CN205316959U - Energy -concerving and environment -protective type lithium fluoride battery anode material pushing plate furnace - Google Patents

Abstract

The utility model relates to a pushing plate furnace especially relates to an energy -concerving and environment -protective type lithium fluoride battery anode material pushing plate furnace. The problem of the technique is solved provide an energy -concerving and environment -protective type lithium fluoride battery anode material pushing plate furnace. Such energy -concerving and environment -protective type lithium fluoride battery anode material pushing plate furnace is provided, including intensification stove I, intensification stove II, temperature sensor I, high temperature furnace I, high temperature furnace II, temperature sensor II, cooling furnace I, heat absorbing sheet, cooling furnace II, circulating pump, waste heat utilization district, exhaust -gas treatment groove I, exhaust -gas treatment groove II, suction fan, control system etc. Intensification stove I is connected with intensification stove II, and intensification stove II is connected with high temperature furnace I, and high temperature furnace I is connected with high temperature furnace II, high temperature furnace II is connected with cooling furnace I, and cooling furnace I is connected with cooling furnace II, cooling furnace's II top is provided with exhaust -gas treatment groove I and exhaust -gas treatment groove II respectively. An energy -concerving and environment -protective type lithium fluoride battery anode material pushing plate furnace who provides has control system, has realized the automation mechanized operation, simple structure.

Description

A kind of energy saving and environment friendly lithium electricity positive electrode pusher furnace

Technical field

This utility model relates to a kind of pusher furnace, particularly relates to a kind of energy saving and environment friendly lithium electricity positive electrode pusher furnace.

Background technology

The main composition material of lithium ion battery includes electrolyte, isolated material, positive and negative pole material etc. Positive electrode occupies larger proportion (mass ratio of positive and negative pole material is 3:1 ~ 4:1), because the performance of positive electrode directly affects the performance of lithium ion battery, its cost also directly determines battery cost height.

Lithium ion battery is 2 primary cell systems of the positive pole using the lithium intercalation compound that can reversibly insert and deviate from lithium ion 2 kinds different as battery and negative pole. During charging, lithium ion is deviate from from the lattice of positive electrode, is inserted in the lattice of negative material after electrolyte so that negative pole richness lithium, positive extreme poverty lithium; During electric discharge, lithium ion is deviate from from the lattice of negative material, is inserted in the lattice of positive electrode after electrolyte so that be just rich in lithium, the lean lithium of negative pole. Such positive and negative pole material when inserting and deviating from lithium ion relative to the difference of the current potential of lithium metal, it is simply that the running voltage of battery.

In the composition of lithium ion battery, positive electrode is to determine its chemical property, security performance, and the key factor of future thrust, at present, in positive electrode production process, in order to produce, reaction is uniform, high crystalline quality, porous nickel, surface area are little, apparent gravity is big, the anode material for lithium-ion batteries product of stable electrochemical property, is often required to utilize crystallography principle and aerodynamic principle, positive electrode is carried out calcination process.

Pusher furnace is a kind of conventional high-temperature calcination equipment, is widely used in the industry such as battery material, pottery, has use temperature range width, and furnace atmosphere environment such as is easily controlled at the feature.

Shell steel plate and shaped steel are welded, and bottom and four is carefully welded, and seal with rubber asbestos plate between stove cover plate and furnace shell;Link plate is joined in furnace shell both sides. Burner hearth adopts assembled structure, material selection 99 corundum; Push pedal material selection corundum-mullite; Being 99 porcelain chute boards below push pedal, burner hearth both sides are molybdenum filament hot plate, and molybdenum filament plate has wire hole, and molybdenum filament is through wherein.

Existing lithium electricity positive electrode pusher furnace, poorly sealed, heat energy loss is serious, simultaneously to the toxic and harmful of outside airborne release, it does not have through any effective process, seriously polluted, not energy-conservation, not environmentally, healthy to people threatens.

Utility model content

(1) to solve the technical problem that

This utility model is in order to overcome existing lithium electricity positive electrode pusher furnace, not energy-conservation, and not environmentally, heat energy loss is serious, and the shortcoming of discharge toxic and harmful, the technical problems to be solved in the utility model is to provide a kind of energy saving and environment friendly lithium electricity positive electrode pusher furnace.

