CN213340431U - High-temperature device for preparing lithium ion battery cathode material - Google Patents

Abstract

The utility model relates to a high temperature device for preparing lithium ion battery cathode material, which is characterized in that the high temperature device comprises a vacuum reaction chamber and a rotary collecting chamber, wherein the vacuum reaction chamber comprises a reaction cavity, a heating layer and a first heat preservation layer from inside to outside in sequence; the rotary collecting chamber sequentially comprises a rotary hearth, a prefabricated heating body and a second heat-insulating layer from inside to outside; the front end of the rotary hearth is communicated with the reaction cavity, the vacuum reaction chamber and the rotary collecting chamber are respectively provided with an independent heating device, and the temperatures of the vacuum reaction chamber and the rotary collecting chamber can be independently controlled.

Description

High-temperature device for preparing lithium ion battery cathode material

Technical Field

The utility model belongs to the technical field of lithium ion battery cathode material prepares, concretely relates to high temperature equipment of preparation lithium ion battery cathode material.

Background

With the rapid development of modern consumer, electronic and electric automobile industries, the research and industrialization process of lithium ion batteries as energy sources is also more and more important. The energy density of lithium ion batteries is still required to be further improved as an important index for measuring the performance of the batteries. However, the energy density of the conventional carbon-based negative electrode material has been raised to the limit, and the demand of the high energy density lithium ion battery cannot be satisfied. In order to promote the further development of lithium ion batteries and related industries and meet the demands of the market on lithium ion battery products, novel lithium ion battery negative electrode materials with high theoretical specific capacity are widely concerned, such as silicon-based negative electrodes, germanium-based negative electrodes, tin-based negative electrodes and the like. However, the new negative electrode materials are often accompanied by a large volume expansion during alloying/non-alloying reactions with lithium, resulting in pulverization of the materials and loss of conductive contact, resulting in a decrease in material stability.

The silicon monoxide negative electrode material has theoretical specific capacity which is several times that of the traditional carbon-based material, and compared with other novel negative electrode materials, the volume expansion is small, researchers improve and promote the electronic conductivity and the circulation stability of the silicon monoxide material by using methods such as surface coating, surface modification or nanocrystallization, and the like, so that the prospect of practical application of the silicon monoxide is greatly improved. Currently, mainstream battery manufacturers generally use C-SiOx material directly or mechanically mix C-SiOx with other negative electrode materials.

Patent CN202010337106.6 provides a lithium ion battery cathode material and a preparation method and device thereof, the preparation method comprises: mixing micron-sized silicon and silicon dioxide, and compacting into blocks to obtain Si/SiO₂Mixing the materials; under vacuum, heating the gasified mixed material and the magnesium metal to different preset temperatures respectively at different heating rates; depositing SiOx in a gas phase and magnesium in a gas phase by cooling mixing; and crushing, grading, demagnetizing and carbon coating to obtain the lithium ion battery cathode material. The preparation device is sequentially provided with a first heating cavity, a rotatable material collecting roller and a second heating cavity; the first heating cavity and the second heating cavity are respectively used for containing Si/SiO materials to be heated₂Mixing the material and the metal magnesium, wherein the collecting roller is used for enabling the SiOx in the gas phase and the magnesium in the gas phase to be deposited on the surface of the roller in a cooling mode to realize the collection of the material; the collecting roller is provided with a temperature control device for controlling the surface temperature of the collecting roller.

In the existing preparation technology of the silicon monoxide cathode, not only is the energy consumption high and the yield low, but also the batch stability is poor, the quality level of the material is uneven, and the large-scale preparation of the silicon monoxide cathode material is seriously limited. In addition, when the C-SiOx formed by crushing and coating is mechanically mixed with other negative electrode materials, the problems of overlarge particles, pulverization in the circulating process and the like exist, so that the performance of the battery is rapidly deteriorated, and the industrial application of the silicon oxide negative electrode is seriously influenced.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides a high temperature device for preparing a lithium ion battery cathode material, which comprises a vacuum reaction chamber and a rotary collecting chamber, wherein the vacuum reaction chamber sequentially comprises a reaction cavity, a heating layer and a first heat preservation layer from inside to outside; the rotary collecting chamber sequentially comprises a rotary hearth, a prefabricated heating body and a second heat-insulating layer from inside to outside; the front end of the rotary hearth is communicated with the reaction cavity, the vacuum reaction chamber and the rotary collecting chamber are respectively provided with an independent heating device, and the temperatures of the vacuum reaction chamber and the rotary collecting chamber can be independently controlled.

