KR101831260B1 - Vacuum drying device for battery material recovery - Google Patents

Abstract

The present invention relates to a battery raw material and N-Methyl-2-pyrrolidone (NMP) recovery apparatus using vacuum-drying. The battery raw material and NMP recovery apparatus can be used to solve the problems of recovering and recycling only cobalt materials due to the lack of technical know-how in effectively treating NMP solutions, great resource and financial loss due to the moist NMP solutions including impurities being treated by incineration in an incinerator, environmental pollution due to highly toxic substances harmful to the human body being generated during the incineration, difficulties in reusage due to the low purity even when the NMP is recovered, and waste of resources due to the significantly low recovery rate making efficient recycling impossible, and the environmental pollution caused by the residual NMP not being recovered. The battery raw material and NMP recovery apparatus includes a battery material recovery apparatus, a raw material conveying apparatus, and a control apparatus to recover the cobalt material without impurities by drying a large amount of the disposed battery materials, refine the NMP material at a high purity rate and high recovery rate compared to a conventional counterpart with low purity and recovery rates to increase the raw material recovery rate, and reduce the environmental pollution accordingly. The battery raw material and NMP recovery apparatus can recycle and sell the high-purity materials recovered thereby, reduce the energy and recovery cost by maximizing the heat insulation by increasing the heating efficiency in incineration, simplify the processing procedure, enable untrained workers to easily control the apparatus and randomly adjust the NMP concentration rate as well as easily adjusting the temperature and pressure, and enable easy and safe NMP refining by using an automated operation.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an apparatus for recovering a battery,

In the present invention, a liquid NMP solution is added to a powdery battery material containing a large amount of impurities resulting from pulverizing a waste battery and a waste battery to decompose impurities, and a sludge-like The raw materials are vacuum-dried to recover the battery raw materials such as cobalt in a solid state, and the vaporized NMP is condensed in the drying state to be collected and recovered in the liquid state to be recycled, so that the recovered raw materials can be resold and the raw materials are not incinerated To a battery material and an NMP recovery device through vacuum drying which can reduce environmental pollution.

As modern society develops, various types of electronic devices are produced. Electronic devices that supply electric current to wireless devices instead of wires are essentially used with built-in batteries.

In particular, cobalt is resistant to high temperatures and is resistant to corrosion and abrasion, making it suitable for use in portable electric devices such as lithium-ion batteries, batteries and smart phones, as well as for hybrid electric vehicles, electric vehicle batteries, gas turbine blades, jet engines, It is used in various fields, and it occupies a large portion in domestic as well as overseas. It is highly utilized and consumes a large amount, but in Korea, the entire amount depends on importing. Because the market value of waste batteries using cobalt is high, It is a fact that it is emerging.

Here, the waste battery is pulverized into a powder form, and a powdery waste battery containing various impurities is immersed in an NMP solution for a predetermined time to remove impurities, and the NMP solution is removed from the sludge- Recycling is done through the process.

Conventionally, when the boiling point of the NMP solution is evaporated to about 200 ° C., there is a problem that the surrounding materials are burnt out. Therefore, the technical know-how to effectively treat the NMP solution is insufficient so that only the raw material of the cobalt can be recycled and the impurity- Is burned and burned out in most of the incinerators, resulting in a large economic loss of resources consumed thereby resulting in toxic toxic substances harmful to human bodies such as arsenic, exceeding the statutory standard value at the time of incineration, causing environmental pollution.

In order to solve these problems, various methods have been sought for recovering the powdery waste battery material without damaging it and at the same time recovering the NMP solution. However, even when the NMP is recovered, the purity is low and reuse is difficult and the recovery rate is remarkably low, There is a problem that resources are wasted and environmental pollution is caused by the remaining amount of NMP that can not be recovered.

In order to solve the above problems, in the present invention, a large amount of waste batteries are incinerated to recover not only cobalt raw material but also recovered NMP raw material which is evaporated upon incineration to have a low recovery rate and a low purification rate, It is possible to reduce pollution, reduce energy by improving heating efficiency and insulation performance at incineration, reduce process system easily, easily change pressure and temperature, and adjust the concentration of NMP arbitrarily. And it is an object of the present invention to provide a battery material and an NMP recovery device through vacuum drying which can be easily controlled even without a worker and which can purify NMP easily and safely by automatic operation.

