KR102541088B1 - Vertical graphitization furnace system - Google Patents

Abstract

The present invention relates to a vertical graphitization furnace system which facilitates the flow of inert gas from the bottom to the top of a crucible tube, prevents leakage of exhaust gas generated inside the crucible tube to the outside, and sufficiently cools the produced graphite. The vertical graphitization furnace system comprises: a transport unit configured to transport and supply raw materials for graphitization; a drying unit connected to the transport unit to heat and dry the raw materials; a vertical graphitization furnace including a crucible tube connected to the drying unit and filled with the raw materials inside to perform graphitization treatment; a rotary cooling unit configured to cool graphite produced by the vertical graphitization furnace; a processing unit configured to transport the graphite cooled while passing through the rotary cooling unit to the outside and store the same; and a vacuum controller coupled to the crucible tube to facilitate the flow of inert gas in the crucible tube. The crucible tube includes a straight pipe part having a predetermined length in a vertical direction and a rectangular horizontal cross-section, the straight pipe part includes a plurality of rectangular crucible lines having a predetermined length in the vertical direction therein, the plurality of rectangular crucible lines fill the crucible tube in a state of being in close contact with each other, and the rectangular crucible line is disposed in close contact with one end of an inert gas pipe for supplying inert gas to a lower portion thereof.

Description

Vertical graphitization furnace system {Vertical graphitization furnace system}

The present invention relates to a vertical graphitization furnace system, and more particularly, to a vertical graphitization furnace system capable of uniformly forming an inert gas flow path in a crucible tube and improving the fluidity of manufactured artificial graphite when it is discharged. will be.

Artificial graphite is widely used in fields such as anode materials for secondary batteries, electrodes for iron and steel making, electric discharge machining electrodes, nuclear fusion reactors, semiconductors and solar cells.

Such artificial graphite has disadvantages of low graphitization and high price due to manufacturing process cost compared to natural graphite, but has a relatively excellent lifespan characteristic, and is particularly in the limelight as an anode material for secondary batteries.

In general, artificial graphite is mostly manufactured using an Acheson furnace. In other words, after putting the raw material in the crucible and charging it into the graphitization furnace, the crucible is covered with auxiliary materials such as resistance material and insulation material, and the crucible is heated at a high temperature of about 3000 ° C for 2 to 3 days, and goes through a natural cooling process and ancillary processes. are manufactured

However, this method requires a lot of crucibles, a lot of auxiliary equipment in manufacturing facilities, and there are problems such as cost increase due to replacement of crucibles, and the graphitization process is not continuous. Possible vertical graphitization furnaces are being developed.

For example, the inventors of the present application have disclosed a vertical graphitization furnace system in Patent Document 1 below.

As shown in FIG. 1, the vertical graphitization furnace system includes a conveying unit 100 for conveying and supplying raw materials for graphitization; A drying unit 200 connected to the transfer unit and comprising an intermediate hopper and a heating device to heat and dry the raw material; The crucible tube 310 connected to the drying unit and filled with raw materials to undergo graphitization, and the body portion 320 having a plurality of electrodes for heating the crucible tube 310, A vertical graphitization furnace 300 in which graphitization is performed; a rotary cooling unit 400 disposed horizontally to cool the graphite produced in the vertical graphitization furnace 300; and a processing unit 500 for transporting and storing the graphite cooled while passing through the rotary cooling unit 400 to the outside, wherein the input tube 10 is at the top of the crucible tube 310 and the discharge tube 20 is at the bottom. ) Is connected, the gas pipe 30 to which the inert gas is supplied is connected to one side of the discharge pipe 20, and is coupled to the crucible pipe 310 to facilitate the flow of the inert gas from the bottom to the top of the crucible pipe. It is characterized in that the controller 600 is provided.

Accordingly, the inert gas introduced into the crucible tube 3 flows more smoothly from the bottom to the top of the crucible tube 3 by the vacuum control unit 600, but the inert gas is supplied from one side of the discharge pipe 20 At this point, there is a problem in that the flow path is not evenly formed on a plane while the inert gas introduced into the discharge pipe 20 flows inside the crucible pipe 3.

As a result, on the side where the flow path of the inert gas is not formed, impurities generated from subsidiary materials easily contact the wall surface of the crucible tube 3, so that the inner surface of the crucible tube 3 deteriorates, shortening the life of the crucible tube 3 and manufacturing A problem that adversely affects the quality of the prepared graphite still remains.

