KR20210003616A - Cathode module and a metal product retrieval apparatus including the same - Google Patents

Abstract

The present invention relates to a cathode module that does not have a risk of damage to a fastening part due to corrosion or thermal deformation, and a metal transformant recovery device including the same. More particularly, according to an embodiment of the present invention, provided is a cathode module comprising: a first conduction module through which a current received from the outside can flow; a basket capable of containing a metal oxide; a second conduction module through which a current for reducing the metal oxide can flow; and a fastening unit driven to selectively contact an upper surface of the second conduction module by moving in one direction to prevent the second conduction module from arbitrarily departing from the first conduction module.

Description

Cathode module and metal converting body recovery device including the same

The present invention relates to a cathode module and a metal conversion material recovery apparatus including the same.

Electrochemical processes can be used to recover metals from impure raw materials or to extract metals from metal oxides. In particular, the electrochemical electrolytic reduction process generates a reduction potential in a cathode module including a basket containing an oxide raw material such as a metal oxide, so that oxygen is dissolved as oxygen ions in the molten salt electrolyte. Accordingly, the metal oxide is converted to metal and remains in the basket of the cathode module. The electrolytic reduction process using such a high-temperature molten salt is applied to a metal conversion process of various metal oxides (TiO2, Ta2O5, UO2, etc.). For example, in the electrolytic reduction process, the metal oxide may be uranium dioxide (UO2), and the reduction product may be uranium metal.

In the conventional electrolytic reduction process, the entire cathode module was used in the next process without separating the metal conversion material converted through the electrolytic reduction process from the basket of the cathode module, and accordingly, the size of the device was large to accommodate the entire cathode module. I lost. In addition, when a process of higher temperature than electrolytic reduction, such as distillation, is performed, the electrolyte salt remaining in the basket and a mesh made of stainless steel react, resulting in material damage.

To solve this problem, the metal conversion body converted through the electrolytic reduction process was separated from the basket of the cathode module for the next process and transferred to a separate recovery container for processing. However, when assembling the cathode module, the upper conductor and the lower conductor fixed to the basket in an insulated state must be firmly fastened to reduce the electrical contact resistance.In the conventional cathode module structure, a manual manipulator is used to fasten it. There was a limit to applying a strong fastening force. In addition, when the fastening portion is deformed or damaged by exposure to high-temperature corrosive gases in the electrolytic reduction process for a long time, there have been cases where separation itself is impossible.

Embodiments of the present invention are invented with the above background in mind, and a cathode module capable of separating and combining the upper conductor and the lower conductor fixed to the basket in an insulated state using a power source, and a metal conversion body including the same To provide a recovery device.

In addition, to provide a cathode module and a metal conversion body recovery device including the same, there is no risk of damage to the fastening portion due to corrosion or thermal deformation.

According to an aspect of the present invention, a first conduction module through which current received from the outside can flow; A basket capable of receiving a metal oxide; A second conduction module through which a current for reducing the metal oxide can flow; And a fastening unit that moves in one direction and is driven to selectively contact an upper surface of the second conduction module in order to prevent the second conduction module from being arbitrarily separated from the first conduction module. have.

According to embodiments of the present invention, there is an effect that the upper conductor and the lower conductor fixed to the basket in an insulated state are not manually fastened, but can be separated and combined using a power source.

In addition, there is an effect that there is no risk of damage to the fastening part by corrosion or thermal deformation.

1 is a perspective view of a metal conversion body recovery apparatus according to an embodiment of the present invention.
2 is a perspective view of the cathode module of FIG. 1.
3 is an exploded perspective view of the cathode module of FIG. 2.
4 is an enlarged view of a first conductive coupling portion of the cathode module of FIG. 2.
5 is a cross-sectional view taken along line A-A' of FIG. 2.
6 is a cross-sectional view taken along line B-B' of FIG. 2.
7 is an exploded perspective view of the separation unit of FIG. 1.
8 is a plan view of the metal conversion body recovery device of FIG. 1.
9 is a side view of the metal conversion body recovery device of FIG. 1.

Hereinafter, specific embodiments for implementing the spirit of the present invention will be described in detail with reference to the drawings.