(2) technical scheme

In order to solve above-mentioned technical problem, this utility model provides such a energy saving and environment friendly lithium electricity positive electrode pusher furnace, includes heating furnace I, heating furnace II, temperature sensor I, high temperature furnace I, high temperature furnace II, temperature sensor II, cooling stove I, heat absorbing sheet, cooling stove II, outlet pipe, circulating pump, water inlet pipe, UTILIZATION OF VESIDUAL HEAT IN district, waste gas treating tank I, waste gas treating tank II, escape pipe, discharge, induced-draught fan, exhaustor I, exhaustor II, exhaustor III, control system;

The right side of heating furnace I is provided with heating furnace II, and heating furnace I is connected with heating furnace II, heating furnace II be provided above an escape pipe, heating furnace II is connected with the escape pipe being disposed there above; Heating furnace II be arranged below temperature sensor I, heating furnace II is connected with temperature sensor I;

The right side of heating furnace II is provided with high temperature furnace I, and heating furnace II is connected with high temperature furnace I, and the right side of high temperature furnace I is provided with high temperature furnace II, and high temperature furnace I is connected with high temperature furnace II; The top of high temperature furnace I and high temperature furnace II is provided with three escape pipes, high temperature furnace I and high temperature furnace II and is connected with three escape pipes being disposed there above respectively;

Three escape pipes that be provided above escape pipe of heating furnace II, high temperature furnace I are respectively provided with the top of high temperature furnace II are all connected with discharge respectively, and discharge is arranged on the top of heating furnace II, high temperature furnace I and high temperature furnace II;

The right side of high temperature furnace II is provided with cooling stove I, and high temperature furnace II is connected with cooling stove I, and what cool down stove I is arranged below temperature sensor II, and cooling stove I is connected with temperature sensor II; The right side of cooling stove I is provided with cooling stove II, and cooling stove I is connected with cooling stove II;

The inside of cooling stove I and cooling stove II is provided with heat absorbing sheet, is separately positioned on cooling stove I and is all connected with water inlet pipe with the right-hand member of the heat absorbing sheet of the inside of cooling stove II; The right side of cooling stove II is provided with UTILIZATION OF VESIDUAL HEAT IN district, and water inlet pipe is connected with UTILIZATION OF VESIDUAL HEAT IN district;

Being separately positioned on cooling stove I to be all connected with outlet pipe with the left end of the heat absorbing sheet of the inside of cooling stove II, what cool down stove II is arranged below circulating pump, and outlet pipe is connected with circulating pump, and circulating pump is connected with UTILIZATION OF VESIDUAL HEAT IN district;

What cool down stove I is provided above induced-draught fan, and induced-draught fan is arranged on the right side of discharge, and discharge is connected with induced-draught fan;

The top of cooling stove II is respectively arranged with waste gas treating tank I and waste gas treating tank II, waste gas treating tank II is arranged on the right side of waste gas treating tank I, induced-draught fan is connected with waste gas treating tank I by exhaustor I, waste gas treating tank I is connected with waste gas treating tank II by exhaustor II, exhaustor III is arranged on the top of waste gas treating tank II, and exhaustor III is connected with waste gas treating tank II;

Temperature sensor I, temperature sensor II, circulating pump, induced-draught fan are connected with control system all respectively.

Operation principle: when preparation, first lithium electricity positive electrode is placed in push pedal, and pushed it into by push plate device in heating furnace I and heating furnace II, wait everything in readiness, start the lithium electricity positive electrode in heating furnace I and heating furnace II is heated up. Lithium electricity positive electrode while heating up, its poisonous and hazardous Substance Transformation that inside can be contained be gaseous volatilization out, simultaneously because the principle expanded with heat and contract with cold, Volatile Gas is known from experience heating furnace I and heating furnace II is damaged.

In order to prevent the above-described problem from occurring, above and below heating furnace II, it is respectively arranged with escape pipe and temperature sensor I. After the lithium electricity positive electrode in heating furnace I and heating furnace II carries out the intensification regular hour, heating furnace I and the temperature in heating furnace II can reach certain numerical value. Temperature in heating furnace II can be detected by temperature sensor I continuously, and when temperature sensor I detects that the temperature in heating furnace II reaches the numerical value arranged, the temperature information detected can be fed back to control system by temperature sensor I.

The temperature information that control system is fed back according to temperature sensor I, start to control induced-draught fan to operate, the escape pipe that induced-draught fan is connected with heating furnace II by discharge, the toxic and harmful that will heat up in stove I and heating furnace II siphons away, and by connected exhaustor I, toxic and harmful is discharged in waste gas treating tank I. Waste gas treating tank I is built with chemical liquid, it is possible to be neutralized reaction with toxic and harmful, substantially carries out no pollution discharge, meets country's discharge standard to pollution gas.

