KR102330799B1 - Wasted battery disassembly system - Google Patents

Abstract

The present invention relates to a waste battery disassembling system, and an object of the present invention is to automate the functions of transporting, fixing, cutting, and discharging waste batteries. Specifically, the waste battery disassembling system of the present invention includes a transport unit 110 in which a seating portion of the waste battery 100 is formed; a fixing unit 120 disposed on the transfer unit 110 to fix the waste battery 100 seated on the transfer unit 110; a cutting unit 125 disposed on one side of the fixing unit 120 to remove both sides of the casing of the waste battery 100; and a discharge unit 130 configured on one side of the cutting unit 125 to push and discharge the contents through the opening from which both sides of the casing of the waste battery 100 are removed.

Description

WASTED BATTERY DISASSEMBLY SYSTEM

The present invention relates to a waste battery disassembling system for cutting and removing both sides of a casing from a waste battery, and discharging its internal contents.

Patent Document 001 relates to a waste battery recycling device, and more specifically, through a spray nozzle tube provided at intervals on the inner upper part of the vibrating screen and a rear spray nozzle provided at the inner rear side, the paste, grid, synthetic resin, and separator It relates to a vibrating screen that can smoothly discharge, provided in the lower part of the crasha, and vibrators are provided on both sides, the upper part is fixed to the spring fixing brackets in front and rear of both sides, and the lower part is installed in the installation part of the vibrating screen A plurality of fixed springs are provided, and a rectangular frame body provided with a discharge part in front; a pulverized material chute provided at the upper rear side of the rectangular frame; a cover provided in front of the upper portion of the rectangular frame; a plate screen provided at the lower part of the rectangular frame, which is the lower part of the pulverized material chute; a mesh screen provided in front of the lower front of the pulverized material chute in front of the plate screen; one or more rear jet nozzles provided at the rear of the rectangular frame for discharging the paste, grid, synthetic resin, and separator of the plate screen to the front mesh screen; a plurality of injection nozzle tubes provided at intervals in the horizontal direction in the middle of the rectangular frame for discharging grids, synthetic resins, and separators that are moved to the mesh screen to a front discharge part; technology that includes

Patent Document 002 relates to a waste battery decomposition device capable of efficiently and precisely separating solid components, that is, metal, PE, and PP, and a pulverizing unit for pulverizing the waste battery in which the waste acid has been released, and the waste passing through the pulverizing unit. A screen part that separates the crushed battery into paste and other crushed products according to the particle size through a sieve, a first separator through which the paste that has passed through the screen is extracted with a specific gravity difference with water, and others that have passed through the screen It comprises a second separation part to which the pulverized materials are transported and PP and metal are extracted by a specific gravity difference with water, wherein the second separation part is a place where the pulverized materials that have passed through the screen are accommodated, and a water storage tank; An extraction pipe communicating with the receiving tank from the lower side, a moving screw for inducing the movement of the pulverized material from the receiving tank to the extraction pipe, and a metal extraction provided at the bottom of the extraction pipe and sinking to the bottom of the extraction pipe It is made including a metal extraction part, and the extraction pipe has a shape in which the cross-sectional area becomes narrower toward the middle part from both upper and lower ends, and the aeration is performed in the upper direction through the middle part for a feeling of rapid sharpening of the metal introduced into the extraction pipe from the receiving tank. is presenting

Patent Document 003 discloses a device structure in which manpower reduction and consequent cost reduction can be enjoyed by automating the smelting process for producing high-purity lead, and the automated process is precisely controlled to efficiently obtain pure lead, It relates to a lead smelting apparatus having a lead and a waste battery decomposing apparatus including the apparatus, wherein the smelting apparatus according to the present invention includes a mixing unit for preparing lead input for smelting, and a fusion in which the lead prepared by the mixing unit is put and melted and a refining unit for refining the molten lead, wherein the mixing unit is a place in which lead extracted from a waste battery is stored, a storage tank equipped with a crane device, and the crane device transported by the A hopper equipped with a screw for transferring the inputted lead to the discharge part as a place where lead is introduced, a flight conveyor to which the lead discharged from the discharge part of the hopper is transported, and the lead transferred through the flight conveyor to the melting part It is made including a distribution conveyor for distributing, and the mixture is put into the flight conveyor for a smooth smelting process. After that, it is suggested to be put into the flight kenbeyer.