Registered Patent Publication No. 10-2315610 (Announced on October 21, 2021)

An object to be solved by the present invention is to provide a vertical graphitization furnace system in which an inert gas flow path is evenly formed on a plane inside the crucible tube of the graphitization furnace and the flowability of the produced artificial graphite can be improved when discharged. .

In order to solve the above problems, the vertical graphitization furnace system of the present invention includes a transfer unit for transporting and supplying raw materials for graphitization, a drying unit connected to the transfer unit to heat and dry the raw material, and an internal connection to the drying unit A vertical graphitization furnace including a crucible tube in which raw materials are filled and graphitized, a rotary cooling unit for cooling the graphite produced in the vertical graphitization furnace, and the graphite cooled while passing through the rotation cooling unit to the outside. In the vertical graphitization furnace system including a processing unit for transporting and storing, and a vacuum control unit coupled to the crucible tube to facilitate the flow of inert gas in the crucible tube, the crucible tube has a predetermined length in the vertical direction and is horizontal a straight pipe section having a rectangular cross section, and a plurality of rectangular crucible lines having a predetermined length in a vertical direction are provided therein; The plurality of rectangular crucible lines are filled in the crucible tube in close contact with each other; One end of an inert gas pipe for supplying an inert gas to a lower portion of the rectangular crucible line is disposed adjacent to the crucible line.

In addition, in the vertical graphitization furnace system of the present invention, the rectangular crucible line is formed by stacking a plurality of rectangular unit crucibles in a vertical direction.

In addition, the vertical type graphitization furnace system of the present invention is composed of a structure in which the upper and lower portions of the rectangular unit crucible are open and the upper and lower portions are coupled to each other.

In addition, in the vertical type graphitization furnace system of the present invention, between each of the rectangular crucible lines and between the straight pipe portion of the crucible tube and the plurality of rectangular crucible lines are closely adhered so that no empty space is generated.

In addition, in the vertical graphitization furnace system of the present invention, each of the inert gas pipes is provided with a control valve having a pressure gauge, and each control valve is configured to equally supply the inert gas from each inert gas pipe to the rectangular crucible line. Control the pressure and flow rate individually.

In addition, the vertical graphitization furnace system of the present invention is composed of a rectangular parallelepiped having a predetermined height at the lower end of the straight pipe of the crucible tube, and a through hole smaller than the size of the rectangular crucible line is formed only in a position corresponding to the arrangement position of the rectangular crucible line. A graphite block pad is provided.

According to the vertical graphitization furnace system of the present invention, since the flow path of the inert gas from the bottom to the top of the crucible tube is evenly formed on a plane by a plurality of rectangular crucible lines, impurities generated from the raw material can be removed more reliably.

In addition, according to the vertical graphitization furnace system of the present invention, the fluidity of the artificial graphite product discharged from the bottom of the crucible tube after the graphitization treatment is improved by the uniform inert gas flow.

In addition, according to the vertical graphitization furnace system of the present invention, the above effects help to extend the life of the crucible tube and improve the quality of manufactured artificial graphite.

1 is a configuration diagram of a vertical graphitization furnace system according to the prior art.
2 is a vertical cross-sectional view of a crucible tube in a vertical graphitization furnace system according to an embodiment of the present invention.
3 is a horizontal cross-sectional view of a crucible tube in a vertical graphitization furnace system according to an embodiment of the present invention.

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

2 and 3, the vertical graphitization furnace system of the present invention includes a transfer unit 100 for transferring and supplying raw materials for graphitization, a drying unit 200 connected to the transfer unit to heat and dry the raw materials, and , Vertical graphitization furnace 300 connected to the drying unit and including a crucible tube 310 filled with raw materials and subjected to graphitization treatment, and a rotary cooling unit for cooling the graphite produced in the vertical graphitization furnace. 400, a processing unit 500 for transporting and storing cooled graphite to the outside through the rotary cooling unit 400, and an inert gas in the crucible tube 310 coupled to the crucible tube 310 In the vertical graphitization furnace system including a vacuum control unit 600 for smooth flow, the crucible tube 1 of the vertical graphitization furnace is provided with a plurality of rectangular crucible lines 20 therein, characterized in that do.

Hereinafter, specific contents of the present invention will be described for each configuration.

The transfer unit 100 is a configuration for transporting and supplying raw materials for graphitization, and the configuration of the transfer unit described in Patent Document 1 is used as it is.

That is, the transfer unit 100 includes a transfer hopper for storing raw materials in the form of pallets, a gate valve provided at an end of the transfer hopper, and a screw conveyor for supplying the raw material transferred from the gate valve to the drying unit.

