KR101836779B1 - Apparatus foe plate transfer and adherence protecting - Google Patents

Abstract

The present invention relates to an apparatus for preventing transfer or adhesion of electrode plates, the apparatus which prevents adhesion of respective electrode plates by applying an impact to an electrode plate group transferred to a post-process line, and particularly is capable of increasing productivity by increasing space utilization and reducing working hours, and is capable of improving quality by reducing deformation or damage of the respective electrode plates generated when the impact is applied to the electrode plate group. The apparatus of the present invention comprises: an inlet conveyor into which the electrode plate group including a plurality of electrode plates, painted with lead and stacked in a state that the electrode plates are horizontally laid, is injected such that the electrode plate group is transferred by the inlet conveyor; an electrode plate adhesion preventing unit which aligns the electrode plates after applying an impact to the electrode plates to prevent adhesion among the electrode plates stacked after receiving the electrode plate group from the inlet conveyor; and an outlet conveyor which receives the electrode plate group from the electrode plate adhesion preventing unit to transfer the electrode plate group to a post-process. The electrode plate adhesion preventing unit includes: a vertical disk wheel which is formed in a vertically erected wheel shape, and which supplies the electrode plate group to the outlet conveyor through an outer circumference of the other side after upwardly rotating the electrode plate group by receiving the electrode plate group from the inlet conveyor through an outer circumference of one side; and an impactor which is installed within the vertical disk wheel, and which applies an impact to the electrode plate group to prevent adhesion of the respective electrode plates when the vertical disk wheel is upwardly rotated.

Description

[0001] APPARATUS FOE PLATE TRANSFER AND ADHERENCE PROTECTING [0002]

More particularly, the present invention relates to an apparatus for preventing adhesion of each electrode plate, and more particularly, to an electrode plate assembly in which a plurality of electrode plates laminated with respective electrode plates are transferred to a post-process line along an inlet conveyor, The present invention relates to an electrode plate feeding device and an adhesion preventing device.

The battery is composed of a positive and negative electrode plate and an electrolytic solution, and is a device that can generate DC power by a chemical action and use it as a power source. The conversion between chemical energy and electrical energy is made possible, and the number of times it is limited to one is the primary battery, and the number of times it is possible is the secondary battery.

It is possible to change chemical energy into electrical energy. This state is called discharge, and electrical energy is supplied from another power source, which can be converted into chemical energy and accumulated. This state is called charge. A battery in which charging and discharging are repeated is referred to as a storage battery or a secondary battery. Such types of batteries are currently widely used, including lead acid batteries using lead, lithium ion batteries using lithium ions, and nickel metal hydride batteries using nickel.

The battery includes a case filled with an electrolytic solution, a cover coupled to the case, a plurality of separators provided inside the case, a plurality of negative plates provided between the separators, A negative electrode plate disposed symmetrically with the negative electrode plate, and a connector coupled to the upper portion of each of the electrode plates.

That is, the positive electrode plate and the negative electrode plate are connected in parallel, and the separator plate provided between the positive electrode plate and the negative electrode plate is formed of an insulating material. In particular, in the case of lead-acid batteries, lead dioxide (PbO ₂ ) is usually used for the anode, and lead (Pb) is used for the anode and the electrolyte is placed in sulfuric acid (H ₂ SO ₄ ) having a specific gravity of 1.2 to 1.3. In the charged state, lead dioxide is used as the anode and lead is used as the cathode. However, when the discharge is continued, the anode and the cathode are all made of lead sulfate (PbSO ₄ ) and water (H ₂ O) is generated at the same time.

The electrode plate of the above-mentioned battery is formed by continuously rolling and thinning the lead plate strip formed by the rolling roller mold, cutting it into a size that can be installed inside the battery, and processing it into an electrode plate shape. Thereafter, an active material promoting smooth chemical reaction is applied to the surface of the electrode plate and dried.

At this time, the active material is referred to as a lentil, and is prepared by mixing water, sulfuric acid, and other additives with a small particle of lead (Pb) and lead oxide (PbO). In the case of the pole plate painted with burrs, the electrode plate is completed when the drying process and the aging process are performed to reduce moisture and lead content.