Thorough in order to what prevent from toxic and harmful is processed, after waste gas treating tank I processes gas, is discharged in waste gas treating tank II again through exhaustor II. It is also equipped with chemical liquid in waste gas treating tank II, it also is able to equally be neutralized reaction with toxic and harmful, ensure that toxic and harmful is processed more clean thoroughly, after complying fully with country's discharge standard to pollution gas, be discharged to the outside in air again through exhaustor III.

After the lithium electricity positive electrode in heating furnace I and heating furnace II carries out the intensification regular hour, then the lithium electricity positive electrode that will heat up in stove I and heating furnace II is pushed in high temperature furnace I and high temperature furnace II, and continues to improve temperature, and keeps the regular hour. Simultaneously because lasting high temperature, the toxic and harmful that lithium electricity positive electrode volatilizees is more thorough, in order to eliminate toxic and harmful, the continual motion of induced-draught fan, and lasting toxic and harmful is discharged in waste gas treating tank I and waste gas treating tank II, after carrying out harmless treatment, it is then exhausted from outside atmosphere.

After the lithium electricity positive electrode in high temperature furnace I and high temperature furnace II is kept the high temperature regular hour, it is necessary to by the lithium electricity positive electrode in high temperature furnace I and high temperature furnace II, it is pushed in cooling stove I and cooling stove II and cools. Being arranged below temperature sensor II at cooling stove I, when temperature sensor II detects that the temperature of the lithium electricity positive electrode pushed in cooling stove I and cooling stove II is higher than when setting numerical value, temperature information can be fed back to control system by temperature sensor II.

The temperature information that control system is fed back according to temperature sensor II, starts to control circulating pump operating. Circulating pump drives cold water to have respectively entered in the heat absorbing sheet in cooling stove I and cooling stove II from water inlet pipe, start to absorb the high temperature that the lithium electricity positive electrode in cooling stove I and cooling stove II volatilizes, and after flowing out to circulating pump by outlet pipe, it is flowed into UTILIZATION OF VESIDUAL HEAT IN district again, also the high temperature that the lithium electricity positive electrode in cooling stove I and cooling stove II volatilizes is brought in UTILIZATION OF VESIDUAL HEAT IN district simultaneously and utilizes, carry out heating such as northerly winter and utilize.

The lithium electricity positive electrode in cooling stove I and cooling stove II detected when temperature sensor II, when the temperature volatilized reaches the numerical value set, temperature information can be fed back to control system by temperature sensor II.The temperature information that control system is fed back further according to temperature sensor II, controls circulating pump and shuts down. Then by the cooling stove I after cooling and the lithium electricity positive electrode in cooling stove II, push next process and process.

(3) beneficial effect

One provided by the utility model energy saving and environment friendly lithium electricity positive electrode pusher furnace, there is control system and temperature sensor, the intensification cooling down operation of pusher furnace can be carried out automatically, temperature is paid close attention in inartificial detection in real time, reduces cost of labor, it is possible to realize heating and heat preservation cooling down operation accurately, do not result in the waste of heat energy, adopt two grades of waste gas treating tanks that the toxic and harmful of discharge is processed, it is achieved that no pollution discharges, and meets national environmental standard simultaneously; Waste heat after cooling being recycled simultaneously, more efficiently avoid the loss waste of heat energy, it is achieved that energy-conservation purpose, work efficiency is high, effective, and simple in construction is easy to operate, maintains easily maintenance.

Accompanying drawing explanation

Fig. 1 is front view structural representation of the present utility model.

Being labeled as in accompanying drawing: 1-heating furnace I, 2-heating furnace II, 3-temperature sensor I, 4-high temperature furnace I, 5-high temperature furnace II, 6-temperature sensor II, 7-cools down stove I, 8-heat absorbing sheet, 9-cools down stove II, 10-outlet pipe, 11-circulating pump, 12-water inlet pipe, 13-UTILIZATION OF VESIDUAL HEAT IN district, 14-waste gas treating tank I, 15-waste gas treating tank II, 16-escape pipe, 17-discharge, 18-induced-draught fan, 19-exhaustor I, 20-exhaustor II, 21-exhaustor III, 22-controls system.

Detailed description of the invention

Below in conjunction with drawings and Examples, this utility model is further described.

Embodiment 1

A kind of energy saving and environment friendly lithium electricity positive electrode pusher furnace, as it is shown in figure 1, include heating furnace I 1, heating furnace II 2, temperature sensor I 3, high temperature furnace I 4, high temperature furnace II 5, temperature sensor II 6, cooling stove I 7, heat absorbing sheet 8, cooling stove II 9, outlet pipe 10, circulating pump 11, water inlet pipe 12, UTILIZATION OF VESIDUAL HEAT IN district 13, waste gas treating tank I 14, waste gas treating tank II 15, escape pipe 16, discharge 17, induced-draught fan 18, exhaustor I 19, exhaustor II 20, exhaustor III 21, control system 22.

