying path; And a transfer unit installed at a transfer path corresponding to a predetermined position rearward of the waiting unit to move the electrode plate group in the transfer path in the transfer path to invert the electrode plate group counterclockwise with respect to the clock and prevent the adhesion between the individual electrode plates, all; Lt; / RTI >
The inverting unit further includes an inverting unit that receives the left and right side portions of the electrode plate group while being moved by the power of the cylinder toward the rising electrode plate group through the lift plate in a state where the inverting unit is installed at a position vertically above the transfer path Wherein the adhesive layer is formed on the surface of the plate. The method according to claim 1,
A second aligning unit installed on a conveying path corresponding to a predetermined position rearward of the inverting unit, for lifting the electrode plate group in the conveying path to secondary align the individual electrode plates;
A feed direction changing unit installed at a feed path corresponding to a certain position rearward of the second aligning unit and changing the feed direction so that the group of the plate groups being fed can be fed from another feed path to another feed path;
And an adhesive layer formed on the adhesive layer. 3. The method of claim 2,
Wherein the first aligning unit, the waiting unit, the inverting unit, and the second aligning unit comprise: a lift plate installed at a center of an inner side of the conveying path to elevate and lift the plate group conveying along the conveying path;
Further comprising:
Wherein the first and second aligning portions include an aligning member that aligns the side steps of the individual electrode plates of the electrode plate group rising from the conveying path through the lifting plate by the same power of the cylinder;
And an adhesive layer formed on the adhesive layer. delete The method according to claim 1,
The polarity reversal is alternately reversed in a counterclockwise direction with the clock, and the polar plate group is inverted together with the polar plate group as the unit is rotated, thereby forming a rim of the external appearance in a trapezoidal shape preventing the individual polar plates from sticking to each other.
The side plates of the electrode plate group are formed by the inclined side shapes of the left and right sides of the trapezoidal rim portion during the counterclockwise inversion of the clock of the inverted case, Of the electrode plate. The method according to claim 1,
Wherein the inverting unit comprises: a motor installed at an upper central point of the frame formed from the left and right outer sides of the conveying path to the upper direction to provide rotational power;
First and second shafts installed on the frame parallel to the left and right with respect to the motor at a predetermined lower portion of the motor and rotated by rotational power provided from the motor;
Each connecting shaft installed in the first and second shafts in the vertical downward direction and rotated by the rotational power of the first and second shafts;
Third and fourth shafts installed in the frame parallel to the left and right at the lower end of each of the connection shafts as in the first and second shafts and rotated by the rotational power of the connection shafts;
And the reversing operation of the reversing is realized by the power transmitting means including the electric power transmitting means. The method according to claim 6,
The reversing unit includes first and second guides installed at upper left and right points of the frame formed from the left and right outer sides of the conveying path to the upper direction;
A moving member for moving the first and second guides horizontally open or narrowed by the power of the cylinder in a state in which the top and bottom faces are bitten, the moving member receiving the first and second shafts and the connection shafts;
Wherein the reversing operation of the reversing door, which is widened toward the electrode plate group raised by the lifting plate, is performed through the moving means including the moving means.

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