In order to accomplish the above object, according to the present invention,

A battery raw material recovery device for recovering dried battery raw materials by collecting high-purity exhausted steam by heating a sludge-type battery raw material in which raw materials pulverized from waste batteries and waste batteries are mixed with NMP solution in a high-temperature vacuum state 10,

A raw material transfer device 20 coupled to the front of the battery material recovery device for moving the raw material along the guide rails through detection of the sensor to the drying furnace and extracting the dried raw material,

And a control unit 30 for measuring and controlling the internal temperature and pressure of the battery material recovery apparatus to confirm whether or not the battery is operating normally and to easily and safely control the extraction of the battery material and the NMP solution by automatic operation .

As described above, in the present invention, not only the recovery of cobalt raw materials in which a large amount of waste battery raw materials are dried to remove impurities, but also the purification of NMP raw materials having a low recovery rate and a low purification rate at high purity and high recovery rate It is possible to increase the recovery rate of the raw material and thereby reduce the environmental pollution and recycle the raw material of the recovered high purity and sell the raw material and increase the efficiency of heating at the time of incineration and maximize the heat insulation, , It can be easily controlled even if it is not a skilled worker by simply reducing the process system, easily changing the pressure and temperature, arbitrarily adjusting the concentration of NMP, and can easily and safely refine NMP by automatic operation It has good effect.

FIG. 1 is a block diagram showing components of a battery material and an NMP recovery device through vacuum drying according to the present invention. FIG.
FIG. 2 is an overall perspective view showing an overall shape of a battery material and an NMP recovery device according to the present invention. FIG.
FIG. 3 is a schematic view showing a state in which a raw material tray is laterally moved along a transverse guide rail of a raw material conveying apparatus according to the present invention,
FIG. 4 is a view showing a state in which the material tray is moved in the longitudinal direction along the longitudinal guide rails of the raw material conveying apparatus according to the present invention,
Fig. 5 is a partially enlarged view showing a lateral guide rail of a conveying main frame and a longitudinal guide rail of a conveying supporting frame of a material conveying device according to the present invention,
FIG. 6 is a perspective view illustrating the components of the dry heating unit according to the present invention,
FIG. 7 is a front view showing a state in which the handle of the door portion of the door according to the present invention is positioned in the lower end direction, and the opening and closing rotation portion, the second engagement protrusion of the first engagement protrusion and the second engagement protrusion of the opening and closing door are engaged with each other,
FIG. 8 is a front view showing a state in which the handle constituting the opening / closing handle portion of the door portion according to the present invention is positioned in the upper direction and the opening / closing rotation portion, the second locking protrusions of the first locking protrusion and the second locking protrusion,
9 shows components of a heat exchanger according to the present invention, and also an embodiment in which the movement path of a fluid to be moved in operation is indicated by an arrow,
Fig. 10 partially shows a heat exchanger according to the present invention, enlarges the upper and lower ends of the heat exchange body,
Fig. 11 shows the components of the vacuum according to the present invention, and in the embodiment in which the moving path of the fluid to be moved in operation is indicated by an arrow,
Fig. 12 shows the components of the adsorption section according to the present invention, and in the embodiment in which the movement path of the fluid to be moved in operation is indicated by the arrow,
Fig. 13 shows the components of the cooling unit according to the present invention. Also in the embodiment in which the moving path of the fluid to be moved in operation is indicated by an arrow,
14 shows components of the nitrogen gas supply unit according to the present invention. Also in the embodiment in which the moving path of the fluid to be moved in operation is indicated by an arrow,
15 is a block diagram showing the components of the control unit according to the present invention.

Before describing the present invention, NMP stands for N-methyl-2-pyrrolidone (N-methyl-2-pyrrolidone).

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing constituent elements of a battery material and an NMP recovery device 1 through vacuum drying according to the present invention, and FIG. 2 shows an overall shape of a battery raw material and an NMP recovery device according to the present invention Which is composed of a battery material recovery device 10, a material transfer device 20, and a control part 30. [

First, the battery material recovery apparatus 10 according to the present invention will be described.

The battery material recovery apparatus 10 is configured to purify exhausted sludge by mixing a raw material obtained by pulverizing waste batteries and waste batteries with a NMP solution and heating the sludge-shaped battery raw material in a high-temperature vacuum state, collecting the discharged sludge in high purity, It serves to recover the raw material.