High temperature device collect the room intercommunication each other with vacuum reaction chamber and gyration to can the independent control vacuum reaction chamber and the gyration collect the indoor portion's temperature, the gyration of room is collected in the independent control gyration and is collected the mode, through adjusting the temperature of vacuum reaction chamber and gyration collection room respectively, the slew velocity of gyration collection room, obtain batch stability, even controllable inferior silicon oxide negative pole material.

The vacuum reaction chamber sequentially comprises a reaction cavity, a heating layer and a first heat preservation layer from inside to outside; the reaction chamber is used for containing raw materials of the silicon monoxide; the heating layer surrounds the outside of the reaction cavity, and a heating element is arranged in the heating layer and used for heating the raw materials in the reaction cavity; the first heat preservation layer surrounds outside the heating layer and is used for insulating heat and preserving heat of the vacuum reaction chamber.

Preferably, the reaction chamber is the crucible, and high temperature resistance is excellent, is applicable to the utility model discloses an inorganic raw materials's high temperature heating.

The reaction chamber is internally provided with a first temperature control component which is connected with a heating element of the heating layer to control the heating temperature.

The top of the vacuum reaction chamber is provided with a top end opening, the top end opening is provided with a first sealing flange, and the communication and the sealing between the reaction cavity and the outside are controlled.

Preferably, an exhaust port is arranged at the upper part of the side wall of the vacuum reaction chamber, and the exhaust port is communicated with the reaction cavity and the tail gas treatment device.

The rotary collecting chamber sequentially comprises a rotary hearth, a prefabricated heating body, a second heat insulation layer and a supporting rotating shaft from inside to outside; the front end of the rotary hearth is communicated with the side face of the reaction chamber, a plurality of material guide plates are arranged in the rotary hearth, one ends of the material guide plates are fixed on the inner wall of the rotary hearth, and the other ends of the material guide plates extend into the rotary hearth and are suspended in the air to drive materials to move at a constant speed; the supporting rotating shafts are arranged at two ends of the rotary hearth and used for supporting the rotary hearth and assisting the rotary hearth to rotate. The prefabricated heating bodies are uniformly arranged outside the rotary hearth and used for heating materials inside the rotary hearth in a rotary mode. And the second heat-insulating layer surrounds the outside of the prefabricated heating body and is used for insulating heat and preserving heat of the rotary hearth.

The shape of the cross section of the rotary hearth is selected from a circle, an ellipse, a square or other polygons, and preferably, the shape of the cross section of the rotary hearth is a circle or an ellipse.

Preferably, gyration furnace is the crucible, and high temperature resistance is excellent, is applicable to the utility model discloses a high temperature heating of inorganic raw materials.

Preferably, the material guide plates are arranged in the rotary hearth in a staggered mode, the disorder degree of materials in the rotary hearth is improved, and full contact and reaction of gas-phase silicon monoxide, core materials and process gas provided by the gas supply device are promoted.

The angle between the material guide plate and the inner wall of the rotary hearth is 20-90 degrees.

More preferably, the ratio of the length of the material guide plate to the inner diameter of the rotary hearth is 1: (3-5).

And a second temperature control component is arranged in the rotary hearth and connected with the prefabricated heating body to control the heating temperature of the prefabricated heating body.

The rear end of the rotary hearth is provided with a fixed flange which is mechanically connected with the transmission device, and the rotary hearth is sealed and is driven by a transmission shaft of the transmission device to rotate.

The rear end of the rotary collecting chamber is provided with a side end opening, the side end opening is provided with a second sealing flange, and the rotary collecting chamber is controlled to be communicated and sealed with the outside. And a rotary sealing shaft is arranged in a disc body of the second sealing flange, and the fixed flange and the second sealing flange are used for being in sealing connection with a transmission device. The sealing form of the rotating sealing shaft comprises but is not limited to one or more combinations of solid contact type dynamic sealing, liquid type vacuum dynamic sealing or magnetic fluid vacuum dynamic sealing.

