CN216704383U - Graphite reaction kettle - Google Patents

Abstract

The utility model discloses a graphite reaction kettle, which comprises: the fixed base is used for fixing the graphite reaction kettle; the supporting structure is arranged on the upper surface of the fixed base and is used for supporting the graphite reaction kettle; a heat exchange structure disposed on a support structure, the heat exchange structure being configured to provide an energy source; the utility model relates to the field of graphite reaction kettles, in particular to a bearing structure which is arranged on a heat exchange structure and used for bearing graphite.

Description

Graphite reaction kettle

Technical Field

The utility model relates to the field of graphite reaction kettles, in particular to a graphite reaction kettle.

Background

The spherical graphite material has the characteristics of good conductivity, high crystallinity, low cost, high theoretical lithium intercalation capacity, low and flat charge-discharge potential and the like, is an important part of a lithium ion battery cathode material, and is a replacement product of the cathode material for the production of lithium ion batteries at home and abroad. The conductive material has excellent conductivity and chemical stability, high charge and discharge capacity, long cycle life and environmental protection.

The current graphite reation kettle reaction effect is not good, need consume a large amount of energy, and the material quality in the container is influenced very easily with pressure to not good control temperature moreover, consequently in order to solve this problem, designs a graphite reation kettle very necessary.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model provides a graphite reaction kettle, which solves the problems that the existing graphite reaction kettle has poor reaction effect, needs to consume a large amount of energy, does not control temperature and pressure well and is easy to influence the quality of materials in a container.

In order to achieve the purpose, the utility model is realized by the following technical scheme: a graphite reaction kettle, comprising:

the fixed base is used for fixing the graphite reaction kettle;

the supporting structure is arranged on the upper surface of the fixed base and is used for supporting the graphite reaction kettle;

a heat exchange structure disposed on a support structure, the heat exchange structure being configured to provide an energy source;

the bearing structure is arranged on the heat exchange structure and is used for bearing graphite;

the stirring structure is arranged on the bearing structure, extends into the bearing structure and is used for stirring graphite;

the detection structure is arranged on the bearing structure and is used for detecting the temperature and the pressure in the bearing structure;

the cooling structure is arranged on the bearing structure and used for controlling the temperature in the bearing structure.

Preferably, the support structure comprises: a pair of door-shaped supporting frames and an annular fixing plate;

the pair of door-shaped supporting frames is arranged on the upper surface of the fixed base, and the annular fixing plate is arranged on the upper ends of the side surfaces of the pair of door-shaped supporting frames.

Preferably, the heat exchange structure includes: the device comprises a heat exchange shell, an air inlet pipe, a joint and a condensate water recovery part;

the heat exchange shell is arranged on the annular fixing plate, the air inlet pipe is arranged on the heat exchange shell, the joint is arranged on the air inlet pipe, and the condensed water recovery part is arranged on the heat exchange shell.

Preferably, the condensed water recovery unit includes: the device comprises a condensed water discharge pipe, a first fixing frame, a bearing water tank, a water outlet pipe and a valve;

the condensed water discharge pipe is arranged on the lower surface of the heat exchange shell, the first fixing frame is arranged on the upper surface of the fixing base, the bearing water tank is arranged on the first fixing frame, the condensed water discharge pipe is connected with the bearing water tank, the water outlet pipe is arranged on the bearing water tank, and the valve is arranged on the water outlet pipe.

Preferably, the load bearing structure comprises: the device comprises a bearing box body, a feeding hopper, a buckle cover, a discharging pipe, an electric control valve and a pressure release valve;

the bearing box body is arranged on the heat exchange shell, the feeding hopper is arranged on the upper surface of the bearing box body, the buckling cover is arranged on the feeding hopper, the discharging pipe is arranged on the lower surface of the bearing box body, the electric control valve is arranged on the discharging pipe, and the pressure release valve is arranged on the bearing box body.