This is constituted by a drying heating unit 100, a heat exchanger 200, a vacuum 300, an adsorption unit 400, a cooling unit 500, and a nitrogen gas supply unit 600.

First, the drying and heating unit 100 according to the present invention will be described.

The drying and heating unit 100 is a horizontally disposed cylindrical frame having a hinged door formed on its front side. A drying furnace coil is formed along the inner periphery to control the internal temperature, And controls the presence or absence of the dry heating body 110, the door 120, and the drying guide rail 130 to vacuum and dry the raw materials.

The drying heating body 110 has an inner wall of a heat insulating structure in a cylindrical shape divided horizontally and has a heater in the form of a coil along the inner circumferential surface to receive and dry the charged battery material.

The drying heating body 110 according to the present invention has a coil-shaped heater connected to the control unit along the inner circumferential surface to heat the sludge-shaped battery raw material by emitting heat in the inward direction at 210 to 350 ° C, A heater 111 for vaporizing the solution is formed.

The drying heating body 110 is connected to the nitrogen gas supply unit through a nitrogen supply pipe connected to one side of the rear side to prevent the inflow of oxygen into the inside of the dry heating body 110 and receives nitrogen gas and is connected to a heat exchanger And a vacuum pressure is formed therein.

In this case, the boiling point of the NMP solution to be vaporized is 197 ° C, and the internal temperature should be raised to 197 ° C or more. When the temperature rises above 100 ° C, a fire may occur due to reaction with oxygen, Oxygen is removed from the inside of the dry heating body through the gas supply unit, and nitrogen gas is introduced.

That is, the inside of the drying heating body 110 is kept in a state where oxygen is removed and nitrogen gas is supplied so that the internal temperature is raised to 100 ° C. or more, but no fire is generated therein, .

At this time, the temperature of the heater is adjusted through the control unit to set the internal temperature of the drying heating body to 210 ° C to 350 ° C.

When the internal temperature of the drying heating body 110 is set to 210 ° C or less, the drying time required for vaporization of the NMP solution in the liquid state takes a long time and energy consumption of the heater is increased. There is a problem that the lifetime of the device is shortened and the energy consumption is rapidly increased due to overloading.

In addition, the dry heating body 110 according to the present invention is formed with a heat insulating material surrounding the inner side sidewalls to insulate the inner side temperature to minimize heat loss caused by the outer surface.

Thus, the loss of energy during the drying operation of the drying hitting unit 100 is minimized, the damage caused by an accident such as an image due to carelessness or safety accident of the operator can be reduced, and the work space for the peripheral work can be ensured.

The door part 120 is a circular door shape which is hinged to one side of the front side of the drying heating body and is opened / closed in the form of a hinged door, and the inner side is in close contact with the door rotation part 121, An opening / closing handle portion 123, and a rotating roller portion 124, as shown in Fig.

The opening / closing rotary part 121 is coupled to the front surface of the dry heating body in the form of a ring-shaped band, the first locking protrusion 121a is formed at regular intervals along the circumference, and the first gear teeth 121b .

Here, the first locking protrusions 121a are formed at regular intervals around the front face of the opening / closing rotary part 121 of the ring-shaped band, and are protruding at right angles to the inner direction, .

At this time, as shown in FIG. 7, when each of the first locking projections 121a formed at regular intervals along the circumference coincides with the position of the second locking projections 122a of the opening and closing door portion and the first locking projections are engaged with the second locking projections 122a, Closing the door so that the opening and closing door is not opened to the front, and when each first locking protrusion 121a is offset from the position of the second locking protrusion 122a of the opening and closing door portion, The second locking protrusion can be moved forward so as to open the opening / closing door so as to be opened forward.

Here, the first gear 121b is formed in a gear shape formed within a predetermined range on the lower side of the right side of the opening / closing rotary part 121, and the opening / closing hand is formed to engage with the negative second gear 123a.

At this time, the first gear rotates the position of the first locking projection through the rotation of the first gear 121b.

The opening / closing door portion 122 is formed in a circular door shape and is coupled to the left side of the front side of the drying heating body through a hinge structure on the left side, and a second locking protrusion 122a is formed at regular intervals along the circumference.

Here, the second locking protrusions 122a are formed at regular intervals around the front surface of the opening / closing door portion 122 of the circular-door shape, and have a protruding shape protruding outward.