Patent Document 004 relates to a waste battery recycling device capable of pulverizing a waste packaged battery and a waste bulk battery together and simultaneously dissolving the paste and grid contained in the pulverized product to produce lead ingots by casting, a pre-processing unit for removing and pulverizing the waste packaged battery and the waste bulk battery to separately obtain a paste, a grid, a synthetic resin, and a separator; The main materials of the grid and the paste are fed to the first scraper conveyor through the discharge screw conveyor, and the sub-materials of powdered coal, powdered iron, and soda ash are put into the first scraper conveyor to mix the main and sub-materials with the second scraper conveyor and the input screw. a material supply unit discharging to a conveyor; a melting unit receiving a material supplied through the material supply unit and heating the material to dissolve the material; a kettle for temporarily storing the material after removing the slag of the material tapped from the melting part; A technology including a casting machine that produces lead ingots by receiving the filled material of the kettle through a lead pump is presented.

KR 10-1275937 B1 (Registration Date June 17, 2013) KR 10-1062877 B1 (Registration Date September 07, 2011) KR 10-1108236 B1 (Registration date February 08, 2012) KR 10-1643904 B1 (registration date July 25, 2016)

It is an object of the present invention to automate the transport, fixing, cutting, and discharging functions of the waste battery, to classify the waste battery, stably perform the cutting and discharging function in a state in which it is stably fixed, and to reduce maintenance It is to provide a waste battery disassembly system that can be easily done.

Waste battery disassembly system of the present invention, the transfer unit 110 in which the seating portion of the waste battery 100 is formed; a fixing unit 120 disposed on the transfer unit 110 to fix the waste battery 100 seated on the transfer unit 110; a cutting unit 125 disposed on one side of the fixing unit 120 to remove both sides of the casing of the waste battery 100; and a discharge unit 130 configured on one side of the cutting unit 125 to push and discharge the contents through the opening from which both sides of the casing of the waste battery 100 are removed.

The waste battery disassembling system of the present invention has a corresponding width W corresponding to the size of the waste battery 100 and is disposed on both sides of the transfer unit 110, and the guide inclined surface so that the corresponding width W is small. (165) may further include a guide member 170 formed at a set position on the inner surface side.

In the waste battery disassembly system of the present invention, the fixing unit 120 includes a fixing block 180 disposed to face the upper surface of the waste battery 100; a movable member 185 disposed on the upper surface side of the fixed block 180; an elastic member 190 interposed between the fixed block 180 and the movable member 185; and a movable cylinder 195 for moving the movable member 185 up and down.

In the waste battery disassembling system of the present invention, the discharge unit 130 includes a discharge plunger 235 having a shape corresponding to the opening removed by the cutting unit 125; and a discharge cylinder 240 connected to the discharge plunger 235 and discharging the contents inside the waste battery 100 to the outside.

The waste battery disassembly system of the present invention may further include a rotation unit 260 for rotating the guide member 170 disposed on the side surface of the waste battery 100 to remove interference with the discharge unit 130 . have.

In the present invention, the waste battery is transported using the transfer unit, the waste battery is fixed using the fixing unit, and both sides of the waste battery are cut and removed using the cutting unit, and the waste battery is removed using the discharge unit. The contents can be discharged easily.

According to the present invention, the transport unit can transport the waste battery in a stable state through the structure of the belt, roller, and support block.

In the present invention, the cutting blade of the cutting unit is configured to be replaceable, and the edge portion of the support block is also configured to be replaceable, thereby improving durability and making maintenance easier.

In the present invention, it is possible to classify waste batteries of different sizes on the transfer conveyor using the guide member.

In the present invention, it is possible to smoothly draw in by forming an inclination surface at the tip edge of the discharge plunger.