In addition, when it is determined that a detailed description of a known configuration or function related to the present invention may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, when it is mentioned that an element is'connected','supported','contacted', or'coupled' to another element, it may be directly connected, supported, contacted, or coupled to the other element, but other elements in the middle. It should be understood that elements may exist.

The terms used in the present specification are used only to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In addition, terms including ordinal numbers such as first and second may be used to describe various elements, but the corresponding elements are not limited by these terms. These terms are only used for the purpose of distinguishing one component from another.

The meaning of "comprising" as used in the specification specifies a specific characteristic, region, integer, step, action, element and/or component, and other specific characteristic, region, integer, step, action, element, component and/or group It does not exclude the existence or addition of

In addition, in the present specification, expressions such as upper, lower, upper, and lower are described based on the drawings in the drawings, and it should be noted in advance that if the direction of the corresponding object is changed, they may be expressed differently. Meanwhile, in the present specification, the vertical direction may be the z-axis direction of FIGS. 1 and 8. In addition, the first direction may be the -x-axis direction of FIGS. 7 and 8, and the second direction may be the +x-axis direction of FIGS. 7 and 8.

Hereinafter, a specific configuration of the metal conversion body recovery apparatus 1 according to an embodiment of the present invention will be described with reference to the drawings.

Hereinafter, referring to FIG. 1, the metal conversion body recovery apparatus 1 according to an embodiment of the present invention separates the cathode module 100 that has undergone an electrolytic reduction process using power, and recovers the metal conversion body. have. This metal conversion body recovery device 1 includes a cathode module 100, a frame 200, a separation unit 300, a lift unit 400, a rotation unit 500, a collection container 600, and a conveyor 700. Can include.

The cathode module 100 may be used in an electrochemical process for extracting metal from metal oxide or recovering metal. The negative electrode module 100 may accommodate an oxide material such as a metal oxide, and a part of the negative electrode module 100 may be introduced into the molten salt electrolyte. In addition, a part of the cathode module 100 may allow current to flow, and current transmitted from the outside may reduce metal oxides. The molten salt electrolyte may pass through the portion where the metal oxide is accommodated in the cathode module 100, and the metal oxide may be converted into metal by a reduction potential and remain in the cathode module 100. The cathode module 100 includes a first conduction module 110, a second conduction module 120, a basket 130, a fastening unit 140, an insulating part 150, and a lifting pin 160. I can.

Referring further to FIG. 2, a current received from the outside may flow through the first conduction module 110. This first conduction module 110 may be a conductor. In addition, the first conductive module 110 may include a first conductive body 111, a first conductive coupling part 112, and a through hole 113.

The first conductive body 111 may flow a current received from the outside, and the current received from the outside may be transferred to the second conductive module 120. The first conductive body 111 may be supported by the frame 200 and may support the second conductive module 120. In addition, the lifting pin 160 to be described later may be connected to the first conductive body 111.

With further reference to FIGS. 3 and 4, the first conductive coupling part 112 may provide a portion in which the second conductive module 120 is supported by the first conductive module 110. The first conductive coupling part 112 may be formed by being inserted into one side of the first conductive module 110. In addition, the second conductive module 120 may be inserted inside the first conductive coupling part 112. The first conductive coupling portion 112 may include a support portion 112a, a coupling portion groove 112b, and a coupling portion jaw 112c.

The support part 112a may provide a portion for supporting the second conduction module 120. The support part 112a may contact the locking part 122 of the second conduction module 120 to be described later.

The coupling part groove 112b may provide a space into which the second conduction module 120 is inserted. In other words, the second conduction module 120 may be inserted into the coupling portion groove 112b and supported by the support portion 112a.

The coupling portion chin 112c may be inserted into the coupling portion groove 112b to prevent the second conduction module 120 supported by the support part 112a from being arbitrarily separated from the first conduction module 110. The coupling portion chin 112c may protrude from the support portion 112a. For example, the coupling portion chin 112c may be formed to protrude from the support portion 112a higher than the thickness of the locking portion 122 to be described later.

The through hole 113 may provide a space for moving the fastening unit 140 to be described later. The through hole 113 may be formed to penetrate from one surface of the first conductive body 111 to the other surface of the first conductive body 111.