The right side of heating furnace I 1 is provided with heating furnace II 2, and heating furnace I 1 is connected with heating furnace II 2, heating furnace II 2 be provided above an escape pipe 16, heating furnace II 2 is connected with the escape pipe 16 being disposed there above; Heating furnace II 2 be arranged below temperature sensor I 3, heating furnace II 2 is connected with temperature sensor I 3.

The right side of heating furnace II 2 is provided with high temperature furnace I 4, and heating furnace II 2 is connected with high temperature furnace I 4, and the right side of high temperature furnace I 4 is provided with high temperature furnace II 5, and high temperature furnace I 4 is connected with high temperature furnace II 5; The top of high temperature furnace I 4 and high temperature furnace II 5 is provided with three escape pipes 16, high temperature furnace I 4 and high temperature furnace II 5 and is connected with three escape pipes 16 being disposed there above respectively.

Three escape pipes 16 that be provided above escape pipe 16 of heating furnace II 2, high temperature furnace I 4 are respectively provided with the top of high temperature furnace II 5 are connected with discharge 17 all respectively, and discharge 17 is arranged on the top of heating furnace II 2, high temperature furnace I 4 and high temperature furnace II 5.

The right side of high temperature furnace II 5 is provided with cooling stove I 7, and high temperature furnace II 5 is connected with cooling stove I 7, and what cool down stove I 7 is arranged below temperature sensor II 6, and cooling stove I 7 is connected with temperature sensor II 6;The right side of cooling stove I 7 is provided with cooling stove II 9, and cooling stove I 7 is connected with cooling stove II 9.

The inside of cooling stove I 7 and cooling stove II 9 is provided with heat absorbing sheet 8, is separately positioned on cooling stove I 7 and is all connected with water inlet pipe 12 with the right-hand member of the heat absorbing sheet 8 of the inside of cooling stove II 9; The right side of cooling stove II 9 is provided with UTILIZATION OF VESIDUAL HEAT IN district 13, and water inlet pipe 12 is connected with UTILIZATION OF VESIDUAL HEAT IN district 13.

Being separately positioned on cooling stove I 7 to be all connected with outlet pipe 10 with the left end of the heat absorbing sheet 8 of the inside of cooling stove II 9, what cool down stove II 9 is arranged below circulating pump 11, and outlet pipe 10 is connected with circulating pump 11, and circulating pump 11 is connected with UTILIZATION OF VESIDUAL HEAT IN district 13; What cool down stove I 7 is provided above induced-draught fan 18, and induced-draught fan 18 is arranged on the right side of discharge 17, and discharge 17 is connected with induced-draught fan 18.

The top of cooling stove II 9 is respectively arranged with waste gas treating tank I 14 and waste gas treating tank II 15, waste gas treating tank II 15 is arranged on the right side of waste gas treating tank I 14, induced-draught fan 18 is connected with waste gas treating tank I 14 by exhaustor I 19, waste gas treating tank I 14 is connected with waste gas treating tank II 15 by exhaustor II 20, exhaustor III 21 is arranged on the top of waste gas treating tank II 15, and exhaustor III 21 is connected with waste gas treating tank II 15; Temperature sensor I 3, temperature sensor II 6, circulating pump 11, induced-draught fan 18 are connected with control system 22 all respectively.

Operation principle: when preparation, first lithium electricity positive electrode is placed in push pedal, and pushed it into by push plate device in heating furnace I 1 and heating furnace II 2, wait everything in readiness, start the lithium electricity positive electrode in heating furnace I 1 and heating furnace II 2 is heated up. Lithium electricity positive electrode while heating up, its poisonous and hazardous Substance Transformation that inside can be contained be gaseous volatilization out, simultaneously because the principle expanded with heat and contract with cold, Volatile Gas is known from experience heating furnace I 1 and heating furnace II 2 is damaged.

In order to prevent the above-described problem from occurring, above and below heating furnace II 2, it is respectively arranged with escape pipe 16 and temperature sensor I 3. After the lithium electricity positive electrode in heating furnace I 1 and heating furnace II 2 carries out the intensification regular hour, heating furnace I 1 and the temperature in heating furnace II 2 can reach certain numerical value. Temperature in heating furnace II 2 can be detected by temperature sensor I 3 continuously, and when temperature sensor I 3 detects that the temperature in heating furnace II 2 reaches the numerical value arranged, the temperature information detected can be fed back to control system 22 by temperature sensor I 3.