The above-mentioned effects according to the embodiments of the present invention are not limited to the described content, and further include all effects predictable from the specification and drawings.

1 is a schematic configuration diagram of a waste battery disassembly system according to an embodiment of the present invention.
Figure 2 is a plan view of the transfer unit and the guide member in the embodiment of the present invention.
3 shows the operation of the fixed unit and the cutting unit in the embodiment of the present invention.
4 shows the operation of the discharge unit in the embodiment of the present invention.
5 shows another embodiment of the fixed unit and the cutting unit in the embodiment of the present invention.
6 is a partial perspective view of a waste battery disassembly system in an embodiment of the present invention.
7 shows another embodiment of the discharge unit in the embodiment of the present invention.
8 shows other embodiments of the discharge plunger in the embodiment of the present invention.
9 shows the operation of the rotation unit in the embodiment of the present invention.
10 shows another embodiment of the rotation unit in the embodiment of the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described in detail in order to describe in detail enough that a person of ordinary skill in the art to which the present invention pertains can easily carry out the present invention.

The numbers cited in the examples below are not limited only to the objects of reference, and may be applied to all examples. Objects exhibiting the same purpose and effect as the configuration presented in the examples correspond to equivalent replacement objects. The higher-level concept presented in the examples includes sub-concept objects that are not described.

[Embodiment 1-1] The present invention relates to a waste battery disassembly system, comprising: a transfer unit 110 in which a seating portion of the waste battery 100 is formed; a fixing unit 120 disposed on the transfer unit 110 to fix the waste battery 100 seated on the transfer unit 110; a cutting unit 125 disposed on one side of the fixing unit 120 to remove both sides of the casing of the waste battery 100; and a discharging unit 130 configured on one side of the cutting unit 125 to push and discharge the contents through the opening from which both sides of the casing of the waste battery 100 are removed.

The scale of the secondary battery industry is rapidly increasing, and accordingly, research on the treatment of used and discarded batteries is being conducted. In general, a battery consists of a casing, battery cells disposed inside the casing, and electrodes provided inside and outside the casing to conduct electricity with the outside and the battery cells. and discharge the contents through the cut opening to separate the casing and contents. However, the casing is formed of an aluminum material, which is harmful to the operator, and studies on automation of these tasks are being conducted.

In the present invention, the operation of transferring the waste battery using the transfer unit, fixing the waste battery using the fixing unit, removing the casings on both sides of the waste battery using the cutting unit, and discharging the contents using the discharge unit to automate Therefore, it is possible to protect the worker from heavy metals scattered during the decomposition process of the waste battery and to regenerate the waste battery to protect the global environment.

[Embodiment 1-2] The present invention relates to a waste battery disassembling system. In Embodiment 1-1, the conveying unit 110 may be a conveyor composed of a belt 135 and a roller 600 .

[Embodiment 1-3] The present invention relates to a waste battery disassembly system. In Embodiment 1-2, a support block 140 for supporting the lower surface of the belt 135; may further include.

In the present invention (refer to FIGS. 2 to 6), the conveying unit for transferring the waste battery has a conveyor structure, which includes a roller 600 (FIG. 6) and a belt wound thereon, and the waste battery is mounted on the upper surface of the belt. face) and move

In addition, a support block is further formed on the lower surface of the belt, and the support block supports the load of the waste battery and can stably support the waste battery while the fixing unit presses the upper surface of the waste battery downward. In addition, the conveyor may be stopped in a state in which the waste battery is fixed. Additionally, in FIG. 6 , a slot 610 and a slot protrusion 620 are further formed. The slot is formed vertically in a portion extending downwardly from both ends of the movable member, and the slot protrusion is shown in FIGS. 5 and 6 . As shown, it is formed to protrude from the side of the fixing block 180 . Through this structure, the fixed block is prevented from falling while the movable member is raised.

[Embodiment 1-4] The present invention relates to a waste battery disassembly system. In Embodiment 1-3, a block groove 145 is formed on the upper surface of the support block 140, and the belt 135 A belt protrusion 150 inserted into the block groove 145 may be formed on the lower surface.