The rear end of the rotary collecting chamber is provided with an air pumping hole, and the air pumping hole is connected with the vacuum device; and air inlets are formed in the fixing flange and the second sealing flange and are connected with the air supply device.

The supporting rotating shaft comprises an upper supporting rod, a lower supporting rod and a roller, the roller is connected between the two supporting rods, the two supporting rods are fixed to the top and the bottom of the bin body respectively, the roller penetrates through one end of the rotary hearth, and the roller can support the rotary hearth and does not block the rotary hearth from rotating.

And the inner wall of the bin body is provided with a cooling water jacket, namely the outer sides of the vacuum reaction chamber and the rotary collecting chamber are provided with the cooling water jacket for cooling the whole bin body. The cooling water jacket is connected with an external water supply device, such as a water cooler, through a pipeline.

The vacuum device is communicated with the air pumping hole of the bin body through a pipeline to vacuumize the bin body. The vacuum device comprises a vacuum pump and a vacuum measuring meter, the vacuum pump is arranged outside the bin body, and the vacuum measuring meter is respectively arranged inside the reaction cavity and the rotary hearth.

The vacuum pump is selected from one or more of a dry mechanical pump, an oil seal mechanical pump, an adsorption pump, a diffusion pump, a sublimation pump, a turbo molecular pump, a composite turbo pump, a low-temperature condensation pump and a roots pump.

The vacuum gauge is selected from one or more of a Michelo vacuum gauge, a heat conduction vacuum gauge and an ionization vacuum gauge.

The transmission device comprises a transmission motor, a transmission chain and a transmission shaft, and the transmission motor is arranged outside the bin body and used for providing rotary power; the transmission chain is arranged between the transmission motor and the transmission shaft and is used for connecting the transmission motor and the transmission shaft and driving the transmission shaft to move; the transmission shaft is a hollow rotating shaft, penetrates through the rotary sealing shaft and is mechanically connected with the fixed flange to drive the rotary collecting chamber to rotate.

The gas supply device is communicated with the rotary hearth of the rotary collecting chamber through a pipeline and is used for introducing process gas. The gas supply device comprises a gas quick-connection pipeline and a gas mixing tank, the front end of the gas quick-connection pipeline is introduced into the rotary hearth of the rotary collecting bin, the rear end of the gas quick-connection pipeline is connected with the gas mixing tank, the front end of the gas quick-connection pipeline is arranged at the hollow position of the transmission shaft and sealed by a sealing ring, and a first vacuum ball valve is arranged on the gas quick-connection pipeline; the gas mixing tank is connected with a gas source.

The gas source comprises one or more of but not limited to C2-C4 alkynes, C1-C4 alkane gas sources, inert gases and reducing gases.

The tail gas treatment device is communicated with the vacuum reaction chamber of the bin body and is used for treating incompletely decomposed process gas in the coating process. The tail gas treatment device comprises a tail gas processor and a tail gas quick-connection pipeline, the tail gas processor is arranged outside the bin body and is connected with the exhaust port on the side face of the bin body through the tail gas quick-connection pipeline, and a second vacuum ball valve is arranged on the tail gas quick-connection pipeline.

Preferably, the high-temperature device further comprises a control device, the control device comprises a PLC controller, and the PLC controller is in communication connection with and controls the first temperature control component, the heating element, the second temperature control component, the prefabricated heating body, the vacuum meter, the vacuum pump, the external water supply device, the transmission motor, the first vacuum ball valve and the second vacuum ball valve.