Preferably, the stirring structure includes: the stirring device comprises a second fixing frame, a first rotating motor, a first stirring rod, a pair of third fixing frames, a pair of second rotating motors and a pair of second stirring rods;

the second fixing frame is arranged at the center of the upper surface of the bearing box body, the first rotating motor is arranged on the second fixing frame, the rotating end of the first rotating motor extends into the rectangular box body, the first stirring rod is arranged on the rotating end of the first rotating motor, the pair of third fixing frames are arranged on the lower surface of the bearing box body, each second rotating motor is arranged on the corresponding third fixing frame, the rotating end of each second rotating motor extends into the rectangular box body, and each second stirring rod is arranged on the rotating end of the corresponding second rotating motor.

Preferably, the detection structure includes: the fourth fixing frame, the temperature detector and the pressure gauge;

the fourth fixing frame is arranged on the bearing box body, the temperature detector is arranged on the fourth fixing frame and communicated with the inside of the bearing box body, and the pressure gauge is arranged on the bearing box body.

Preferably, the cooling structure comprises: a pair of ventilation ducts, a pair of fifth fixing frames, a pair of heat dissipation fans and a pair of blocking grids;

the pair of ventilating ducts are arranged on the bearing box body, each ventilating duct is connected with the bearing box body, each fifth fixing frame is arranged on the corresponding ventilating duct, each heat dissipation fan is arranged on the corresponding fifth fixing frame, and each blocking grid is arranged in the corresponding ventilating duct.

Preferably, the fixed base is provided with a controller, and the fixed base is provided with a mains supply interface.

Advantageous effects

The utility model provides a graphite reaction kettle. The method has the following beneficial effects: this graphite reation kettle can be better react graphite, and is very convenient, and it is troublesome to have reduced unnecessary, has reduced the consumption of the energy, and temperature and pressure in the control bearing container that can be better have guaranteed the quality, and the structure is simple relatively, convenient to use.

Drawings

FIG. 1 is a schematic structural diagram of a graphite reaction kettle according to the present invention.

FIG. 2 is a front view structural diagram of a graphite reaction kettle according to the present invention.

FIG. 3 is a front view of a graphite reactor according to the present invention.

FIG. 4 is a side view of a graphite reactor according to the present invention.

FIG. 5 is a partial schematic view of a graphite reactor according to the present invention.

In the figure: 1-fixing a base; 2-a support structure; 3-a heat exchange structure; 4-a load-bearing structure; 5-a stirring structure; 6-detection of the structure; 7-a cooling structure; 8-a controller; 9-mains supply interface; 201-door type support frame; 202-annular fixed plate; 301-heat exchange housing; 302-an intake pipe; 303-a linker; 304-condensate drain pipe; 305-a first mount; 306-a carrier tank; 307-water outlet pipe; 308-a valve; 401-carrying case; 402-a feed hopper; 403-cover; 404-a discharge pipe; 405-an electrically controlled valve; 406-pressure relief valve; 501-a second fixing frame; 502-a first rotating electrical machine; 503-a first stirring rod; 504-a third mount; 505 — a second rotating electrical machine; 506-a second stirring rod; 601-a fourth mount; 602-temperature detector; 603-pressure gauge; 701-ventilating duct; 702-a fifth mount; 703-a heat dissipation fan; 704-a stopping grid.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a graphite reaction kettle, comprising: the device comprises a fixed base 1, wherein the fixed base 1 is used for fixing a graphite reaction kettle; the supporting structure 2 is arranged on the upper surface of the fixed base 1, and the supporting structure 2 is used for supporting the graphite reaction kettle; the heat exchange structure 3 is arranged on the support structure 2, and the heat exchange structure 3 is used for providing energy; the bearing structure 4 is arranged on the heat exchange structure 3, and the bearing structure 4 is used for bearing graphite; the stirring structure 5 is arranged on the bearing structure 4, and the stirring structure 5 extends into the bearing structure 4 and is used for stirring graphite; the detection structure 6 is arranged on the bearing structure 4, and the detection structure 6 is used for detecting the temperature and the pressure in the bearing structure 4; cooling structure 7, cooling structure 7 settles on bearing structure 4, and cooling structure 7 is used for controlling the temperature in bearing structure 4.