[Embodiment 1-5] The present invention relates to a waste battery disassembly system. In Embodiments 1-4, the block groove 145 and/or the belt protrusion 150 may be formed in the movement direction of the belt. have.

In the present invention (refer to FIGS. 2 to 6), the belt slides on the upper surface of the support block by rotation of the roller, and a structure is required in which the belt moves the upper surface of the support block stably.

Accordingly, a block groove may be formed on the upper surface of the support block in the conveying direction, and a belt protrusion may be formed on the lower surface of the belt in the conveying direction to correspond to the block groove. In this embodiment, the block grooves are preferably formed continuously in the conveying direction, and the belt projections may be formed at intervals. In addition, although the block groove and the belt protrusion are formed one by one, they may be formed side by side with an interval therebetween.

[Embodiment 1-6] The present invention relates to a waste battery disassembly system. In Embodiments 1-3, one edge of the support block 140 is detachably attached to a position corresponding to the cutting unit 125. an edge member 155 to be fastened; can be formed.

In the present invention (refer to FIG. 5), the cutting unit cuts the casing on both sides of the waste battery while the fixing unit presses the upper surface of the waste battery, and at this time, the support block supports the lower surface of the waste battery. At this time, the edge portion of the support block may be damaged by repeatedly applying a large pressing force. Therefore, in the present embodiment, the edge members that can be reassembled at both corners of the support block are configured. Through this edge member, the durability of the support block can be improved.

[Embodiment 1-7] The present invention relates to a waste battery disassembly system. In Embodiment 1-1, the casing of the waste battery 100 may be made of an aluminum material.

[Embodiment 1-8] The present invention relates to a waste battery disassembling system. In Embodiment 1-1, at least one side of both sides of the waste battery 100 cut by the cutting unit 125 has electrical input and output An electrode may be formed.

In the present invention, the waste battery is an aluminum casing, and a battery cell is disposed therein, and the battery cell may contain lead, nickel-cadmium, nickel-hydrogen, and lithium, and the waste battery is immersed in salt water for a predetermined time. It will be disassembled in a state where electricity production capacity has been removed. In addition, a copper electrode for electric input/output may be formed in a portion cut from the casing of the waste battery cell.

[Embodiment 2-1] The present invention relates to a waste battery disassembling system. In Embodiment 1-1, the transfer unit 110 having a corresponding width W corresponding to the size of the waste battery 100 a guide member 170 disposed on both sides of, and formed at a position where the guide inclined surface 165 is set so that the corresponding width W is reduced on one side; may further include.

In the present invention (refer to FIG. 2), the transfer unit is constituted by a conveyor belt, and guide members are constituted on both sides thereof. In the drawing, the guide member 700 is divided into first, second, and third guide members 700a, b, and c.

In addition, the guide member has two characteristics. One is the corresponding width W and the guide inclined surface 165 corresponding to the width of the battery. This corresponding width corresponds to the width of the waste battery, and the guide inclined surface guides the movement of the waste battery to move the waste battery to a set position, and it is possible to classify the transport position of the waste battery by size.

[Embodiment 2-2] The present invention relates to a waste battery disassembling system. In Embodiment 2-1, the guide member 170 includes at least two products disposed in the transport direction of the waste battery 100. 1 and 2 guide members 170a and b may be included.

[Embodiment 2-3] The present invention relates to a waste battery disassembly system. In Embodiment 2-2, the guide inclined surfaces 165 are formed on one side of the first and second guide members 170a and b, respectively. can be

In the present invention (see Fig. 2), when the waste battery moves along the conveyor belt, the waste battery is positioned by the guide inclined surface. A waste battery of a large size is positioned on the first guide member 170a, a waste battery of a medium size is positioned on the second guide member 170b, and a waste battery of a small size is positioned on the third guide member 170c. can In the present invention, the guide member is composed of three, but is composed of two or four or more, so that the present invention can process waste batteries of various sizes.

[Embodiment 2-4] The present invention relates to a waste battery disassembling system. In Embodiment 2-2, the transfer unit 110 has at least two corresponding to the first and second guide members 170a and b. It may include two first and second transfer units (110a, b).