The drying unit 200 is configured to heat and dry raw materials before inputting them into the vertical graphitization furnace 300, and the configuration of the drying unit described in Patent Document 1 is used as it is.

That is, the drying unit 200 includes an intermediate hopper and a heating device composed of a coil wound around the outer periphery of the intermediate hopper.

The vertical graphitization furnace 300 is installed vertically to graphitize raw materials, and most of the configurations of Patent Document 1 are used.

That is, the vertical graphitization furnace 300 is composed of a cylindrical container in which raw materials are filled and graphitized, and the top and bottom of the crucible tube are in the shape of a funnel with upper and lower sides, and the crucible tube is wrapped around the circumference. It consists of a body portion provided with a plurality of electrodes for heating the crucible tube as a cylindrical outer wall, and a cover provided on the upper portion of the body portion.

However, in the present invention, the detailed configuration of the crucible tube is changed in order to achieve the above-described problem.

Specifically, as shown in FIG. 2, the crucible tube 1 has a straight pipe part 10 having a predetermined length in the vertical direction and having a rectangular horizontal cross section, and an upper and lower narrow pipe expansion part formed on the upper part of the straight pipe part 10 ( 12), and a plurality of rectangular crucible lines 20 having a predetermined length in the vertical direction inside the straight pipe part 10, which are made of a shaft tube part 14 of the upper and lower sides formed under the straight pipe part 10. do.

The rectangular crucible line 20 is a configuration in which a raw material is filled and graphitized, and the horizontal cross section is made in a rectangular shape, and a plurality of rectangular crucible lines 20 are in close contact with each other inside the crucible tube 1 is filled in

At this time, between each of the rectangular crucible lines 20 and between the straight pipe part 10 of the crucible tube 1 and the plurality of rectangular crucible lines 20 are in close contact with each other so that no empty space is generated, and the plurality of rectangular crucible lines 20 are in close contact with each other. The crucible line 20 divides the space within the straight pipe 10 into n equal parts (n≥2, the maximum value of n is the size of the crucible tube and the rectangular determined by the size of the crucible line).

In addition, one end of an inert gas pipe 30 for supplying an inert gas to a lower portion thereof is disposed adjacent to the rectangular crucible line 20, and the crucible line 20 provides a flow passage for the supplied inert gas.

At this time, the inert gas pipe 30 is installed by drilling a connection hole 14a in the shrinkage pipe portion 14 of the crucible pipe 1 and inserting it therein.

In addition, the rectangular crucible line 20 is formed by stacking a plurality of rectangular unit crucibles 20' in a vertical direction, and the rectangular unit crucible 20' has upper and lower portions as shown in the enlarged portion of FIG. 2. It is composed of a structure in which the upper part and the lower part are coupled to each other while being open.

As described above, in the present invention, since the small size rectangular crucible lines 20 provided inside the crucible tube 1 serve as flow passages for the inert gas, the inert gas is supplied to the discharge tube and then flows only into the bottom of the large size crucible tube. The impurities generated from the raw material are removed more reliably than the prior art, which is made to flow freely to the top.

In addition, the artificial graphite product graphitized in the rectangular crucible line 20 falls freely to the bottom when discharged, in that the inert gas flows in a restrained state within the small-sized rectangular crucible line 20, the inert gas If the supply amount is the same, the voids caused by the inert gas in the artificial graphite in the small-sized rectangular crucible line 20 have an effect of generating much more than the voids caused by the inert gas in the artificial graphite in the large-sized crucible tube 1. When discharged, the fluidity of the artificial graphite product is greatly improved.

On the other hand, control valves 40 are provided in each of the inert gas pipes 30 disposed adjacent to the rectangular crucible line 20, and each control valve 40 is provided with a pressure gauge to individually measure the pressure and flow rate of the inert gas. configured to be controlled.

This is to equalize the supply of inert gas from each inert gas pipe 30 to the rectangular crucible line 20, and the density of the raw material or artificial graphite filled in each rectangular crucible line 20 is different from each other, resulting in a rectangular shape. Since inert gas cannot be evenly supplied to the crucible line 20, the pressure in each inert gas tube 30 connected to the rectangular crucible lines 20 is constantly checked and the flow rate in each inert gas tube 30 is controlled therefrom. will be.

Meanwhile, in the present invention, a graphite block pad 50 is further provided at the lower end of the straight tube part 10 of the crucible tube 1.