The second conduction module 120 may flow a current received from the first conduction module 110. In other words, a current for reducing a metal oxide inside the basket 130 to be described later may flow through the second conduction module 120. This second conduction module 120 may be a conductor. In addition, the second conduction module 120 may include a second conduction body 121, a locking part 122, and a fastening part 123.

The second conductive body 121 may flow the current received from the first conduction module 110, and the current received from the first conduction module 110 may flow into the basket 130.

3 and 4, the locking part 122 may provide a portion in which the second conduction module 120 is supported by the first conduction module 110. The locking part 122 may be inserted into the coupling part groove 112b and may be supported in contact with the support part 112a. In addition, the locking part 122 may be prevented from being separated from the first conduction module 110 by the coupling part chin 112c. For example, the shape of the locking portion 122 may be a plate shape, and the thickness of the plate-shaped locking portion 122 may be formed to be lower than the height of the coupling portion jaw 112c. The locking part 122 may be pressed by a load pin 144 to be described later in order to prevent separation from the first conduction module 110. In addition, the locking part 122 may be connected to the second conductive body 121.

The fastening part 123 may be connected to the second conductive body 121, and may be connected to the basket 130 through a first insulating member 152 to be described later. A fastening groove 123a capable of supporting a second insulating member 153 to be described later may be formed in the fastening part 123. The fastening groove 123a may be formed by being inserted into a predetermined depth from the surface of the fastening part 123. In addition, a hole into which a connecting member 151 to be described later may be inserted may be formed in the fastening groove 123a. For example, a plurality of fastening grooves 123a may be formed on the surface of the fastening part 123, and holes may be formed in each of the plurality of fastening grooves 123a.

The basket 130 may contain an oxide raw material such as a metal oxide required for conversion of a metal converter. The basket 130 may be introduced into a molten salt electrolyte to reduce metal oxides in the electrolytic reduction process. In addition, a basket body 131 and a basket net 132 may be included.

The basket body 131 may support an oxide material such as a metal oxide. In other words, a reduction potential is generated inside the basket body 131 so that the metal oxide is converted into a metal conversion body, and the converted metal conversion body may remain inside the basket body 131. The basket body 131 may be connected to the fastening part 123. In addition, a plurality of holes into which the connecting member 151 may be inserted may be formed in the basket body 131. The plurality of holes of the basket body 131 may be formed to correspond to the plurality of holes of the fastening part 123.

The basket net 132 may surround the metal oxide supported on the basket body 131. In other words, the basket net 132 may be connected to the basket body 131 to provide a space in which metal oxides are accommodated together with the basket body 131. The basket network 132 may be introduced as a molten salt electrolyte, and may be provided in the form of a mesh in order to contact the molten salt electrolyte and the metal oxide. In other words, the molten salt electrolyte may pass through the basket network 132, and the metal oxide may be reduced in the basket 130.

3 and 6, when the second conduction module 120 is supported by the first conduction module 110, the fastening unit 140 includes the second conduction module 120 and the first conduction module 110. It can be driven to be placed in a fastened state that can prevent any deviation from it. In addition, the fastening unit 140 may selectively contact the locking portion 122 by a separation unit 300 to be described later, and may press the locking portion 122. The fastening unit 140 may be driven to prevent the second conduction module 120 from being arbitrarily separated from the first conduction module 110 by the contact between the fastening unit 140 and the locking part 122. In addition, the fastening unit 140 may include a rotation gear 141, a first threaded member 142, a second threaded member 143, a load pin 144 and a stopper 145.

The rotation gear 141 may be connected to the separation unit 300 and may be rotated by the separation unit 300. In other words, the rotation gear 141 may be selectively engaged with the idle gear 330 to be described later, and may be rotated by the idle gear 330. In addition, the rotation gear 141 may be connected to the first threaded member 142, and may be rotated to rotate the first threaded member 142. This rotation gear 141 may be supported on one surface of the first conductive body 111.

The first threaded member 142 may be connected to the rotation gear 141, and when the rotation gear 141 rotates, it may rotate in response to the rotation of the rotation gear 141. Male threads may be formed on the outer surface of the first threaded member 142. For example, the first threaded member 142 may be a screw or a bolt. In addition, the first threaded member 142 may be disposed inside the through hole 113. The first threaded member 142 is engaged with the second threaded member 143 to move the rod pin 144 forward and backward in one direction.