In the present invention (see FIG. 2), the guide member 700 includes the first, second, and third guide members 700a, b, and c. Accordingly, the transfer unit 110 includes the first, second, and third transfer units. (110a, b, c). These transfer units can be driven individually. For example, while the first transfer unit is operated, the second transfer unit or the third transfer unit may be stopped. The fixing unit corresponding to the second and third transfer units may perform an operation of fixing the waste battery, the cutting unit cutting both sides of the casing to remove it, and the discharging unit removing the contents.

[Embodiment 3-1] The present invention relates to a waste battery disassembly system. In Embodiment 1-1, the fixing unit 120 includes a fixing block ( 180); a movable member 185 disposed on the upper surface side of the fixed block 180; an elastic member 190 interposed between the fixed block 180 and the movable member 185; and a movable cylinder 195 for moving the movable member 185 up and down; may include.

In the present invention (refer to FIG. 3), a belt is disposed on the support block, a waste battery is disposed on the belt, a fixed block is disposed on the upper surface of the waste battery, a movable member is disposed on the stationary block, and a movable cylinder holds the movable rod. It has a structure that presses the movable member downward through it. Here, the elastic member is interposed between the movable member and the fixed block. Substantially, the elastic member has a structure for elastically pressing the fixing block to the waste battery.

[Embodiment 3-2] The present invention relates to a waste battery disassembling system. In Embodiment 3-1, the upper surface of the fixing block 180 has a seating groove 200 in which the elastic member 190 is seated. can be formed.

[Embodiment 3-3] The present invention relates to a waste battery disassembling system. In Embodiment 3-1, the cutting unit 125 includes the movable member 185 corresponding to both sides of the fixed block 180 . ) cutting blades 205 disposed in portions extending downward from both ends; may include.

In the present invention (see Fig. 3), a seating groove is formed in the center of the upper surface of the fixing block, and the lower end of the elastic member is drawn into the seating groove. An upper end of the elastic member may contact a lower surface of the movable member. Both ends of the movable member extend downward, and a cutting blade of the cutting unit is formed at the lower end thereof. The cutting blades are disposed on both sides of the fixed block, and come down together with the movable member to cut and remove the casings on both sides of the waste battery.

[Embodiment 3-4] The present invention relates to a waste battery disassembly system. In Embodiment 3-1, the cutting unit 125 is a cutting blade that is reassembled to one side of the movable member 185 and is fastened to one side. (205); may include.

In the present invention (see FIG. 5), the cutting blades are assembled to the lower ends of both sides of the movable member, and when the cutting blades become dull, the cutting blades can be removed and replaced with new ones. Here, the cutting blade may be fastened to the lower end of the movable member by a bolt. This reassemblyable cutting blade can have different specifications depending on the material or size of the waste battery, and can improve overall durability and maintenance convenience.

[Embodiment 3-5] The present invention relates to a waste battery disassembly system. In Embodiment 3-1, the movable cylinder 195 and the movable member 185 are configured in a movable rod 210 connecting the movable member 185 A load cell 215 may be further included.

[Embodiment 3-6] The present invention relates to a waste battery disassembling system. In Embodiment 3-5, the controller 225 includes the transfer unit 110 according to a signal detected by the load cell 215, It is possible to control the operation of the fixing unit 120 , the cutting unit 125 , and/or the discharge unit 130 .

In the present invention (see FIG. 6 ), the movable cylinder moves the movable member downward through the movable rod, and the movable rod further includes a load cell. This load cell can sense the pressing force applied to the movable rod in real time. The controller can determine whether the waste battery is fixed according to the magnitude of the load signal sensed by the load cell, and control the operation of the movable cylinder to simultaneously control the cutting operation. The controller may also control the operation of the discharge unit according to the detection signal.

[Embodiment 3-7] The present invention relates to a waste battery disassembly system. In Embodiment 3-1, a distance sensor 220 mounted on the movable member 185 or the fixed block 180; may further include.