Then, the completed electrode plate is transferred to the assembly line, laminated in the order of the anode plate, the separator plate, and the cathode plate, and then the welding is performed and the battery is installed in the case of the battery. Here, the completed electrode plates are laminated and transferred to the assembling line by the electrode plate group. However, there occurs a phenomenon that the laminated electrode plates are adhered to each other in the coating process and the charging process. When each of the adhered electrode plates is supplied to the assembly line, each of the adhered positive and negative plates can not be assembled into a single sheet, resulting in failure of the battery.

Therefore, when the laminated electrode plates are transferred to the assembly line through the drying process and the aging process, generally, an operator applies shock to the outside of the electrode plate group to prevent sticking, and aligns the supplied electrode plates to the conveying conveyor. However, when the worker is put into the process line and performs the work, the production cost due to the labor cost is increased and the production amount is decreased.

In order to solve the above-mentioned problem, a battery is manufactured by providing a device for applying an impact to prevent adhesion of each electrode plate to a line to be transferred to an assembly line. In the "automatic plate feeding device" of Patent Publication No. 10-1608331, the sticking of each of the plate plates is prevented through the plate plate arranging portion. However, in the case of the above-mentioned electrode plate arranging portion, the polar plate group vertically erected from the conveyor is pressed on both sides to apply vibration to prevent sticking. When the both layer surfaces of the electrode plate group are pressed, a problem occurs that the electrode plate is bent by the pressure, which degrades the quality of the battery.

In addition, when both sides of each of the attached electrode plates are pressed, the center of each of the electrode plates is bent and separated, but both ends of each of the electrode plates are maintained in a state of being adhered. Therefore, when the electrode plates are elastically restored after the pressurization is completed, there is a problem that the electrodes are restored. In this way, the electrode plates that are adhered to each other are not effectively separated from each other. There is a problem that the detached kidney falls on the transfer line and contaminates the electrode plate group.

In addition, in the 'apparatus for preventing sticking of the electrode plate' of Patent Document 10-1690689, the electrode plate group having the reversing portion is held at both ends and raised in the conveying path, and then reversed clockwise and counterclockwise, prevent. However, since the operation of rotating the pole plate group moving along the conveyor occurs, the time required for the operation is increased and the productivity is lowered. Also, by installing a device having a mechanism for raising the pole plate group and a mechanism for rotating the pole plate group, There is a problem that not only the apparatus becomes longer and larger at the same time, but also the space utilization is lowered, as well as the pole plate group is separated by rotation and each pole plate is hit by a collision.

In addition, the rotation of the inversion portion causes a phenomenon in which the electrode plate group is accumulated in the inverting portion due to the contact impact with the inverting portion of the electrode plate, The quality of the product is lowered due to contamination, and the surface of each of the electrode plates is damaged due to contact with the accumulated burrs.

It is an object of the present invention, which has been devised to solve the above-mentioned problems, to provide a method and apparatus for preventing an adhesion of each electrode plate by applying an impact to an electrode plate group transferred to a post-process line, And to provide an electrode plate feeding and sticking prevention device capable of improving the quality by reducing the deformation and damage of each electrode plate caused by impact on the electrode plate group.

In order to achieve the above object, the present invention provides an electrode plate conveying and sticking prevention device comprising: an inlet conveyor for feeding a group of electrode plates laminated with a plurality of polar plates in a state where the nose is painted and horizontally laid, And an outlet conveyor for feeding the electrode plate group from the electrode plate sticking prevention portion to a post-process, and an adhesive layer The vertical plate wheel is a wheel formed vertically and has a vertical disc wheel for supplying the plate group to the outlet conveyor through the outer circumference of the other side after the plate group is supplied from the inlet conveyor through the outer circumference, , And is provided inside the vertical disc wheel, and when the vertical disc wheel is rotated upward, And an impactor for applying an impact to prevent adhesion of each of the electrode plates.

The vertical disc wheel may include a pair of stationary discs fixedly installed so as to face each other in a vertically erected state, a plurality of erecting holes provided on an outer circumferential surface of the stationary disc, A plurality of electrode plate stacking members formed radially on the outer circumferential surface of the wheel body so that the electrode plate group is inserted and loaded, and a rotating motor for rotating the wheel body.