When the vacuum pressure of the vacuum pump connected to the heat exchanger through the NMP steam supply pipe connected to the rear surface of the dry heating body is generated inside the drying heating body, pressure is applied from the front to the rear and the opening and closing door unit 122 is closely contacted rearward .

Accordingly, when the battery material and the NMP recovery device are driven, the opening and closing door portion 122 is firmly attached to the front surface of the drying and heating body to prevent oxygen from leaking into the inside, It is possible to minimize the heat loss through the heat exchanger.

The opening / closing handle 123 is formed in a spur gear shape and is coupled to one side of the lower right end of the front right side of the drying hitting body. The handle is formed by protruding a handle. The first gear 121b is engaged with the second gear (123a) is formed to rotate the opening / closing rotary part.

Here, the second gear 123a is formed in a gear shape rotated about the rotation axis of the opening / closing handle 123 and at a position where the first gear 121b engages with the second gear 123a.

7, the second gear 123a rotates in the clockwise direction and rotates the first engagement protrusion 121b in the counterclockwise direction by rotating the knob of the opening / closing handle 123 in the downward direction , As shown in FIG. 8, the second gear 123a is rotated in the counterclockwise direction and the second locking protrusion 121b is rotated in the clockwise direction.

Closing rotation part 121 to control the opening and closing of the opening and closing door part 122. [

The roller support portion 124 is horizontally fixed to the lower end of the front side of the drying heating body, and the roller support frame is fixed to the upper end of the roller support frame. The rotating rollers are formed symmetrically with respect to the left and right sides of the opening and closing rotary part and are rotated.

Thereby reducing friction during rotation of the opening and closing rotary part and reducing wear due to friction between the first gear 121b and the second gear 123a to facilitate opening and closing of the opening and closing door part 122 , It is possible to improve the service life of the door part.

The drying guide rails 130 support the lower end of the material feed tray 2, which is inserted into the inside of the rectangular guide frame 130, and facilitate the feeding during feeding and withdrawal.

3, when the conveying support frame 22 is positioned at the left end of the raw material main frame 21 through the transverse guide rails 21a at the upper end of the raw material main frame 21, As shown in FIG.

Thus, the material feed tray loaded on the material feed device can be automatically fed into and out of the drying heating body 110.

Second, the heat exchanger 200 according to the present invention will be described.

The heat exchanger 200 is a cylindrical frame vertically coupled to the upper center of the rectangular frame, the upper end of the heat exchanger 200 is connected to the rear surface of the drying hood by a pipe, the lower end of the frame is connected to the vacuum And a pipe for circulating cooling water is connected to the upper and lower ends of the rear surface, thereby absorbing the heat energy of the high-temperature NMP vapor generated during the vacuum drying of the battery material in the drying heat source, thereby condensing and reducing the heating load The heat exchanger 200 includes a heat exchange support 210, a heat exchange body 220, an NMP vapor supply pipe 230, a vacuum pipe 240, a cooling water supply pipe 250 and a cooling water discharge pipe 260.

The heat exchange support 210 supports a heat exchange body 220 vertically coupled to the center of the upper surface by a rectangular frame.

The heat exchange body 220 is vertically connected to the center of the top surface of the heat exchange support by an upright cylindrical frame and an NMP vapor supply pipe 230 connected to one side of the rear side of the drying heating part 100 is formed on the upper front side A cooling water supply pipe 250 connected to one side lower side of the cooling part 500 is formed at the lower rear side of the vacuum tube 240 and the lower end of the cooling water supply pipe 250 is connected to one side of the side of the vacuum chamber 300, A cooling water discharge pipe 260 connected to a side upper end of the cooling unit 500 is formed and a partition wall is formed between the connected NMP steam supply pipe 230 and the vacuum pipe 240, A plurality of tube tubes 221 are formed.

The heat exchanging body 220 according to the present invention is configured such that the NMP vapor fluid supplied from the NMP vapor supply pipe 230 through the vacuum pressure of the vacuum tube 240 connected to the vacuum is discharged from the upper end along the inner hole of the tube tube 221 The cooling water supplied from the cooling water supply pipe 250 coupled to one side of the upper end of the lower end partition wall inside the heat exchange body 220 rises in the upper direction from the lower end along the outer surface of the tube pipe 221, 260, respectively.