The use method of the high-temperature device comprises the following steps:

(1) keeping the gas quick-connection pipeline and the tail gas quick-connection pipeline vacuum-sealed, putting a raw material of silicon monoxide into a reaction cavity of the vacuum reaction chamber, and putting a core material into a rotary hearth of the rotary collection chamber;

(2) sealing the first sealing flange, the fixing flange and the second sealing flange, and starting the vacuum device for vacuumizing; starting the transmission device, and rotating the collecting chamber;

(3) heating the heating layer of the vacuum reaction chamber to 1200-1600 ℃ to fully gasify the raw material of the silicon monoxide to obtain silicon monoxide steam;

(4) keeping the temperature for 5-25h, so that the silicon monoxide steam enters a rotary hearth of a rotary collecting chamber and is uniformly deposited on the surface of the inner core material to form a nano coating layer;

(5) opening the gas supply device and introducing process gas into the rotary collecting chamber, closing the vacuum device and opening the tail gas treatment device, adjusting the temperature of the rotary collecting chamber to 600-1000 ℃, preserving the heat for 2-5h, and carrying out carbon coating on the materials in the rotary collecting chamber;

(6) and stopping heating, cooling, closing the transmission device, and opening the first sealing flange, the fixed flange and the second sealing flange to obtain the lithium ion battery cathode material.

In the step (1), the core material is carbon, silicon, metal and metal oxide thereof; the metal and metal oxide include, but are not limited to, one of titanium, iron, manganese, germanium, tin and oxides thereof, preferably germanium, tin and oxides thereof.

Compared with the prior art, the utility model provides a high temperature device and preparation method have following beneficial effect:

the high-temperature device communicates the vacuum reaction chamber with the rotary collection chamber, and the deposition form of the silicon monoxide is adjusted by means of independent temperature control and rotary collection, so that the energy consumption of equipment is reduced, the product yield is improved, and the quality and batch stability of the silicon monoxide are effectively improved. The compounding of the silicon monoxide and other materials is completed in the same high-temperature space, and carbon coating is carried out, so that the problems of material loss, impurity doping and the like caused in the transferring and mixing processes before the silicon monoxide is compounded with other cathode materials are solved, and the problems of overlarge particles, structural damage and uneven mixing after the materials are compounded are solved. The lithium ion battery cathode material with good cycling stability and high energy density is produced by using the high-temperature device.

Drawings

Fig. 1 is a schematic structural view of the high temperature device in the embodiment of the present invention.

Fig. 2 is a perspective view of the high temperature device in the embodiment of the present invention.

In the attached drawing, 1-a cabin body, 101-a cooling water jacket, 102-a first sealing flange, 103-a second sealing flange, 1031-a rotary sealing shaft, 2-a vacuum reaction chamber, 201-a reaction chamber, 202-a heating layer, 203-a first heat preservation layer, 3-a rotary collection chamber, 301-a rotary hearth, 3011-a material guide plate, 3012-a fixed flange, 302-a prefabricated heating body, 303-a second heat preservation layer, 304-a supporting rotating shaft, 4-a vacuum device, 5-a transmission device, 501-a transmission motor, 502-a transmission chain, 503-a transmission shaft, 6-a gas supply device, 601-a gas mixing tank, 602-a gas quick-connection pipeline, 6021-a first vacuum ball valve, 7-a tail gas treatment device and 701-a tail gas treater, 702-tail gas quick-connection pipeline, 7021-second vacuum ball valve.

Detailed Description

Example 1

The embodiment provides a high-temperature device for preparing a lithium ion battery cathode material, which comprises a bin body 1, and a vacuum device 4, a transmission device 5, an air supply device 6 and a tail gas treatment device 7 which are connected with the bin body; the bin body 1 comprises a vacuum reaction chamber 2 and a rotary collecting chamber 3, the front end of the rotary collecting chamber 3 is communicated with the vacuum reaction chamber 2, the rear end of the rotary collecting chamber 3 is respectively connected with a vacuum device, a transmission device and an air supply device, and a tail gas treatment device 7 is connected with the vacuum reaction chamber; the vacuum reaction chamber 2 and the rotary collecting chamber 3 are respectively provided with an independent heating device, and the temperatures of the vacuum reaction chamber and the rotary collecting chamber can be independently controlled.