The impactor may include a punching member installed in the wheel body of the vertical disc wheel and penetrating the annular discharge hole of the wheel body to impact the pole plate group, And a punching cylinder for advancing and retracting the punching member.

In addition, the impactor applies an impact to the electrode plate group through the burr hole when the burr hole of the wheel body is located at the uppermost end of the wheel body.

In addition, the impactor may be installed at an angle to be symmetrical with respect to the pair of the arms, and when the right hole of the wheel body is located at the left upper portion and the right upper portion of the wheel body, And a shock is applied to each of them.

In addition, when the above-mentioned errands released from the surface of each of the electrode plates are dropped through the erroneous discharge hole of the wheel body due to the impact of the impactor, the erroneously falling errands are collected and discharged to the outside And a discharge port for discharging the water.

In addition, the burner discharge unit may include a burner socket installed below the impactor to receive the burner falling through the burner outlet hole of the wheel body, and a discharge conveyor for transferring the burner from the burner receiver to the outside And a collection box for collecting the kidney transferred from the discharge conveyor.

The electrode plate conveying and sticking prevention device according to the present invention is characterized in that an electrode plate adhesion preventing portion is formed in a wheel shape and supplied to an outlet conveyor through an outer conveyor after the electrode plate group is supplied from one side to the upper conveyor, The space efficiency of the device can be increased by minimizing the length of the device to prevent.

In addition, when an impactor applies impact to the electrode plate group, when the electrode plate rotates and moves upwardly of the vertical disc wheel, the impact is applied to the electrode plate group, so that an impact is generated only below the electrode plate group.

In addition, when the vertical plate wheel supplied in the horizontal state rotates and moves upward, the vertical plate is formed, and since the impactor impacts the vertical plate group, it is easy to separate each of the plate groups, The respective anti-sticking effects can be enhanced.

In addition, when the pair of impactors are symmetrically arranged at an angle to be inclined, impact is applied when the electrode plate group is positioned on the left upper side and the right upper side of the vertical disk wheel, respectively, so that the production time can be reduced and the production amount can be increased.

In addition, since the impact hole is formed in the wheel body of the vertical disc wheel so that the impact is applied to the pole plate group, the erroneous member is separated from the surface of each pole plate and accumulated in the pole plate stacking member of the vertical disc wheel, It is possible to prevent the phenomenon of accumulation on the outer peripheral surface,

In addition, a burnout discharge unit is installed to collect the burned down coal from the burnout hole of the wheel body and discharge the burned coal to the outside, so that the burned coal falling from the upper side of the wheel body is inserted into the engagement portion of the plate anti- .

1 is a front view showing an apparatus for transferring and sticking an electrode according to the present invention,
Figure 2 is a top plan view of the embodiment of Figure 1,
FIG. 3 is a side view of the embodiment of FIG. 1,
Fig. 4 is a front view showing the anti-adhesion portion in the embodiment of Fig. 1,
5 to 7 are front views showing in detail the process of separating and aligning each of the pole plates by applying an impact when the pole plate group is located at the uppermost end of the wheel body,
8 is a front view showing another embodiment of the electrode plate feeding and sticking prevention apparatus according to the present invention,
Fig. 9 is a front view showing an anti-adhesion portion in the embodiment of Fig. 8,
10 to 12 are front views showing in detail the process of separating and aligning each of the impact plates when impact plates are placed on the left upper and right upper portions of the wheel body, respectively,
13 is a front view showing an electrode plate feeding and sticking prevention device provided with a burner discharge portion for collecting the burned-away burned-away burner from the surface of each of the pole plates by the impact of the pole plate's anti-
14 is a plan view of the embodiment of Fig. 13 viewed from above.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the electrode plate transferring and sticking prevention device according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 3, the apparatus for conveying and adhering an electrode according to the present invention comprises an inlet conveyor 100, an electrode plate anti-adhesion portion 200 and an outlet conveyor 300, The prevention unit 200 includes a vertical disc wheel 210 and an impactor 220.