At this time, the hot NMP vapor fluid descends from the upper end to the lower end along the inner hole of the tube tube 221, the cooling water rises upward from the lower end of the outer surface of the tube tube 221, The NMP vapor fluid of high temperature is condensed by the temperature difference between the inside and the outside of the cooling unit 500,

In this case, the liquefied NMP solution moves through the vacuum tube to the vacuum, and is finally transferred to the NMP storage tank 311 through the transfer pump 310 and is collected.

This allows the vaporized NMP vapor to be liquefied and captured in a high purity NMP solution.

The NMP steam supply pipe 230 has a circular tube shape and has a front end connected to one side of the rear side of the drying heating body 110 and a rear end connected to one side of the upper end of the heat exchange body 220, And serves as a moving passage for moving the gas including the NMP to the heat exchanger.

This is because the front end connected to one side of the rear side of the dry heating body has a shape of 'ㅓ', and a trace amount of NMP solution which is condensed and liquefied in the early stage among the NMP steam discharged from the drying heating body 110 is lowered to the lower end, The NMP vapor in the form of gas is raised to the upper end by the vacuum pressure of the vacuum tube and is moved to the heat exchange body 220.

In this case, the initial NMP trace collection pipe 231 has a valve at the lower end thereof to collect a small amount of the NMP solution collected through the opening and closing of the valve.

The upper end of the vacuum tube 240 is connected to the lower end surface of the heat exchange body 220 in a vertical tube shape. The side end of the tube 240 is connected to one side of the vacuum chamber 240, It serves to move the fluid inside the heat exchange body to vacuum.

Through which the NMP solution (3a) is condensed and the residual gas which has not been condensed is moved to the vacuum chamber (300).

The cooling water supply pipe 250 has a circular tube shape and has a front end connected to one side of the lower end of the heat exchange body 220 and a rear end connected to one side of the lower end of the cooling water tank 510, To the heat exchange body (220).

This serves to supply low-temperature cooling water to the outer surface of the tube pipe 221 through which the high-temperature NMP vapor passes.

The front end of the cooling water supply pipe 250 is connected to the lower end hole of the tube pipe 221 formed at the lower end of the heat exchange body with the partition wall to prevent the cooling water from flowing into the lower end hole of the tube pipe.

The cooling water discharge pipe 260 has a circular tube shape and has a front end connected to one end of the upper end of the heat exchange body 220 and a rear end connected to one end of the upper end of the cooling water tank 510, And serves as a moving passage for discharging the cooling water passing through the outer surface of the tube tube to the cooling water tank 510.

This is to discharge the cooling water whose temperature has risen to the cooling tank 510 after passing through the outer surface of the tube pipe 221 through which the high temperature NMP vapor passes.

The front end of the cooling water discharge pipe 260 is connected to the upper hole of the tube 221 formed on one side of the upper end of the heat exchange body with the partition wall to prevent the cooling water from flowing into the upper hole of the tube.

Third, the vacuum 300 according to the present invention will be described.

The vacuum chamber 300 is connected to the lower end of the heat exchanging body 220 by piping on one side of the side surface of the vacuum tank 300. The NMP solution is transferred and accommodated in a liquefied state through vacuum pressure, The vacuum pump tube 320 and the NMP solution storage tank 330 are connected to each other through a pipe to transfer residual gas that has not been condensed.

The transfer pump tube 310 has a circular tube shape and has a left end connected to the vacuum chamber, a right end connected to the NMP solution storage tank 330, and a transfer pump 311 coupled to the center, To the NMP solution storage tank (330).

The vacuum pump tube 320 has a circular tube shape and has a front end connected to the vacuum chamber, a side end connected to the suction part 400, a vacuum pump 321 coupled to one side of the vacuum pump 320, Which is not condensed in the adsorbing unit 400, to the adsorbing unit 400.

The NMP solution storage tank 330 is a cylindrical tank, and one side of the NMP solution storage tank 330 is connected to the transfer pump tube 310 to receive the condensed NMP solution in a liquefied state.

At this time, the accommodated NMP solution has a high purity NMP solution containing no impurities in a condensed and liquefied state at the time of heating at high temperature and can be reused, and more than 90% of NMP solution used for removing impurities from the waste battery Can be recovered.

This is because the recovery rate of the NMP solution is high, thereby minimizing the environmental pollution generated in the incineration treatment and re-use of the raw material brings about an economical effect.

Fourth, the adsorption unit 400 according to the present invention will be described.