The support structure 2 comprises: a pair of gate-shaped supporting frames 201 and a ring-shaped fixing plate 202; a pair of door-shaped supporting frames 201 are arranged on the upper surface of the fixed base 1, and an annular fixing plate 202 is arranged on the upper ends of the side surfaces of the pair of door-shaped supporting frames 201.

The heat exchange structure 3 includes: a heat exchange shell 301, an air inlet pipe 302, a joint 303 and a condensed water recovery part; the heat exchange housing 301 is mounted on the annular fixing plate 202, the air inlet pipe 302 is mounted on the heat exchange housing 301, the joint 303 is mounted on the air inlet pipe 302, and the condensed water recovery portion is mounted on the heat exchange housing 301.

The condensed water recovery unit includes: a condensed water discharge pipe 304, a first fixing frame 305, a bearing water tank 306, a water outlet pipe 307 and a valve 308; the condensed water discharge pipe 304 is disposed on the lower surface of the heat exchange housing 301, the first fixing frame 305 is disposed on the upper surface of the fixing base 1, the water tank 306 is disposed on the first fixing frame 305, the condensed water discharge pipe 304 is connected to the water tank 306, the water outlet pipe 307 is disposed on the water tank 306, and the valve 308 is disposed on the water outlet pipe 307.

The load bearing structure 4 comprises: a bearing box body 401, a feeding funnel 402, a buckle cover 403, a discharge pipe 404, an electric control valve 405 and a pressure release valve 406; bearing box 401 is arranged on heat exchange shell 301, feeding funnel 402 is arranged on the upper surface of bearing box 401, cover 403 is arranged on feeding funnel 402, discharging pipe 404 is arranged on the lower surface of bearing box 401, electric control valve 405 is arranged on discharging pipe 404, and pressure relief valve 406 is arranged on bearing box 401.

The stirring structure 5 includes: a second holder 501, a first rotating electric machine 502, a first stirring rod 503, a pair of third holders 504, a pair of second rotating electric machines 505, and a pair of second stirring rods 506; the second fixing frame 501 is arranged at the center of the upper surface of the bearing box 401, the first rotating electric machine 502 is arranged on the second fixing frame 501, the rotating end of the first rotating electric machine 502 extends into the rectangular box, the first stirring rod 503 is arranged on the rotating end of the first rotating electric machine 502, the pair of third fixing frames 504 is arranged on the lower surface of the bearing box 401, each second rotating electric machine 505 is arranged on the corresponding third fixing frame 504, the rotating end of each second rotating electric machine 505 extends into the rectangular box, and each second stirring rod 506 is arranged on the rotating end of the corresponding second rotating electric machine 505.

The detection structure 6 includes: a fourth fixing frame 601, a temperature detector 602 and a pressure gauge 603; the fourth fixing frame 601 is disposed on the carrying case 401, the temperature detector 602 is disposed on the fourth fixing frame 601, the temperature detector 602 is communicated with the inside of the carrying case 401, and the pressure gauge 603 is disposed on the carrying case 401.

The temperature reducing structure 7 includes: a pair of ventilation ducts 701, a pair of fifth fixing frames 702, a pair of heat dissipation fans 703, and a pair of blocking grids 704; a pair of ventilation ducts 701 is disposed on the carrying case 401, each ventilation duct 701 is connected to the carrying case 401, each fifth fixing frame 702 is disposed on the corresponding ventilation duct 701, each heat dissipation fan 703 is disposed on the corresponding fifth fixing frame 702, and each blocking mesh 704 is disposed in the corresponding ventilation duct 701.