As shown in FIGS. 1 to 3, the inlet conveyor 100 is a line through which an electrode plate group PG, in which a plurality of electrode plates P are stacked in a state of being laid horizontally, is inserted and transported, (PG) refers to a state in which the electrode plates (P) are cut so that they can be inserted into the battery through the manufacturing process as described above in the background art. In addition, in the case of the inlet conveyor 100, a protective cap is placed on the outer circumferential surface of the chain to prevent surface damage of the electrode plate group, and the widths of the left and right chains provided on the inlet conveyor 100 are A conveyor that is relatively narrower than the width of the vertical disc wheel 210 of the later-described polar plate anti-adhesion portion 200 should be provided.

1 to 3, the outlet conveyor 300 is a line for receiving the electrode plate group PG from the later-described electrode plate anti-adherence preventing unit 200 and transferring the group of electrode plates PG to a subsequent process. At this time, Refers to a process of manufacturing a battery through a manufactured electrode plate (P), such as a process of disposing the battery in the battery or arranging the battery in the order of the positive electrode plate, the negative electrode plate and the separator. In the case of the outlet conveyor 300, a protective cap is placed on the outer circumferential surface of the chain in order to prevent surface damage of the electrode plate group. The widths of the left and right chains provided on the outlet conveyor 300 are It is necessary to provide a conveyor which is relatively narrower than the width of the vertical disc wheel 210 of the later-described polar plate anti-adhesion portion 200.

As shown in FIGS. 1 to 3, the electrode plate anti-adhesion part 200 is formed by applying the electrode plate group PG from the inlet conveyor 100 and applying a shock to prevent adhesion between the electrode plates P stacked and laminated Perform post sorting. At this time, the polar plate sticking prevention part 200 includes a vertical disc wheel 210 and an impactor 220 to simultaneously perform an operation of preventing the polar plate group PG from being conveyed and sticking.

First, the vertical disc wheel 210 is a vertically erected wheel shape as shown in FIGS. 1 to 4. The vertical disc wheel 210 is supplied with the plate group PG from the inlet conveyor 100 through one outer circumference, A wheel body 212, an electrode plate loading member 213 and a rotary motor 214 for performing an operation of supplying the electrode plate group PG to the outlet conveyor 300 through the outer periphery of the other side .

As shown in FIGS. 1 to 4, the stationary disc 211 is fixedly installed so that a pair of discs are vertically erected so as to face each other. The stationary disc 211 is fixed to the inlet conveyor 100 and the outlet conveyor 200, (300) is installed, and performs the same function as the frame. In addition, the respective original plates are apart from each other. In the space where the inlet conveyor 100 and the outlet conveyor 300 are installed, a frame plate (not shown) for fixing and supporting the plate- And a casing disc (not shown) having the same center as that of the casing and spaced apart from the frame disc by a predetermined distance. In this case, a coupling member (not shown) may be further included which is radially fixedly coupled between the respective discs to fix the casing original plate to the frame original plate.

As shown in FIGS. 1 to 4, the wheel body 212 is rotatably installed between the stationary discs 211 in the form of a vertically erected ring, and a plurality of annular discharge holes 211a are formed in the outer circumferential surface of the wheel body 212 . That is, the center of the fixed disk 211 has the same center as the center of the fixed disk 211 and is spaced apart from the disk of the fixed disk 211 by a predetermined distance between the fixed disks 211, .

3, a bearing (not shown) for supporting the rotation of the wheel body 212 in the direction toward the right of the wheel body 212, that is, in the direction of the frame disk of the fixed disk 211, And is disposed between the wheel body 212 and the frame disk of the fixed disk 211. Here, regardless of what type of bearing is installed, it is preferable to provide a cross roller bearing in order to reduce the axial load of the rotary motor 214, which will be described later.