The adsorption unit 400 is connected to the vacuum pump pipe in a rectangular frame shape to receive the exhausted gas without being condensed in the heat exchange body through the vacuum pump and to filter the odor, dust and gas generated in the gas, It acts to adsorb a small amount of non-condensed NMP.

This minimizes the discharge of vaporized NMP by trapping a small amount of non-condensed NMP gas passing through the tube tube due to the temperature difference between the inside and the outside of the tube tube and filtering out particulates such as dust formed in the gas, It prevents contamination and raises NMP recovery rate.

Fifth, the cooling unit 500 according to the present invention will be described.

The cooling unit 500 is connected to a plurality of coolers in a cylindrical tank and is connected to a pipe of the heat exchanger to cool and circulate the cooling water to prevent overheating of the heat exchanger. The cooling water tank 510, And a cooler 520.

The cooling water tank 510 is connected to the lower end of the heat exchange body 220 through a cooling water supply pipe 250. The cooling water tank 510 is connected to the heat exchange body 220 through a cooling water discharge pipe 260, And a pipe for circulating the cooling water to the cooler 520 is connected to one side of the side, and serves to store and store the cooling water.

The cooling water tank 510 circulates and supplies the cooling water to the heat exchange body 220 through the cooling water supply pipe 250 and the cooling water discharge pipe 260. The cooling water tank 510 is connected to the cooler at one side of the upper side of the side surface to circulate the heat exchange body, A first cooling water pipe 511 for transferring the cooling water to the cooler and a second cooling water pipe 512 connected to the cooler at one side lower side side to receive the cooling water cooled by the cooler 520.

This circulates the heat exchanger body, circulates the cooled water to the cooler, lowers the temperature, and makes the circulation of the coolant repeated.

Thereby preventing overheating of the heat exchanger and condensing the NMP vapor passing through the plurality of tube tubes 221 inside by a temperature difference so as to be collected in a liquefied state.

The cooler 520 is formed in a rectangular shape with a plurality of cooling fans formed therein. The cooler 520 lowers the temperature of the cooling water whose temperature is increased by the cooling water tank, through the cooling fan, and transfers the cooled cooling water to the cooling water tank It plays a role.

This is because the first cooling water pipe 511 is connected to one side of the side upper end to receive the cooling water whose temperature has been raised from the cooling tank and the second cooling water pipe 512 is connected to one side of the lower side of the side to cool the cooling water cooled by the cooling fan And a cooling water circulation structure for transferring the water to the tank.

Sixth, the nitrogen gas supply unit 600 according to the present invention will be described.

The nitrogen gas supply unit 600 is connected to the drying heating unit through a nitrogen gas supply pipe 610 in a rectangular frame and circulates and supplies nitrogen gas to supply nitrogen gas to the inside of the drying heating unit.

This is because, when the battery raw material and the NMP recovery device are operated, oxygen is removed from the inside of the drying heating body 110 and nitrogen gas is supplied, so that even when the internal temperature of the drying heating body is raised to 100 ° C or more during drying of the recycled raw material, It is an oxygen-free, oxygen-free state that prevents fire from occurring inside and prevents the recycled material (3) from being damaged by fire.

Next, the raw material conveying device 20 according to the present invention will be described.

The raw material conveying device 20 is coupled to the front of the battery raw material collecting device, moves the raw material along the guide rails through the sensing of the sensor, and feeds the raw material to the drying furnace and draws the dried raw material.

This is constituted by a conveying main frame 21 and a conveying supporting frame 22.

The conveying main frame 21 is a rectangular frame shaped frame formed on the front side of the drying heating body and has a transverse direction guide rail 21a formed parallel to the transverse direction in forward and backward directions at the upper end thereof, It automatically moves back and forth.

The conveying support frame 22 is a rectangular frame shaped frame formed at the upper end of the conveying main frame. The conveying supporting frame 22 is parallel to the top in the longitudinal direction in the left-right direction, The guide rails 22a are formed to automatically feed and discharge the battery raw material to the dry heating body.

Next, the control unit 30 according to the present invention will be described.

The controller 30 measures and controls the internal temperature and pressure of the battery material collecting device to check whether the battery is operating normally and controls the extraction of the battery material and the NMP solution simply and safely by automatic operation.

It consists of a temperature control unit 31, a cooling control unit 32 and a vacuum control unit 33.

The temperature control unit 31 is connected to the drying heating unit 100 to turn on / off the heater inside the drying heating body, to measure the internal temperature in real time, to control the heating temperature of the heater, If not maintained, a beep sounds, and when the temperature exceeds 350 ° C, it is blocked.