The second threaded member 143 may move in one direction from the inside of the through hole 113. A female thread capable of engaging with a male thread formed on an outer surface of the first threaded member 142 may be formed on the inner surface of the second threaded member 143. For example, the second threaded member 143 may be a nut. In addition, the shape of the cross section of the second threaded member 143 may correspond to the shape of the cross section of the portion in which the through hole 113 contacts the second threaded member 143. For example, the shape of the cross section of the second threaded member 143 and the shape of the cross section of the portion in which the through hole 113 contacts the second threaded member 143 may be a shape in which a portion is cut from a polygon or circle. have. The second threaded member 143 may move in the vertical direction by rotation of the first threaded member 142. In other words, when the first threaded member 142 engaged with the second threaded member 143 rotates, the second threaded member 143 can move vertically along the thread without rotating by the through hole 113. have.

Referring to FIG. 4, the load pin 144 may move in one direction to selectively contact the locking part 122. The load pin 144 may be connected to the second threaded member 143 and may move integrally with the second threaded member 143. In other words, the second threaded member 143 moves in one direction by the rotation of the first threaded member 142, and the rod pin 144 is locked by the movement of the second threaded member 143 It may move toward and contact the locking part 122. For example, in order to reduce the electrical contact resistance between the first conduction module 110 and the second conduction module 120, the load pin 144 presses the locking part 122 to prevent the first conduction module 110 and the second conduction module 110. 2 The conduction module 120 can be fastened. In addition, when the rotation direction of the first threaded member 142 is changed, the movement direction of the second threaded member 143 may be changed, and the movement direction of the load pin 144 is also changed, so that the load pin 144 is engaged with the locking part 122 ) Can be separated from

The stopper 145 may prevent the first threaded member 142 from being separated from the first conductive body 111 when the first threaded member 142 rotates with respect to the second threaded member 143. In other words, referring to FIG. 6, when the first threaded member 142 rotates with respect to the second threaded member 143, the flange portion protruding from the first threaded member 142 is caught by the stopper 145. , The stopper 145 may prevent the first threaded member 142 from moving upward. Even if the first threaded member 142 rotates with respect to the second threaded member 143 by the stopper 145, the first threaded member 142 does not move upward, while the second threaded member 143 is lower You can move in any direction.

The insulating part 150 may connect the basket 130 and the second conduction module 120, and may insulate the basket 130 and the second conduction module 120. The insulating part 150 may include a connecting member 151, a first insulating member 152 and a second insulating member 153.

The connecting member 151 may connect the fastening part 123, the first insulating member 152, the second insulating member 153, and the basket body 131. The connecting member 151 may be inserted into a plurality of holes formed in the fastening part 123, the first insulating member 152, the second insulating member 153, and the basket body 131. For example, the connection member 151 may be a bolt. This connecting member 151 is connected to the fastening part 123 to connect the fastening part 123 and the basket body 131 while preventing current from being transmitted from the fastening part 123 to the basket body 131. It may be spaced apart a predetermined distance from the formed hole.

The first insulating member 152 may prevent the current transmitted from the first conduction module 110 to the second conduction module 120 from being transmitted to the basket 130. The first insulating member 152 may be disposed between the fastening part 123 and the basket body 131. In other words, the fastening part 123 and the basket body 131 may be connected via the first insulating member 152, and the fastening part 123 and the basket body 131 are due to the first insulating member 152. ) Can be insulated. In addition, the first insulating member 152 may have a plurality of holes into which the connecting member 151 may be inserted. For example, the first insulating member 152 may have a plate shape, and a plurality of holes passing through the plate-shaped first insulating member 152 may be formed.

Referring to FIG. 5, the second insulating member 153 may prevent current from being transmitted from the fastening part 123 to the basket body 131 through the connection member 151. For example, the second insulating member 153 may be a washer made of a ceramic material. The second insulating member 153 may be disposed inside the fastening groove 123a formed in the fastening part 123 to separate the fastening part 123 and the connecting member 151. In addition, the second insulating member 153 may be connected to the connection member 151.