The vacuum reaction chamber 2 is used for heating and gasifying the silicon monoxide raw material under the vacuum condition. The vacuum reaction chamber 2 comprises a reaction cavity 201, a heating layer 202 and a first heat preservation layer 203 from inside to outside in sequence; the reaction chamber 201 is used for containing a raw material of silicon monoxide; the heating layer 202 surrounds the outside of the reaction chamber, and a heating element is arranged in the heating layer for heating the raw materials in the reaction chamber; the first heat insulation layer 203 surrounds the heating layer for heat insulation and heat preservation of the vacuum reaction chamber 2.

Preferably, reaction chamber 201 is the crucible, and high temperature resistance is excellent, is applicable to the utility model discloses an inorganic raw materials's high temperature heating.

The reaction chamber 201 is provided with a first temperature control component inside, and the first temperature control component is connected with the heating element of the heating layer 202 to control the heating temperature.

The top of the vacuum reaction chamber 2 is provided with a top opening, the top opening is provided with a first sealing flange 102, and the communication and the sealing between the reaction cavity 201 and the outside are controlled.

And an exhaust port is arranged at the upper part of the side wall of the vacuum reaction chamber 2 and is communicated with the reaction cavity and the tail gas treatment device 7.

In a specific embodiment of the present invention, the innermost reaction chamber 201 of the vacuum reaction chamber 2 is a crucible, when in use, a raw material of silicon monoxide is placed in the crucible, the outer side of the crucible is an electric heating layer, the crucible can bear a heating temperature of more than 1000 ℃ for gasifying the silicon monoxide, a first temperature control component is arranged inside the crucible, and the first temperature control component is connected with the electric heating layer and controls the heating temperature of the electric heating layer; the outer side of the electric heating layer is provided with a first heat preservation layer 203, and the first heat preservation layer is specifically a foam heat preservation layer, so that the heat insulation and heat preservation of the reaction cavity 201 are ensured, and the overhigh temperature outside the reaction cavity is avoided; the top of the crucible is provided with a top opening, the top opening enables the crucible to be communicated with the external environment, but the tops of the electric heating layer and the foam heat insulation layer are not communicated with the external environment, and the electric heating layer and the foam heat insulation layer form independent cavity spaces respectively; and an exhaust port is arranged at the upper part of the side wall of the vacuum reaction chamber 2 and is communicated with the reaction cavity 201 and the tail gas treatment device 7.

The rotary collecting chamber 3 is used for coating the surface of the core material with the gasified silicon monoxide and collecting the final cathode material product. The rotary collecting chamber 3 sequentially comprises a rotary hearth 301, a prefabricated heating body 302, a second insulating layer 303 and a supporting rotating shaft 304 from inside to outside; the front end of the rotary hearth 301 is communicated with the side surface of the reaction chamber 201, and a plurality of material guide plates 3011 are arranged in the rotary hearth 301, one end of each material guide plate is fixed on the inner wall of the rotary hearth 301, and the other end of each material guide plate extends into the rotary hearth 301 and is suspended in the air to drive the materials to move at a constant speed; the supporting rotating shafts 304 are arranged at two ends of the rotary hearth, and are used for supporting the rotary hearth 301 and assisting the rotary hearth to rotate. The prefabricated heating bodies 302 are uniformly arranged outside the rotary hearth 301 and used for heating materials in the rotary hearth in a rotary mode. The second insulating layer 303 surrounds the exterior of the prefabricated heating body 302 and is used for insulating heat and preserving heat of the rotary hearth.

The shape of the cross section of the rotary hearth 301 is selected from a circle, an ellipse, a square or other polygons, and preferably, the shape of the cross section of the rotary hearth 301 is a circle or an ellipse.

Preferably, rotary hearth 301 is the crucible, and high temperature resistance is excellent, is applicable to the utility model discloses a high temperature heating of inorganic raw materials.

Preferably, the material guide plates 3011 are arranged in the rotary hearth 301 in a staggered manner, so as to improve the disorder degree of the materials in the rotary hearth 301 and promote the gas-phase silicon monoxide, the core material and the process gas provided by the gas supply device 6 to fully contact and react.

The angle between the material guide plate 3011 and the inner wall of the rotary hearth 301 is 20-90 degrees.

More preferably, the ratio of the length of the material guide plate 3011 to the inner diameter of the rotary hearth 301 is 1: (3-5).