Here, when the internal temperature of the drying hitting unit 100 is 350 ° C or more, the reason for shutting down is that the life of the device is shortened due to the overheating of the heater, the energy efficiency is reduced due to energy consumption, and the energy is wasted .

If the internal temperature of the drying heating part 100 is 210 캜 or lower, the drying time of the NMP solution becomes long and the NMP solution does not dry when the temperature falls below 197 캜.

At this time, the NMP injected into the drying heating body is vaporized, the battery material is completely dried, and when the internal temperature rises, the temperature is automatically sensed and the heater power is turned off.

Through this, it is possible to check and control the temperature of the dry heating part in real time, thereby maximizing heating efficiency and enabling efficient consumption of energy.

The cooling control unit 32 is connected to the heat exchanger 200 and the cooling unit 500 to turn on / off the cooling unit, measure the internal temperature of the heat exchange support unit in real time, and control the circulation amount of the cooling water through the automatic valve It plays a role.

In this way, the NMP, which moves from the upper end to the lower end of the heat exchanger in the form of a hot steam, is condensed to be collected in a liquid state.

The vacuum control unit 33 is connected to the vacuum chamber 300 to turn on / off the vacuum pump, measure the vacuum pressure in the vacuum tank in real time, and control the vacuum pressure through the vacuum pump .

Through this, the NMP vaporized due to the high temperature inside the dry heating body is moved from the upper end of the tube tube formed in the heat exchanger to the lower end so that the condensation can be rapidly performed.

Hereinafter, an operation process of the battery material and the NMP recovery device through vacuum drying according to the present invention will be described.

First, a powdery raw material obtained by pulverizing a waste battery into a raw material transfer tray is charged and an NMP solution is mixed to remove impurities and impurities contained in the powdery battery.

Next, the raw material transfer tray containing the sludge-like raw material mixed with the pulsed powdery battery and the NMP solution is placed on the top of the material transfer supporting frame, and the position is determined through the lateral guide rail and the longitudinal guide rail to the front Direction.

Next, the opening / closing handle of the door portion is rotated to rotate the opening / closing rotary portion formed on one side of the first gear engaged with the second gear, so that the first locking protrusion is separated from the second locking protrusion.

Next, the raw material transfer tray is inserted inward along the drying guide rail portion formed at the lower inner end of the drying heating body, and the door handle is rotated so that the first locking projection and the second locking projection engage with each other, Lt; / RTI >

Next, the heater power of the drying and heating unit is turned on through the temperature control unit, the temperature of 210 to 350 ° C is set, the cooling water is supplied to the inside of the heat exchanger through the cooling control unit, Vacuum pressure is formed in the tube of the heat exchanger.

At this time, nitrogen gas is supplied to the interior of the drying heating body, vacuum pressure is formed, and the material is not oxidized even when the temperature inside the drying heating body is 210 to 350 ° C, so that the NMP solution is prevented from being oxidized can do.

Next, the NMP in the vapor state moves from the upper end of the tube tube to the lower end of the heat exchanger, and is condensed to collect the liquid NMP.

At this time, the cooling water is continuously circulated and supplied to the outside of the plurality of tube tubes formed vertically in the heat exchanger to prevent the NMP condensing efficiency from being lowered.

Lastly, steam containing a trace amount of NMP that has passed through the heat exchanger without being collected is moved to the adsorption tower to filter out impurities such as dust and adsorb a trace amount of NMP.

1: Battery material and NMP recovery device through vacuum drying
10: Battery raw material recovery device 100: Drying heating part
110: Drying heating body 120: Door part
130: drying guide rail 200: heat exchanger
300: vacuum chamber 400: adsorption part
500: cooling section 600: nitrogen gas supply section
20: Feedstock feeding device 21: Feeding main frame
22: conveying support frame 30:
31: temperature control unit 32: cooling control unit
33: Vacuum controller

Claims (7)