Subsequently, the electrode plate loading member 213 is radially projected on the outer circumferential surface of the wheel body 212 so that the electrode plate group PG is inserted and loaded, as shown in FIGS. The electrode plate loading member 213 protrudes from both sides of the wheel body 212 when viewed from above the wheel body 212 to form a space between the electrode plate loading members 213. When the inlet conveyor 100 is inserted into the space and the plate group PG conveyed through the inlet conveyor 100 arrives at the end of the inlet conveyor 100, the inlet conveyor 100 comes into contact with the outer peripheral surface of the wheel body 212 And simultaneously rest on the upper side of the electrode plate loading member 213.

Therefore, when the electrode plate group PG is seated on the electrode plate loading member 213 and the wheel body 212 is rotated, the empty electrode plate loading member 213 is again positioned at the end portion of the inlet conveyor 100, It is possible to supply the electrode plate group PG to the outlet conveyor 300. That is, as described above in the inlet conveyor 100, it is preferable that the interval between the electrode plate stacking members 213 is formed to have a sufficient space to allow the inlet conveyor 100 to be inserted therein.

1 to 4, the rotation motor 214 rotates the wheel body 212. In order to increase the rotation force, one end of the gear box (not shown) is connected to the rotation motor 214, And the other end of the gear box is engaged with the cross roller bearing described above in the wheel body 212. [

In other words, the rotation of the rotation motor 214 rotates the gears of the gear box to rotate the cross roller bearing, and the cross roller bearing rotates the wheel body 212. The rotary motor 214 also intermittently rotates the wheel body 211 so that the impactor 220 described later sufficiently performs an operation of impacting the pole plate group PG inserted in the pole plate loading member 213. [ Further, a control unit for receiving the control signal by the rotation motor 214 is provided outside the plate-like anti-adhesion unit 200.

Next, the impactor 220 is installed inside the vertical disc wheel 210 as shown in FIGS. 1 to 4, and impacts the pole plate group PG when the vertical disc wheel is rotated upward, At this time, the impactor 220 includes a punching member 221 and a punching cylinder 222. The punching member 221 and the punching cylinder 222 are disposed on the impact plate 220, respectively.

1 to 4, the punching member 221 is installed inside the wheel body 212 of the vertical disc wheel 210, and the punching member 221 is inserted into the annular hole 212a of the wheel body 212 And impacts the electrode plate group PG. One surface of the punching member 221 is formed to be inclined regardless of whether the impact is applied to the electrode plate group PG so that the impact received by each electrode plate is different from that of the wheel body 212. At this time, the inclined surface is formed in a rounded shape instead of a straight line, and it is in point contact with the lower surface of each of the electrode plates loaded on the electrode plate mounting member 213, thereby increasing the amount of impact received by the electrode plate group PG, have.

In addition, in the course of the downward movement of the electrode plate group PG due to the impact of the punching member 221, each of the electrode plates P is separated and aligned along the outer circumferential surface of the wheel body 212 . That is, in the case of the wheel body 212, a part of the outer circumferential surface on which the electrode plate loading member 213 is formed may be formed in a plane other than the rounded shape.

The punching cylinder 222 advances and retracts the punching member 221 toward the upper side of the release hole 212a of the wheel body 212 as shown in FIGS. At this time, a punching piston (not shown), which is coupled to the other end of the punching member 221 and advances the punching member 221, is inserted in front of the punching cylinder 222 and automatically retracts the forwardly advancing punching piston A punching spring (not shown) is provided in the punching cylinder 222.

Further, a guide shaft inserted into the punching spring and coupled to the punching cylinder 222 is installed. One end of the guide shaft is fixedly coupled to the other end of the punching member 221 and the other end is provided to protrude from the rear of the punching cylinder 222. The punching spring is coupled to the punching cylinder in such a manner as to elastically support the guide shaft.

5 and 6, when the pole plate group PG mounted on the pole plate stacking member 213 is located at the uppermost end of the wheel body 212, the punching piston 222 of the punching cylinder 222 is moved forward The punching member 221 is advanced upward through the soft discharge hole 212a of the wheel body 212 to apply an impact to the electrode plate group PG so that each of the electrode plates P rises due to the impact They are separated at the same time.

7, the guide shaft is retracted by the resilient restoring force of the punching spring, and the punching member 221 is retracted to the lower side of the soft discharge hole 212a of the wheel body 212, Are also brought into contact with the outer peripheral surface of the wheel body 212 and aligned. That is, since the impact is applied only to the lower surface of the vertically erected electrode plate group PG, deformation or damage of each of the electrode plates can be prevented.