[Embodiment 3-8] The present invention relates to a waste battery disassembling system. In Embodiment 3-7, the controller 225 includes the transfer unit 110 according to a signal detected by the distance sensor 220, It is possible to control the operation of the fixing unit 120 , the cutting unit 125 , and/or the discharge unit 130 .

In the present invention (see FIG. 6), the movable cylinder moves the movable member downward through the movable rod, and a distance sensor is further configured on the front side of the fixed block. The distance sensor can indirectly calculate the thickness of the waste battery by sensing the distance between the upper surfaces of the belt. The controller can determine whether the waste battery is fixed according to the size of the distance signal detected by the distance sensor, and control the operation of the movable cylinder to simultaneously control the cutting operation. The controller may also control the operation of the discharge unit according to the detection signal.

[Embodiment 3-9] The present invention relates to a waste battery disassembling system. In Embodiment 3-1, a fixing protrusion 230 may protrude from the lower surface of the fixing block 180 .

[Embodiment 3-10] The present invention relates to a waste battery disassembling system. In Embodiment 3-7, the fixing protrusions 230 are arranged at a set interval on the lower surface of the fixing block 180 at a set interval. can be

In the present invention (see FIG. 5), a small-sized fixing protrusion is formed to protrude from the lower surface of the fixing block, and the fixing protrusion is dug into the upper surface of the waste battery while forming a groove. Accordingly, the fixing block can stably limit the movement of the waste battery through the fixing protrusion. In particular, when the discharge unit enters the waste battery in the lateral direction, the waste battery may be moved by a load applied in the lateral direction, and the fixing protrusion may eliminate this side effect.

[Example 4-1] The present invention relates to a waste battery disassembling system. In Example 1-1, the discharge unit 130 has a shape corresponding to the opening removed by the cutting unit 125. having a discharge plunger 235; and a discharge cylinder 240 connected to the discharge plunger 235 and discharging the contents inside the waste battery 100 to the outside; may include.

In the present invention (see Fig. 7), the cutting blade cuts the casing on both sides of the waste battery, and the movable cylinder raises the cutting blade together with the movable member. Then, the discharge cylinder advances the discharge plunger, and the discharge plunger is inserted into the casing through the opening of the casing to discharge the contents (battery cell part) inside the casing to the outside. Here, it is preferable that the discharge plunger has a rectangular cross section according to the shape of the waste battery.

[Embodiment 4-2] The present invention relates to a waste battery disassembling system, and in Embodiment 4-1, an inlet inclined surface 245 may be formed along a corner at the distal end of the discharge plunger 235 .

[Embodiment 4-3] The present invention relates to a waste battery disassembling system. In Embodiment 4-1, the outer surface of the inlet inclined surface 245 may be circular, curved, and/or straight.

In the present invention (refer to FIG. 8), an inlet inclined surface is formed along the tip edge of the discharge plunger, and the inlet inclined surface is formed along a circular curve as shown in (a), or has a long straight shape as shown in (b). , may have a chamfer shape as in (c). If there is no inlet slope, when the discharge plunger is drawn into the opening of the casing, the discharge plunger may be caught by the casing and the discharge operation may be stopped.

[Embodiment 4-4] The present invention relates to a waste battery disassembling system. In Embodiment 4-3, a nozzle 250 for ejecting the gas supplied from the outside is formed on the outer surface of the discharge plunger 235 can be

[Embodiment 4-5] The present invention relates to a waste battery disassembling system. In Embodiment 4-3, a nozzle 250 for ejecting a gas supplied from the outside may be formed on the inlet inclined surface 245 .

In the present invention (see FIGS. 7 and 8 ), when the discharge plunger is drawn into the casing, frictional heat may be generated by compressing the contents between the contents and the inlet inclined surface, which should be eliminated. Accordingly, in this embodiment, a nozzle is formed on the outer surface and/or the inlet inclined surface of the discharge plunger, and gas (air) is supplied to the nozzle side. Therefore, the air sprayed from this nozzle reduces frictional heat, a cleaning effect inside the casing can be expected, and foreign substances inside the casing can be effectively removed.