The sludge-type battery raw material in which the pulverized battery and the waste battery are pulverized and the NMP solution is heated to a high-temperature vacuum state to purify the exhausted steam and collect it in high purity. In order to recover the dried battery raw material, Shaped frame having a shape of a door part formed in a horizontal direction, a drying furnace coil is formed along the inner periphery to control the internal temperature, and a vacuum tank is connected to control the presence or absence of a vacuum state, A drying and heating unit 100 for drying,
Shaped frame which is vertically coupled to the upper center of the frame of the rectangular frame, the upper end of the upper part is connected to the rear surface of the drying hitting part by a pipe, the lower end of the frame is connected by vacuum and piping, A heat exchanger 200 is connected to a pipe for circulating the cooling water at the upper and lower ends of the rear surface to absorb heat energy of the high temperature NMP vapor generated during vacuum drying and drying of the battery raw material in the drying heating unit, Wow,
Shaped tank, which is connected to the lower end of the heat-exchanging body 220 by a pipe at one side of the side, transports and accommodates the condensed NMP solution in a liquefied state through vacuum pressure, and is connected to the adsorption unit 400 through piping, A vacuum 300 for delivering residual gas,
It is connected with the vacuum pump tube in the shape of a rectangular frame and receives the exhausted gas without condensation in the heat exchange body through the vacuum chamber. It filters the odor, dust and gas generated in the gas and forms a small amount of condensed NMP in the heat exchanger An adsorbing portion 400 for adsorbing the liquid,
A cooling unit 500 connected to a plurality of coolers in a cylindrical tank and connected to a pipe of the heat exchanger to cool and circulate the cooling water to prevent overheating of the heat exchanger,
And a nitrogen gas supply unit 600 connected to the drying heating unit through a nitrogen gas supply pipe 610 and circulating and supplying nitrogen gas to supply nitrogen gas to the interior of the dry heating unit, )Wow,
A raw material transfer device 20 coupled to the front of the battery material recovery device for moving the raw material along the guide rails through detection of the sensor to the drying furnace and extracting the dried raw material,
And a control unit (30) for controlling the internal temperature and pressure of the battery raw material recovery device to check whether the battery is operating normally and to easily and safely control the extraction of the battery raw material and the NMP solution by automatic operation. In the battery raw material and the NMP recovery device,
The drying heating unit 100
A drying heating body 110 having an inner wall of a heat insulating structure in a cylindrical shape divided horizontally and having a heater in the form of a coil along an inner circumferential surface thereof and accommodating and drying the charged battery material,
A door portion 120 which is opened and closed in a hinged shape in a circular door shape coupled with a hinge structure on one side in the front side direction of the dry heating body,
And a drying guide rail (130) for supporting the lower end of the raw material conveying tray (2) inserted into the inside thereof in a rectangular shape and facilitating the feeding during feeding and withdrawing. And an NMP recovery device.
delete delete The door (120) according to claim 1, wherein the door portion
Closing rotary part 121 coupled to the front surface of the dry heating body in a circular strip shape and having a first locking protrusion 121a formed at regular intervals along the circumference and a first gear 121b formed at a lower end of the lower surface of the right side, Wow,
An opening and closing door portion 122 coupled to the left side of the front side of the drying heating body through a hinge structure on the left side in a circular door shape and having a second locking protrusion 122a formed at regular intervals along the circumference,
A second gear 123a is formed which is coupled to one side of the lower right end of the front right side of the drying heating body in the form of a spur gear and is formed with a handle protruded and engaged with the first gear 121b and rotated according to the rotation of the handle, An opening / closing handle 123 for rotating the opening / closing handle 123,
The roller supporting frame is horizontally fixed to the lower end of the front side of the drying heating body and the rotating roller is formed symmetrically in the left-right direction on the upper end of the roller supporting frame And a rotating roller portion (124) which is rotated in contact with the left and right lower ends of the opening and closing rotary portion, respectively.
delete delete The apparatus of claim 1, wherein the control unit (30)
And is connected to the drying heating unit 100 to turn on / off the heater inside the drying heating body, to measure the internal temperature in real time, to control the heating temperature of the heater, and when the temperature of 197 to 350 ° C is not maintained, A temperature control unit 31 for shutting off when the temperature is over 350 DEG C,
A cooling control unit 32 connected to the heat exchanger 200 and the cooling unit 500 to turn on / off the cooling unit, measure the internal temperature of the heat exchange support unit in real time, and control the circulation amount of the cooling water through the automatic valve,
And a vacuum control unit 33 connected to the vacuum chamber 300 to turn on / off the vacuum pump, measure the vacuum pressure inside the vacuum chamber in real time, and control the intensity of the vacuum pressure through the vacuum pump The battery material and the NMP recovery device through vacuum drying.

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