The vertical disk wheel 210 is a vertically erected wheel shape and a single impactor 220 is rotated by the outlet conveyor 300 from the inlet conveyor 100 to the pole plate group The impactor 220 may prevent the sticking of a larger amount of the plate group PG by a single sticking prevention operation, rather than applying an impact to the plate group PG. That is, as shown in FIG. 8, the pair of impactors 220 are installed inside the wheel body 212 so as to be symmetrical with respect to each other at an angle, and the center hole 212 a of the wheel body 212 When the wheel body 212 is positioned at the upper left and upper right portions of the wheel body 212, impacts may be applied to each of the electrode plate groups PG through the respective annular discharge holes 212a.

8, the impactor 220 may be symmetrically disposed on the upper portion of the wheel body 212 so that a larger amount of the plate group PG may be connected to the outlet conveyor 300 by a single anti- Or two impacts may be applied to one plate group PG in a state of tilting leftward or rightward to further maximize the efficiency of preventing sticking. Although two pairs of impactors 220 are illustrated in the drawing, in the case where the diameter of the wheel body 212 is large and the number of the electrode plate groups PG loaded on the electrode plate loading member 213 is large, three or more The impactor 220 may be installed.

When the pair of impactors 220 are installed, the pole plate group PG mounted on the pole plate loading member 213 is positioned at the upper left portion and the upper right portion of the wheel body 212, respectively, as shown in FIG. 9 to FIG. The respective punching members 221 are advanced upward through the annular discharge hole 212a of the wheel body 212 by the punching piston advance force of each of the punching cylinders 222, And each of the electrode plates P is raised and separated by the impact.

11, the guide shaft is retracted by the resilient restoring force of the punching spring, and the respective punching members 221 are retracted to below the soft discharge hole 212a of the wheel body 212, The electrode plate group PG is also brought into contact with the outer peripheral surface of the wheel body 212 and aligned. Therefore, by installing the pair of impactors 220, it is possible to supply a larger amount of the plate group PG to the outlet conveyor 300 than when a single impactor 220 is installed through a single anti-adhesion operation, Alternatively, two impacts may be applied to one plate group PG in a state of tilting leftward or rightward to further maximize the efficiency of preventing sticking.

Further, the impact applied by the impactor 220 causes the wearer to fall down from the surface of each of the pole plates P, which falls through the wearer's release hole 212a of the wheel body 212. However, since the fallen burrs may enter the device-joining portions of the respective electrode plate anti-adhesion portions 200 to cause malfunction and breakage of the device, it is preferable that the fallen burrs are installed inside the wheel body 212 as shown in FIGS. 13 and 14 And when the teeth separated from the surfaces of the pole plates P by the impact of the impactor 220 fall through the tooth hole 212a of the wheel body 212, And a burner discharge unit 400 for discharging the laundry to the outside.

Here, the generators 400 include a generators 410, a discharge conveyor 420, and a collection box 430.

13 and 14, the lancet base 410 is installed at a lower portion of the impactor 220 and receives the lancet falling through the lancet hole 212a of the wheel body 212 It performs the function of issuing. As shown in FIG. 13, in the case of the living room receptacle 410, it may be formed into a shape having a wide width in the right and left direction, However, when the soft tooth separated from the surface of each of the electrode plates P falls through the soft tooth discharge hole 212a of the wheel body 212, it is dispersed by the operation of the impactor 220 and the rotation of the wheel body 212 It is easy to catch the falling down when the entrance is formed in a wide shape as shown in Fig.

Next, the discharging conveyor 420 transfers the errata from the ergonomic receiver 410 to the outside. A discharge conveyor 420 is inserted into the burberry 410 to pass the burrow to the discharge conveyor 420 from the burrow receiver 410 and a receiving hole through which the burnt burrow is passed to the discharge conveyor 420 is formed . And the discharge conveyor 420 is transferred by the discharging conveyor 420 to the outside.