And a second temperature control component is arranged in the rotary hearth 301 and is connected with the prefabricated heating body 302 to control the heating temperature of the prefabricated heating body.

The rear end of the rotary hearth 301 is provided with a fixed flange 3012, the fixed flange is mechanically connected with the transmission device 5, and the rotary hearth 301 is sealed and driven by a transmission shaft 503 of the transmission device 5 to rotate.

The rear end of the rotary collecting chamber 3 is provided with a side end opening, the side end opening is provided with a second sealing flange 103, and the rotary collecting chamber 3 is controlled to be communicated and sealed with the outside. A rotary seal shaft 1031 is arranged in the disc body of the second seal flange 103 and is used for vacuum dynamic sealing of the transmission shaft 503. The sealing form of the rotating seal shaft 1031 includes, but is not limited to, one or more combinations of solid contact dynamic seal, liquid vacuum dynamic seal, or magnetic fluid vacuum dynamic seal.

The rear end of the rotary collecting chamber 3 is provided with an air pumping hole, and the air pumping hole is connected with the vacuum device 4; and air inlets are formed in the fixing flange 3012 and the second sealing flange 103 and are connected with the air supply device 6.

The supporting rotating shaft 304 comprises an upper supporting rod, a lower supporting rod and a roller, the roller is connected between the two supporting rods, the two supporting rods are respectively fixed at the top and the bottom of the inner wall of the bin body 1, the roller penetrates through one end of the rotary hearth 301, and the roller can support the rotary hearth 301 and does not block the rotary hearth from rotating.

In a specific embodiment of the present invention, the innermost rotary hearth 301 of the rotary collecting chamber 3 is a cylindrical crucible, when in use, the crucible is placed with the inner core material, the outer side of the crucible is a prefabricated heating body 302, which can adopt an electric heating form, the crucible can bear a heating temperature above 1000 ℃, so as to keep the gasification of the silicon monoxide, and facilitate the uniform coating of the gas phase silicon monoxide and the inner core material; the outer side of the prefabricated heating body 302 is provided with a second heat insulation layer 303, and the second heat insulation layer is specifically a foam heat insulation layer, so that heat insulation and heat preservation of the rotary hearth 301 are ensured, and overhigh external temperature of the rotary hearth is avoided. And a second temperature control component is arranged in the rotary hearth and is connected with the prefabricated heating body 302 to control the heating temperature of the prefabricated heating body. The front end of the rotary hearth is communicated with the side surface of the reaction cavity 201, 16 material guide plates 3011 are arranged in the rotary hearth, one end of each material guide plate is fixed on the inner wall of the rotary hearth, and the other end of each material guide plate vertically extends into the rotary hearth and is suspended in the air so as to drive materials to move at a constant speed; the material guide plates 3011 are uniformly staggered on the upper, lower, left and right side surfaces of the cylindrical crucible; the ratio of the length of the material guide plate 3011 to the inner diameter of the rotary hearth 301 is 1: 3. the rear end of the rotary hearth is provided with a fixed flange 3012, the fixed flange is mechanically connected with the transmission shaft 503 of the transmission device 5, and the rotary hearth is enabled to rotate along with the transmission shaft 503. The two ends of the prefabricated heating body 302 and the second heat-insulating layer 303 are not communicated with the space in the bin body 1, and the prefabricated heating body 302 and the second heat-insulating layer 303 respectively form independent chamber spaces and rotate together with the rotary hearth 301. The two sets of supporting rotating shafts 304 are respectively arranged at two ends of the outer part of the rotary hearth 301, each set of supporting rotating shaft 304 comprises an upper supporting rod, a lower supporting rod and a roller, the roller is connected between the two supporting rods, the two supporting rods are respectively fixed at the top and the bottom of the inner wall of the bin body 1, and the front end and the rear end of the rotary hearth respectively penetrate through one roller, so that the rotary hearth rotates in the two rollers. The rear end of the rotary collecting chamber 3 is provided with a side end opening, the side end opening is provided with a second sealing flange 103 for controlling the communication and the sealing between the rotary collecting chamber 3 and the outside, and a rotary sealing shaft 1031 for liquid type vacuum dynamic sealing of the transmission shaft 503 is arranged in a disc body of the second sealing flange 103. The rear end of the rotary collecting chamber 3 is provided with an air pumping hole, namely the rear end of the bin body 1 is provided with an air pumping hole which is connected with the vacuum device 4; all be equipped with the air inlet on mounting flange 3012 and the second sealed flange 103, gaseous fast pipeline 602 passes second sealed flange and mounting flange through two air inlets in proper order, gets into rotary hearth, gaseous fast pipeline 602 with gas supply unit 6 is connected.