Specifically, the graphite block pad 50 is composed of a rectangular parallelepiped having a predetermined height, and a through hole 50a having a size smaller than the size of the rectangular crucible line 20 is formed only at a position corresponding to the position of the rectangular crucible line 20. is formed

Thus, the graphite block pad 50 supports the lower portions of the plurality of rectangular crucible lines 20, and the inert gas supplied from the inert gas pipe 30 flows in through the through holes 50a, and the through holes 50a Through this, the artificial graphite product manufactured in the crucible line 20 is discharged.

The rotational cooling unit 400 is arranged horizontally to cool the graphite produced in the vertical graphitization furnace 300, and the configuration of the rotational cooling unit described in Patent Document 1 is used as it is.

That is, the rotary cooling unit 400 is composed of a transfer drum providing a passage through which the graphite discharged from the lower part of the body of the vertical graphitization furnace flows in and out, and a spiral blade disposed inside the transfer drum. It consists of a rotor for transferring the graphite introduced into one side of the upper portion toward the transfer pipe, a drive unit for rotating the rotor, and a cooling channel for forcibly cooling the graphite moving inside the transfer drum.

The processing unit 500 transfers and stores cooled graphite to the outside through the rotary cooling unit, and the configuration of the processing unit described in Patent Document 1 is used as it is.

That is, the processing unit 500 is connected to a transfer pipe to temporarily store graphite, and a storage hopper equipped with a rotary valve at the bottom to adjust the amount of graphite discharged, and a storage means composed of a bulk bag or storage tank in which graphite is stored and stored. It consists of including.

The vacuum control unit 600 is configured to smoothly flow the inert gas in the crucible tube by suctioning and discharging air in the crucible tube 310, and the configuration of the vacuum control unit described in Patent Document 1 is used as it is.

That is, the vacuum controller 600 includes a suction pipe having one end disposed inside the crucible pipe, a vacuum control valve connected to the suction pipe, and a vacuum pump connected to the vacuum control valve to provide suction power.

Although the preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and it should be understood that the scope of the present invention extends to those within the scope substantially equivalent to the embodiments of the present invention. Various modifications and implementations are possible by those skilled in the art to which the invention pertains without departing from the spirit of the invention.

1: crucible tube
11: straight pipe 12: expansion pipe 13: shrink pipe
20: rectangular crucible line 20': rectangular unit crucible
30: inert gas pipe 40: control valve
50: graphite block pad
100: transfer unit 200: drying unit
300: vertical graphitization furnace 400: rotary cooling unit
500: processing unit 600: vacuum control unit

Claims (6)

A vertical comprising a transfer unit for transporting and supplying raw materials for graphitization, a drying unit connected to the transfer unit to heat and dry the raw material, and a crucible tube connected to the drying unit and filled with the raw material to undergo graphitization. A type graphitization furnace, a rotary cooling unit for cooling the graphite produced in the vertical type graphitization furnace, a processing unit for transporting and storing the cooled graphite to the outside through the rotation cooling unit, and coupled to the crucible tube in the crucible tube In the vertical graphitization furnace system including a vacuum control unit for smooth inert gas flow in,
The crucible tube includes a straight tube having a predetermined length in the vertical direction and having a rectangular horizontal cross section, and a plurality of rectangular crucible lines having a predetermined length in the vertical direction are provided inside the straight tube;
The plurality of rectangular crucible lines are filled in the crucible tube in close contact with each other;
One end of an inert gas pipe for supplying an inert gas to the lower portion of the rectangular crucible line is adjacently disposed,
Each of the inert gas pipes is provided with a control valve having a pressure gauge,
Each control valve individually controls the pressure and flow rate of the inert gas so as to equalize the supply of inert gas from each inert gas pipe to the rectangular crucible line,
The plurality of rectangular crucible lines are arranged to divide the space in the straight pipe into n equal parts so that the inert gas can be evenly supplied on a plane in the straight pipe,
At the lower end of the straight tube of the crucible tube,
A graphite block pad composed of a rectangular parallelepiped having a predetermined height and having a through hole smaller than the size of the rectangular crucible line formed only at a position corresponding to the arrangement position of the rectangular crucible line is provided. Vertical graphitization furnace system. delete delete According to claim 1,
A vertical graphitization furnace system, characterized in that the spaces between each of the rectangular crucible lines and between the straight pipe portion of the crucible tube and the plurality of rectangular crucible lines are closely adhered so that no empty space is generated. delete delete

Images