Here, the discharge conveyor 420 may be formed as a conveyor to automatically move the kidney as shown in FIGS. 13 and 14, but may also be a downwardly sloping slide structure to reduce the cost of equipment. However, in the case of a slide structure, it is preferable to use a conveyor because the abutment may remain in the slide structure without contacting the slide structure and sliding downward. In addition, when the discharge conveyor 420 is formed by a conveyor, the collection box 430 can be freely installed according to the structure of the space in which the plate transfer and adhesion prevention apparatus according to the present invention is installed.

Lastly, as shown in FIGS. 13 and 14, the collection box 430 collects the laundry transferred from the discharge conveyor 420 so that an operator can collect the laundry. The lifting jacket 430 has a function of collecting the pole plates P separated from the pole plate loading member 213 by the impact of the impactor 220 as well as the soft fall falling through the core hole 212a of the wheel body 212 .

Therefore, the manufactured electrode plate P can be prevented from sticking through the above-described process, and can be aligned and supplied to the battery manufacturing process.

The embodiments of the present invention described above and shown in the drawings should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art will be able to modify the technical idea of the present invention in various forms. Accordingly, such improvements and modifications will fall within the scope of the present invention as long as they are obvious to those skilled in the art.

P: Plate
PG: Plate group
100: inlet conveyor
200:
210: Vertical disc wheel 211: Fixed disc
212: wheel body 212a:
213: electrode plate mounting member 214: rotation motor
220: Impactor
221: Punching member 222: Punching cylinder
300: Outlet conveyor
400: Burner discharge part 410: Burner
420: Discharge conveyor 430: Charge collector

Claims (7)

An inlet conveyor for feeding and transporting an electrode plate group in which a plurality of electrode plates are stacked in a state in which they are horizontally laid with a corrugated board and feeding the electrode plate group from the inlet conveyor to the electrode plates, And an outlet conveyor for feeding the plate group from the plate adhesion preventing portion to the post-process,
The electrode plate anti-
A vertical disc wheel which is shaped like a vertically erected wheel and which receives the plate group from the inlet conveyor through an outer circumference and upwardly rotates and supplies the plate group to the outlet conveyor through the outer circumference of the other side, And an impactor for applying an impact to the electrode plate group to prevent adhesion of the electrode plate when the vertical disk wheel rotates upward,
Wherein the vertical disc wheel comprises:
A pair of stationary disks fixedly installed so as to face each other in a vertically erected state,
A wheel body rotatably installed between the stationary disks in a ring shape erected vertically and having a plurality of annular discharge holes penetratingly formed on an outer circumferential surface thereof,
A plurality of electrode plate stacking members radially protruding from the outer circumferential surface of the wheel body so that the electrode plate group is inserted and loaded;
And a rotating motor for rotating the wheel body.
delete The method according to claim 1,
The impactor includes:
A punching member installed inside the wheel body of the vertical disc wheel and penetrating the annular discharge hole of the wheel body to apply an impact to the pole plate group;
And a punching cylinder for advancing and retracting the punching member toward the upper side of the main discharge hole of the wheel body.
The method of claim 3,
The impactor includes:
Wherein when the annular discharge hole of the wheel body is located at the uppermost end of the wheel body, the electrode array unit applies an impact to the electrode plate group through the annular discharge hole.
The method of claim 3,
The impactor includes:
The pair of pole plates are inclined at a predetermined angle so that a pair of the pair of pole plates are symmetrically disposed on the upper and lower right and left sides of the wheel body, Features of the polar plate feeding and sticking prevention device.
The method according to claim 1,
A wheel body disposed inside the wheel body and adapted to collect the soft tooth dropped when the soft tooth dropped off the surface of each of the pole plates due to the impact of the impactor falls through the soft tooth discharge hole of the wheel body, Further comprising a discharging portion for discharging the electrode.
The method according to claim 6,
Wherein,
A charger socket installed at a lower portion of the impactor to receive the charm falling through the charger discharge hole of the wheel body,
A discharge conveyor for transferring the cornucopia from the cornucopia receiver to the outside,
Further comprising: a collection box for collecting the kidney transferred from the discharge conveyor.

Images