The lifting pin 160 provides a portion in which the cathode module 100 is gripped by the lifting device when the cathode module 100 is moved by a lifting device (not shown). In other words, in order to recover the metal conversion body accommodated in the cathode module 100 that has undergone the electrolytic reduction process, the user holds the lifting pin 160 through the lifting device, and then uses the metal conversion body recovery device 1. Can be transferred. These lifting pins 160 may be connected to one side of the first conductive body 111.

The frame 200 may support at least some of the other components of the metal conversion body recovery device 1. For example, the frame 200 may support the cathode module 100, the separation unit 300, the lift unit 400, and the rotation unit 500. A module receiving groove 210 may be formed in the frame 200. The module receiving groove 210 may be a portion in which the cathode module 100 is supported by the frame 200. In other words, the cathode module 100 may be moved to the upper part of the frame 200 by a lifting device (not shown), descended into the module receiving groove 210, and supported by the frame 200.

Referring further to FIG. 7, the separation unit 300 may drive the fastening unit 140 so that the fastening state between the first conduction module 110 and the second conduction module 120 is released. The separation unit 300 may be supported on the frame 200. In addition, the separation unit 300 may include a driver 310, a driving gear 320, an idle gear 330, a separation body 340, a moving device 350, and a clutch 360.

The driver 310 may generate power for driving the fastening unit 140. Such a driver may be connected to a clutch 360 to be described later. In addition, the actuator 310 may be an actuator.

The drive gear 320 may be connected to the clutch 360 and may be rotated by power generated from the driver 310. The driving gear 320 may be meshed with the idle gear 330 and rotated by the power generated from the driver 310, thereby rotating the idle gear 330.

The idle gear 330 may mesh with the rotation gear 141 and rotate by the drive gear 320 to rotate the rotation gear 141. The idle gear 330 may be rotated by the driving gear 320 to release the fastened state between the first conduction module 110 and the second conduction module 120. In addition, the idle gear 330 may be selectively meshed with the rotation gear 141 by a moving device 350 to be described later.

The separation body 340 may support the driver 310, the drive gear 320, the idle gear 330, and the clutch 360. In other words, the separation body 340 is a driver 310, a drive gear 320, an idle so that the driver 310, the drive gear 320, the idle gear 330, and the clutch 360 can move in one direction at the same time. A portion of the gear 330 and the clutch 360 may be supported.

Referring further to FIG. 8, the moving device 350 may move the separation body 340 in one direction to prevent interference between the separation unit 300 and the cathode module 100. In other words, when the cathode module 100 is lifted to move to the next process or seated in the module receiving groove 210, the separation body 340 is used to prevent interference between the cathode module 100 and the separation unit 300. ) Can be moved. For example, when the cathode module 100 is seated in the module receiving groove 210, the moving device 350 may move the separating body 340 in the first direction. In addition, when the cathode module 100 is supported in the module receiving groove 210, the moving device 350 provides the separation body 340 to separate the first conduction module 110 and the second conduction module 120. It can be moved in two directions. The idle gear 330 moved in this second direction may be engaged with the rotating gear 141 to drive the fastening unit 140, and the moving device 350 moves the cathode module 100 to the next process. The separation body 340 may be moved in the first direction in order to lift it. One side of the moving device 350 may be connected to the separation body 340, and the other side of the moving device 350 may be supported by the frame 200.

When the separation unit 300 moves in one direction and is connected to the fastening unit 140, the clutch 360 meshes with the idle gear 330 to assist the meshing between the idle gear 330 and the rotation gear 141. A degree of freedom of rotation may be given to the drive gear 320. In other words, when the idle gear 330 and the rotation gear 141 are meshed, the clutch 360 is kept in a power-separated state, and the drive gear 320 and the idle gear 330 freely rotate to rotate the rotation gear. Can be engaged in (141). In addition, after the idle gear 330 and the rotation gear 141 are meshed, the driving gear 320 may be rotated by the power generated from the driver 310.

Referring further to FIG. 9, the lift unit 400 may separate the second conduction module 120 from the first conduction module 110. The lift unit 400 may be supported on the frame 200. In addition, the lift unit 400 may include a lifting unit 410 and a sliding unit 420.