The fixed base 1 is provided with a controller 8, and the fixed base 1 is provided with a mains supply interface 9.

The embodiment is as follows: the fixed base 1 is used for fixing a graphite reaction kettle, the supporting structure 2 on the upper surface of the fixed base 1 is used for supporting the graphite reaction kettle, the heat exchange structure 3 on the supporting structure 2 is used for providing energy, the bearing structure 4 on the heat exchange structure 3 is used for bearing graphite, the stirring structure 5 on the bearing structure 4 extends into the bearing structure 4 and is used for stirring the graphite, the detection structure 6 on the bearing structure 4 is used for detecting the temperature and the pressure in the bearing structure 4, the cooling structure 7 on the bearing structure 4 is used for controlling the temperature in the bearing structure 4, firstly, the commercial power interface 9 on the fixed base 1 is connected with a power supply, the controller 8 on the fixed base 1 is opened, the door-shaped supporting frame 201 and the annular fixing plate 202 on the fixed base 1 are used for supporting, the buckle cover 403 on the feeding funnel 402 is opened, and materials are fed into the bearing box body 401 through the feeding funnel 402, then, a pipeline is connected through a connector 303 on an air inlet pipe 302, hot steam is sent into a heat exchange shell 301 through the air inlet pipe 302 to be heated, then condensed water is discharged into a bearing water tank 306 on a first fixing frame 305 through a condensed water discharge pipe 304, the condensed water is discharged through a water outlet pipe 307, a valve 308 on the water outlet pipe 307 is controlled, meanwhile, a first rotating motor 502 on a second fixing frame 501 and a second rotating motor 505 on a third fixing frame 504 are opened through a controller 8 on a fixed base 1, the first rotating motor 502 on the second fixing frame 501 drives a first stirring rod 503 to stir, the second rotating motor 505 on the third fixing frame 504 drives a second stirring rod 506 to stir, so that graphite is subjected to full reaction, meanwhile, a temperature detector 602 on the fourth fixing frame 601 and a pressure gauge 603 are started to detect the temperature and the pressure in the bearing box 401, and when the pressure is too high, the pressure release valve 406 on the bearing box 401 is opened to release the pressure, and when the temperature is too high, the heat radiation fan 703 on the fifth fixing frame 702 in the ventilation pipeline 701 is opened to radiate the heat, which is very convenient.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation. The use of the phrase "comprising one of the elements does not exclude the presence of other like elements in the process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. A graphite reaction kettle is characterized by comprising:

the fixing base (1), the said fixing base (1) is used for fixing the graphite reaction kettle;

the supporting structure (2), the supporting structure (2) is arranged on the upper surface of the fixed base (1), and the supporting structure (2) is used for supporting the graphite reaction kettle;

a heat exchange structure (3), the heat exchange structure (3) being arranged on a support structure (2), and the heat exchange structure (3) being adapted to provide an energy source;

the bearing structure (4), the bearing structure (4) is arranged on the heat exchange structure (3), and the bearing structure (4) is used for bearing graphite;

the stirring structure (5) is arranged on the bearing structure (4), and the stirring structure (5) extends into the bearing structure (4) and is used for stirring graphite;

a detection structure (6), the detection structure (6) being disposed on the carrying structure (4), and the detection structure (6) being configured to detect a temperature and a pressure within the carrying structure (4);

the cooling structure (7) is arranged on the bearing structure (4), and the cooling structure (7) is used for controlling the temperature in the bearing structure (4).

2. A graphite reactor kettle according to claim 1, wherein said support structure (2) comprises: a pair of door-shaped supporting frames (201) and an annular fixing plate (202);

the pair of door-shaped supporting frames (201) is arranged on the upper surface of the fixed base (1), and the annular fixed plate (202) is arranged on the upper ends of the side surfaces of the pair of door-shaped supporting frames (201).