The inner wall of the bin body 1 is provided with a cooling water jacket 101, namely the outer sides of the vacuum reaction chamber 2 and the rotary collecting chamber 3 are provided with the cooling water jacket 101 for cooling the whole bin body 1. The cooling water jacket 101 is connected to an external water supply device, such as a water chiller, through a pipe.

The vacuum device 4 is communicated with the air extraction opening of the bin body 1 through a pipeline to vacuumize the bin body 1. The vacuum device 4 comprises a vacuum pump and a vacuum meter, the vacuum pump is arranged outside the bin body, and the vacuum meter is respectively arranged inside the reaction chamber 201 and the rotary hearth 301.

The vacuum pump is selected from one or more of a dry mechanical pump, an oil seal mechanical pump, an adsorption pump, a diffusion pump, a sublimation pump, a turbo molecular pump, a composite turbo pump, a low-temperature condensation pump and a roots pump.

The vacuum gauge is selected from one or more of a Michelo vacuum gauge, a heat conduction vacuum gauge and an ionization vacuum gauge.

The transmission device 5 comprises a transmission motor 501, a transmission chain 502 and a transmission shaft 503, wherein the transmission motor 501 is arranged outside the bin body 1 and is used for providing rotary power; the transmission chain 502 is arranged between the transmission motor 501 and the transmission shaft 503, and is used for connecting the transmission motor and the transmission shaft and driving the transmission shaft to move; the transmission shaft 503 is a hollow rotating shaft, penetrates through the rotary seal shaft 1031 and is mechanically connected with the fixed flange 3012 to drive the rotary collection chamber 3 to rotate.

The gas supply device 6 is communicated with the rotary hearth 301 of the rotary collecting chamber through a gas quick-connection pipeline 602 and is used for introducing process gas. The gas supply device 6 comprises a gas quick-connection pipeline 602 and a gas mixing tank 601, the front end of the gas quick-connection pipeline 602 is introduced into a rotary hearth of the rotary collecting bin, the rear end of the gas quick-connection pipeline is connected with the gas mixing tank 601, the front end of the gas quick-connection pipeline 602 is arranged at the hollow position of the transmission shaft 503 and sealed by a sealing ring, and a first vacuum ball valve 6021 is arranged on the gas quick-connection pipeline 602; the gas mixing tank 601 is connected with a gas source.

The gas source comprises one or more of but not limited to C2-C4 alkynes, C1-C4 alkane gas sources, inert gases and reducing gases.

The tail gas treatment device 7 is communicated with the vacuum reaction chamber 2 of the bin body and is used for treating incompletely decomposed process gas in the coating process. The tail gas treatment device 7 comprises a tail gas processor 701 and a tail gas quick-connection pipeline 702, the tail gas processor 701 is arranged outside the bin body 1, the tail gas quick-connection pipeline 702 is connected with the exhaust port on the side face of the bin body, and a second vacuum ball valve 7021 is arranged on the tail gas quick-connection pipeline 702.