The lifting part 410 may move the second conduction module 120 and the basket 130 in the vertical direction. The lifting part 410 may lift the basket 130 connected to the second conduction module 120 to separate the second conduction module 120 from the first conduction module 110. In other words, the lifting part 410 may allow the locking part 122 to be spaced apart from the support part 112a. In addition, the lifting unit 410 may lift the basket 130 to the height of the gripper unit 510 to be described later in order to grip the basket 130 by the gripper unit 510.

The sliding part 420 may move the second conduction module 120 and the basket 130 separated from the first conduction module 110 toward the rotation unit 500 to be described later. In other words, the sliding part 420 may move the second conduction module 120 and the basket 130 toward the rotation unit 500 when the locking part 122 is separated from the support part 112a.

Referring to FIG. 9, the rotating unit 500 may grip and rotate the basket 130 to recover the metal converting body accommodated in the basket 130. The rotation unit 500 may include a gripper part 510 and a rotation part 520.

The gripper part 510 may grip the side surface of the basket 130. The gripper part 510 may be connected to the rotating part 520.

The rotating part 520 may rotate the gripper part 510 gripping the side of the basket 130. In other words, when the rotating part 520 rotates the gripper part 510 by 180°, the basket 130 held by the gripper part 510 may also be rotated 180°, and the metal inside the basket 130 is converted. The sieve can freely fall in the recovery container 600.

The recovery container 600 may contain the metal conversion body recovered from the basket 130 and may be transferred by the conveyor 700.

Hereinafter, the operation and effect of the metal conversion body recovery apparatus 1 having the above-described configuration will be described.

The metal conversion body recovery device 1 may be used to recover the metal conversion body inside the basket 130 by separating the cathode module 100 that has undergone an electrolytic reduction process. A user may put an oxide raw material such as metal oxide in the basket 130 of the cathode module 100 and then put it into the molten salt electrolyte. A reduction potential is generated by transferring a current from the outside to the input cathode module 100 to convert a metal oxide inside the basket 130 into a metal converter. In order to recover the metal conversion body that has undergone such an electrolytic reduction process, a module formed on the frame 200 of the metal conversion body recovery device 1 after holding the lifting pin 160 of the cathode module 100 using a lifting device The cathode module 100 may be seated in the receiving groove 210. In addition, when the cathode module 100 transferred by the lifting device is supported by the frame 200, the moving device 350 moves the separating body 340 in the second direction, so that the idle gear 330 and the fastening unit 140 ) Of the rotating gear 141 can be engaged. The idle gear 330 may be rotated by the driving gear 320 rotated by the power generated from the driver 310, thereby driving the fastening unit 140. The rotation gear 141 of the fastening unit 140 is rotated by the rotation of the idle gear 330, thereby separating the load pin 144 from the locking part 122, and the first conduction module 110 and the second conduction The fastening state between the modules 120 may be released.

When the fastening state between the first conduction module 110 and the second conduction module 120 is released, the lifting part 410 lifts the basket 130, and the sliding part 420 is the basket 130 in which the metal converter is accommodated. ) Can be transferred to the gripper unit 510. The gripper part 510 part grips the side of the conveyed basket 130, and the rotation part 520 may rotate the gripper part 510. The basket 130 gripped by the gripper part 510 is also rotated by the rotation of the gripper part 510, and the metal conversion body accommodated in the rotated basket 130 can be recovered to the recovery container 600. have. In addition, the recovery container 600 from which the metal conversion body is recovered may be transferred by the conveyor 700.

The basket 130 from which the metal conversion body has been recovered may return to the position before being separated so that the first conduction module 110 and the second conduction module 120 can be fastened again, and the first conduction module 110 and the second conduction module 110 2 The conduction module 120 may be refastened by the separation unit 300 and reused.

There is an effect that the user can separate and couple using a power source without manually fastening the upper conductor and the lower conductor fixed to the basket in an insulated state. In addition, it is possible to reduce manpower and automate the process by separating and combining it as a power source rather than manual connection by the user. In addition, during the electrolytic reduction process, there is no risk of damage to the cathode module due to thermal deformation and corrosion of the fastening portion due to high temperature.