[Embodiment 4-6] The present invention relates to a waste battery disassembling system. In Embodiment 4-1, one side of the discharge plunger 235 has a cleaning member ( 255) may be further formed.

[Embodiment 4-7] The present invention relates to a waste battery disassembling system. In Embodiment 4-1, the cleaning member 255 may have a brush structure.

In the present invention (refer to (c) of FIG. 8), an inlet inclined surface is formed along the tip edge of the discharge plunger, a gas injection nozzle is formed on the inlet inclined surface, and a cleaning member is further formed along the rear end edge of the discharge plunger However, the cleaning member may have a brush structure. This cleaning member can cleanly remove the battery contents attached to the surface of the casing inside like a light stalk. In addition, the cleaning member may be detachably mounted to the discharge plunger.

[Example 5-1] The present invention relates to a waste battery disassembling system. In Example 2-1, by rotating the guide member 170 disposed on the side of the waste battery 100, the discharge unit ( 130) and a rotation unit 260 to remove the indirection; may further include.

In the present invention, as shown in FIG. 2, guide members are disposed on both sides of the transfer unit, and the waste batteries are classified by size. Then, the fixing unit fixes the waste battery, and the cutting unit removes the casings on both sides of the waste battery at the same time. In addition, the discharge unit is driven from the side of the discharge unit, at this time, the guide member must be removed.

In this embodiment, the rotation unit rotates the guide member to move from the side to the upper side of the waste battery, thereby eliminating interference with the discharge plunger.

[Embodiment 5-2] The present invention relates to a waste battery disassembling system. In Embodiment 5-1, the rotation unit 260 may move the guide member 170 through a link structure.

[Example 5-3] The present invention relates to a system for disassembling a waste battery. In Example 5-1, the link structure comprises:

a rotation link 265 arranged to rotate around a rotation hinge 305, one end connected to the guide member 170; and

a link rotation member 270 configured on one side of the fixed unit 120 or the cutting unit 125 and configured to rotate the other end of the rotation link 265 in a descending operation; may include.

In the present invention (see Fig. 9), the link structure includes a rotating hinge, a rotating link, and a link rotating member. First, link rotation members are formed on both sides of the fixing member. The link rotation member is further formed with a rotation projection downward. Then, a rotation link is rotatably arranged around the rotation hinge, and the guide member is connected to one end of the rotation link. When the fixed block descends, the link rotation member descends and presses the other end of the rotation link downward to rotate the rotation link. Then, the guide member coupled to one end of the rotary link rotates around the rotary hinge. Accordingly, the problem of interference between the discharge plunger and the guide member is solved.

[Embodiment 5-4] The present invention relates to a waste battery disassembling system. In Embodiment 5-1, the rotary link 265 and/or the guide member 170 to return the guide member 170 ) a return elastic member 285 for elastically supporting one side; may further include.

[Embodiment 5-5] The present invention relates to a waste battery disassembling system. In Embodiment 5-3, the link rotation member 270 may include a rotation protrusion 275 .

[Embodiment 5-6] The present invention relates to a waste battery disassembly system. In Embodiment 5-5, the other end of the rotation link 265 has a rotation groove 280 corresponding to the rotation projection 275. can be formed.

In the present invention (see FIG. 9), link rotation members are formed on both sides of the fixing member. A rotation protrusion is further formed in the lower portion of the link rotation member, and a rotation groove is further formed at the other end of the rotation link. Accordingly, when the fixed block descends, the rotation protrusion of the link rotation member descends and presses the rotation groove of the rotation link downward to rotate the rotation link. Then, the guide member coupled to one end of the rotary link rotates around the rotary hinge, thereby solving the problem of interference between the discharge plunger and the guide member.

[Embodiment 5-7] The present invention relates to a waste battery disassembly system. In Embodiment 5-1, the rotation unit 260 may rotate the guide member 170 through a gear structure.