Preferably, the high-temperature device further comprises a control device, wherein the control device comprises a PLC controller, and the PLC controller is in communication connection with and controls the first temperature control component, the heating element, the second temperature control component, the prefabricated heating body 302, the vacuum meter, the vacuum pump, the external water supply device, the transmission motor 501, the first vacuum ball valve 6021 and the second vacuum ball valve 7021; the PLC controller presets standard data of reaction chamber temperature, rotary hearth temperature, vacuum degree and rotary speed, the first temperature control component and the second temperature control component respectively collect actual reaction chamber temperature and rotary hearth temperature and transmit the actual reaction chamber temperature and rotary hearth temperature to the PLC controller, the PLC controller compares the actual reaction chamber temperature and rotary hearth temperature with the preset standard reaction chamber temperature and rotary hearth temperature, the heating element and the prefabricated heating body 302 are operated to carry out heating, cooling or heat preservation operation, and an external water supply device is operated to supply cooling water; the vacuum measuring meter collects the pressure of the actual reaction chamber and the pressure of the actual rotary hearth, transmits the pressure to the PLC, compares the pressure with a preset standard vacuum degree, and operates the vacuum pump to perform vacuum pumping operation; the driving motor 501 transmits an actual revolution speed, and the driving motor 501 is operated to change the revolution speed in comparison with a preset standard revolution speed. The PLC controller controls the supply of the process gas and the extraction of the tail gas by controlling the opening degree of the first vacuum ball valve 6021 and the second vacuum ball valve 7021.

The above-mentioned embodiments, further detailed description of the objects, technical solutions and advantages of the present invention, it should be understood that the above description is only the embodiments of the present invention, and is not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements, etc. made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (10)

1. The high-temperature device for preparing the lithium ion battery cathode material is characterized by comprising a vacuum reaction chamber and a rotary collecting chamber, wherein the vacuum reaction chamber sequentially comprises a reaction cavity, a heating layer and a first heat preservation layer from inside to outside; the rotary collecting chamber sequentially comprises a rotary hearth, a prefabricated heating body and a second heat-insulating layer from inside to outside; the front end of the rotary hearth is communicated with the reaction cavity, the vacuum reaction chamber and the rotary collecting chamber are respectively provided with an independent heating device, and the temperatures of the vacuum reaction chamber and the rotary collecting chamber can be independently controlled.

2. The high temperature device of claim 1, wherein the heating layer is internally provided with a heating element; the reaction chamber is internally provided with a first temperature control part, and the first temperature control part is connected with the heating element to control the heating temperature.

3. The high temperature device of claim 2, wherein the vacuum reaction chamber is provided with a top opening at the top, and the top opening is provided with a first sealing flange.

4. The high-temperature device as claimed in claim 2, wherein a plurality of material guiding plates are arranged inside the rotary hearth, one end of each material guiding plate is fixed on the inner wall of the rotary hearth, and the other end of each material guiding plate extends into the rotary hearth and is suspended in the air so as to drive the materials to move at a constant speed.

5. The high-temperature device as claimed in claim 4, wherein the material guiding plates are arranged in the rotary hearth in a staggered manner, and the angle between the material guiding plates and the inner wall of the rotary hearth is 20-90 degrees;

the ratio of the length of the material guide plate to the inner diameter of the rotary hearth is 1: (3-5).

6. The high temperature device of claim 4, wherein the rotary collection chamber further comprises support shafts provided at both ends of the rotary hearth;

the supporting rotating shaft comprises an upper supporting rod, a lower supporting rod and a roller, the roller is connected between the two supporting rods, the two supporting rods are respectively fixed at the top and the bottom of the inner wall of the rotary collecting chamber, the roller penetrates through one end of the rotary hearth, and the roller can support the rotary hearth and does not block the rotary hearth from rotating.

7. The high-temperature device as claimed in claim 4, wherein a second temperature control component is arranged inside the rotary hearth, and the second temperature control component is connected with the prefabricated heating body and used for controlling the heating temperature of the prefabricated heating body.

8. The high temperature device of claim 7, wherein the rear end of the rotary hearth is provided with a fixed flange;

the rear end of the rotary collecting chamber is provided with a side end opening, a second sealing flange is arranged at the side end opening, a rotary sealing shaft is arranged in a disc body of the second sealing flange, and the fixing flange and the second sealing flange are used for being connected with a transmission device in a sealing mode.

9. The high-temperature device as claimed in claim 8, wherein the rear end of the rotary collecting chamber is provided with a suction port, and the suction port is connected with a vacuum device.

10. The high temperature device of claim 7, further comprising a control device comprising a PLC controller communicatively coupled to and controlling the first temperature control member, the heating element, the second temperature control member, and the pre-fabricated heating body.

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