The embodiments of the present invention have been described above as specific embodiments, but these are only examples, and the present invention is not limited thereto, and should be construed as having the widest scope in accordance with the basic idea disclosed herein. A person skilled in the art may combine/substitute the disclosed embodiments to implement a pattern of a shape not indicated, but this also does not depart from the scope of the present invention. In addition, those skilled in the art can easily change or modify the disclosed embodiments based on the present specification, and it is clear that such changes or modifications also belong to the scope of the present invention.

1: metal conversion body recovery device 100: cathode module
110: first conduction module 111: first conduction body
112: first conductive coupling portion 112a: support portion
112b: coupling portion groove 112c: coupling portion jaw
113: through hole 120: second conduction module
121: second conduction body 122: locking portion
123: fastening part 123a: fastening groove
130: basket 131: basket body
132: basket net 140: fastening unit
141: rotation gear 142: first threaded member
143: second threaded member 144: rod pin
145: stopper 150: insulation
151: connecting member 152: first insulating member
153: second insulating member 160: lifting pin
200: frame 210: module receiving groove
300: separation unit 310: actuator
320: drive gear 330: idle gear
340: separation body 350: moving device
360: clutch 400: lift unit
410: lifting part 420: sliding part
500: rotation unit 510: gripper portion
520: rotating part 600: recovery container
700: conveyor

Claims (10)

A first conduction module through which current received from the outside flows;
A basket capable of receiving a metal oxide;
A second conduction module through which a current for reducing the metal oxide can flow; And
In order to prevent the second conduction module from being arbitrarily separated from the first conduction module, it includes a fastening unit that moves in one direction and is driven to selectively contact an upper surface of the second conduction module,
Cathode module. The method of claim 1,
The first conductive module includes a first conductive coupling portion capable of supporting the second conductive module,
The second conduction module includes a locking part that can be supported in contact with the first conduction module coupling part,
Cathode module. The method of claim 2,
The fastening unit,
A load pin that can contact the locking part;
A first threaded member capable of moving the load pin forward and backward along one direction; And
Comprising a rotation gear that can be rotated to rotate the first threaded member,
Cathode module. The method of claim 1,
The basket surrounds the metal oxide and includes a basket network having a mesh shape,
Cathode module. The method of claim 4,
Further comprising an insulating portion for connecting the basket and the second conductive module, and insulating between the basket and the second conductive module,
Cathode module. The method of claim 3,
The first threaded member moves the rod pin toward the locking portion while being rotated by the rotation gear,
In order to prevent the second conduction module from being arbitrarily separated from the first conduction module, the load pin contacts the locking part supported in contact with the inside of the first conduction coupling part,
Cathode module. A cathode module capable of accommodating a metal converter;
Separation unit;
A gripper unit gripping the cathode module; And
It includes a rotation unit for rotating the negative electrode module to recover the metal conversion body from the negative electrode module,
The cathode module,
A first conduction module through which current received from the outside flows;
A basket capable of accommodating the metal converter;
A second conduction module through which a current for reduction into the metal conversion body can flow; And
A fastening unit driven to be placed in a fastened state capable of preventing the second conductive module from being arbitrarily separated from the first conductive module,
The separating unit drives the fastening unit so that the fastening state can be released,
Metal conversion body recovery device. The method of claim 7,
The separation unit,
A drive that generates power;
A drive gear rotated by the power generated from the actuator; And
Including an idle gear engaged with the fastening unit and capable of releasing the fastened state by the drive gear,
Metal conversion body recovery device. The method of claim 8,
The fastening unit further includes a rotation gear engaged with the idle gear and rotated by the separation unit,
The separation unit,
A separating body supporting the driver, the drive gear, and the idle gear; And
Further comprising a moving device for moving the separation body so that the idle gear is selectively engaged with the rotation gear,
Metal conversion body recovery device. The method of claim 9,
The separation unit,
When the separation unit moves in one direction and is connected to the fastening unit, further comprising a clutch for imparting rotational freedom to the drive gear meshed with the idle gear to assist meshing between the idle gear and the rotation gear,
Metal conversion body recovery device.

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