[Embodiment 5-8] The present invention relates to a waste battery disassembling system. In Embodiment 5-1, the gear structure is arranged to rotate around a rotary hinge 305, and a driven gear 295 has an outer peripheral surface. ) is formed, the rotational gear member 290 connected to the guide member 170 through the connecting bar (310); and a driving gear 300 formed on one side of the fixed unit 120 and/or the cutting unit 125 so as to be in contact with the driven gear 295; may include.

In the present invention (see FIG. 10), the rotation gear member is rotatably disposed around the rotation hinge, and a driven gear is formed on the outer peripheral surface of the rotation gear member. In addition, cutting blades are formed under both ends of the movable member, and driving gears are formed in the vertical direction on the outer surface side of the cutting blade. In this embodiment, when the movable cylinder lowers the movable member, the driving gear and the cutting blade are lowered, and the driving gear is engaged with the driven gear of the rotational gear member to rotate the rotational gear member by a set angle.

A connecting arm is fixed to one side of the rotation gear member, and the front end of the connecting box is coupled to the guide member. Accordingly, when the driving gear rotates the rotation gear member through the driven gear, the guide member rotates around the rotation hinge, thereby solving the problem of interference with the discharge plunger.

100: waste battery 101: casing
102: contents 105: seating surface
110: transfer unit 110a, b, c: first, second, third transfer unit
120: fixed unit 125: cutting unit
130: discharge unit 135: belt
600: roller 140: support block
145: block groove 150: belt projection
155: edge member W: corresponding width
165: guide inclined surface 170: guide member
170a, b, c: first, second, third guide member 180: fixed block
185: movable member 190: elastic member
195: movable cylinder 200: seating groove
205: cutting blade 210: movable rod
215: load cell 220: distance sensor
225: controller 230: fixing projection
235: discharge plunger 240: discharge cylinder
245: inlet slope 250: nozzle
255: cleaning member 260: rotation unit
265: rotation link 270: link rotation member
275: rotation projection 280: rotation groove
285: return elastic member 290: rotation gear member
295: driven gear 300: driving gear
305: rotary hinge 310: connecting bar
610: slot 620: slot turn

Claims (5)

a transfer unit 110 in which a seating portion of the waste battery 100 is formed;
a fixing unit 120 disposed on the transfer unit 110 to fix the waste battery 100 seated on the transfer unit 110;
a cutting unit 125 disposed on one side of the fixing unit 120 to remove both sides of the casing of the waste battery 100; and
A discharge unit 130 configured on one side of the cutting unit 125 so as to push and discharge the contents through the opening in which both sides of the casing of the waste battery 100 are removed.
The transfer unit 110 is formed in a conveyor structure consisting of a belt 135 and a roller 600,
It further includes; a support block 140 for supporting the lower surface of the belt 135;
and an edge member 155 detachably fastened to a position corresponding to the cutting unit 125 on one edge side of the support block 140 ,
The fixing unit 120,
a fixing block 180 disposed to face the upper surface of the waste battery 100;
a movable member 185 disposed on the upper surface side of the fixed block 180;
an elastic member 190 interposed between the fixed block 180 and the movable member 185; and
and a movable cylinder 195 for moving the movable member 185 up and down.
The fixing block 180 is
It includes a; includes a;
a movable rod 210 connecting the movable cylinder 195 and the movable member 185 and having a load cell 215 formed therein; and
Lung further comprising; battery disassembly system.
According to claim 1,
It has a corresponding width (W) corresponding to the size of the waste battery (100) and is disposed on both sides of the transfer unit (110), and on one side, the guide inclined surface (165) is set so that the corresponding width (W) is small. The guide member 170 is formed;
Waste battery disassembly system, characterized in that it further comprises.
delete According to claim 1,
The discharge unit 130,
a discharge plunger 235 having a shape corresponding to the opening removed by the cutting unit 125; and
a discharge cylinder 240 connected to the discharge plunger 235 and discharging the contents inside the waste battery 100 to the outside;
Waste battery disassembly system comprising a.
3. The method of claim 2,
a rotation unit 260 for removing interference with the discharge unit 130 by rotating the guide member 170 disposed on the side of the waste battery 100;
Waste battery disassembly system, characterized in that it further comprises.

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