3. A graphite reactor kettle according to claim 2, wherein said heat exchange structure (3) comprises: the device comprises a heat exchange shell (301), an air inlet pipe (302), a joint (303) and a condensed water recovery part;

the heat exchange shell (301) is arranged on the annular fixing plate (202), the air inlet pipe (302) is arranged on the heat exchange shell (301), the joint (303) is arranged on the air inlet pipe (302), and the condensed water recovery part is arranged on the heat exchange shell (301).

4. A graphite reaction kettle according to claim 3, wherein the condensed water recovery part comprises: a condensed water discharge pipe (304), a first fixing frame (305), a bearing water tank (306), a water outlet pipe (307) and a valve (308);

the condensed water discharge pipe (304) is arranged on the lower surface of the heat exchange shell (301), the first fixing frame (305) is arranged on the upper surface of the fixing base (1), the bearing water tank (306) is arranged on the first fixing frame (305), the condensed water discharge pipe (304) is connected with the bearing water tank (306), the water outlet pipe (307) is arranged on the bearing water tank (306), and the valve (308) is arranged on the water outlet pipe (307).

5. A graphite reactor kettle according to claim 3, wherein said load bearing structure (4) comprises: the device comprises a bearing box body (401), a feeding hopper (402), a buckle cover (403), a discharging pipe (404), an electric control valve (405) and a pressure release valve (406);

the bearing box body (401) is arranged on the heat exchange shell (301), the feeding funnel (402) is arranged on the upper surface of the bearing box body (401), the buckling cover (403) is arranged on the feeding funnel (402), the discharging pipe (404) is arranged on the lower surface of the bearing box body (401), the electric control valve (405) is arranged on the discharging pipe (404), and the pressure relief valve (406) is arranged on the bearing box body (401).

6. A graphite reactor according to claim 5, wherein the stirring structure (5) comprises: a second fixing frame (501), a first rotating motor (502), a first stirring rod (503), a pair of third fixing frames (504), a pair of second rotating motors (505) and a pair of second stirring rods (506);

the second fixing frame (501) is arranged at the center of the upper surface of the bearing box body (401), the first rotating motor (502) is arranged on the second fixing frame (501), the rotating end of the first rotating motor (502) extends into the rectangular box body, the first stirring rod (503) is arranged on the rotating end of the first rotating motor (502), a pair of third fixing frames (504) is arranged on the lower surface of the bearing box body (401), each second rotating motor (505) is arranged on the corresponding third fixing frame (504), the rotating end of each second rotating motor (505) extends into the rectangular box body, and each second stirring rod (506) is arranged on the rotating end of the corresponding second rotating motor (505).

7. A graphite reaction kettle according to claim 5, characterized in that the detection structure (6) comprises: a fourth fixing frame (601), a temperature detector (602) and a pressure gauge (603);

the fourth fixing frame (601) is arranged on the bearing box body (401), the temperature detector (602) is arranged on the fourth fixing frame (601), the temperature detector (602) is communicated with the interior of the bearing box body (401), and the pressure gauge (603) is arranged on the bearing box body (401).

8. A graphite reactor kettle according to claim 5, wherein said temperature reducing structure (7) comprises: a pair of ventilation ducts (701), a pair of fifth fixing frames (702), a pair of heat dissipation fans (703) and a pair of blocking grids (704);

the pair of ventilation ducts (701) is arranged on the bearing box body (401), each ventilation duct (701) is connected with the bearing box body (401), each fifth fixing frame (702) is arranged on the corresponding ventilation duct (701), each heat dissipation fan (703) is arranged on the corresponding fifth fixing frame (702), and each blocking grid (704) is arranged in the corresponding ventilation duct (701).

9. The graphite reaction kettle according to claim 1, wherein a controller (8) is arranged on the fixed base (1), and a commercial power interface (9) is arranged on the fixed base (1).

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