The temperature information that control system 22 is fed back according to temperature sensor I 3, start to control induced-draught fan 18 to operate, the escape pipe 16 that induced-draught fan 18 is connected with heating furnace II 2 by discharge 17, the toxic and harmful that will heat up in stove I 1 and heating furnace II 2 siphons away, and by connected exhaustor I 19, toxic and harmful is discharged in waste gas treating tank I 14. Waste gas treating tank I 14 is built with chemical liquid, it is possible to be neutralized reaction with toxic and harmful, substantially carries out no pollution discharge, meets country's discharge standard to pollution gas.

Thorough in order to what prevent from toxic and harmful is processed, after waste gas treating tank I 14 processes gas, is discharged in waste gas treating tank II 15 again through exhaustor II 20. It is also equipped with chemical liquid in waste gas treating tank II 15, it also is able to equally be neutralized reaction with toxic and harmful, ensure that toxic and harmful is processed more clean thoroughly, after complying fully with country's discharge standard to pollution gas, it is discharged to the outside in air again through exhaustor III 21.

After the lithium electricity positive electrode in heating furnace I 1 and heating furnace II 2 is carried out the intensification regular hour, will heat up the lithium electricity positive electrode in stove I 1 and heating furnace II 2 again and be pushed in high temperature furnace I 4 and high temperature furnace II 5, and continue to improve temperature, and keep the regular hour. Simultaneously because lasting high temperature, the toxic and harmful that lithium electricity positive electrode volatilizees is more thorough, in order to eliminate toxic and harmful, the continual motion of induced-draught fan 18, and lasting toxic and harmful is discharged in waste gas treating tank I 14 and waste gas treating tank II 15, after carrying out harmless treatment, it is then exhausted from outside atmosphere.

After the lithium electricity positive electrode in high temperature furnace I 4 and high temperature furnace II 5 is kept the high temperature regular hour, it is necessary to by the lithium electricity positive electrode in high temperature furnace I 4 and high temperature furnace II 5, it is pushed in cooling stove I 7 and cooling stove II 9 and cools. Cooling stove I 7 be arranged below temperature sensor II 6, when temperature sensor II 6 detects that the temperature of the lithium electricity positive electrode pushed in cooling stove I 7 and cooling stove II 9 is higher than when setting numerical value, temperature information can be fed back to control system 22 by temperature sensor II 6.

The temperature information that control system 22 is fed back according to temperature sensor II 6, starts to control circulating pump 11 and operates. Circulating pump 11 drives cold water to have respectively entered in the heat absorbing sheet 8 in cooling stove I 7 and cooling stove II 9 from water inlet pipe 12, start to absorb the high temperature that the lithium electricity positive electrode in cooling stove I 7 and cooling stove II 9 volatilizes, and after flowing out to circulating pump 11 by outlet pipe 10, it is flowed into UTILIZATION OF VESIDUAL HEAT IN district 13 again, also the high temperature that the lithium electricity positive electrode in cooling stove I 7 and cooling stove II 9 volatilizes is brought in UTILIZATION OF VESIDUAL HEAT IN district 13 simultaneously and utilizes, carry out heating such as northerly winter and utilize.

The lithium electricity positive electrode in cooling stove I 7 and cooling stove II 9 detected when temperature sensor II 6, when the temperature volatilized reaches the numerical value set, temperature information can be fed back to control system 22 by temperature sensor II 6. The temperature information that control system 22 is fed back further according to temperature sensor II 6, controls circulating pump 11 and shuts down. Then by the cooling stove I 7 after cooling and the lithium electricity positive electrode in cooling stove II 9, push next process and process.

Embodiment described above only have expressed preferred implementation of the present utility model, and it describes comparatively concrete and detailed, but therefore can not be interpreted as the restriction to this utility model the scope of the claims. It should be pointed out that, for the person of ordinary skill of the art, without departing from the inventive concept of the premise, it is also possible to make some deformation, improvement and replacement, these broadly fall into protection domain of the present utility model. Therefore, the protection domain of this utility model patent should be as the criterion with claims.

Claims (1)

1. an energy saving and environment friendly lithium electricity positive electrode pusher furnace, it is characterized in that, include heating furnace I (1), heating furnace II (2), temperature sensor I (3), high temperature furnace I (4), high temperature furnace II (5), temperature sensor II (6), cooling stove I (7), heat absorbing sheet (8), cooling stove II (9), outlet pipe (10), circulating pump (11), water inlet pipe (12), UTILIZATION OF VESIDUAL HEAT IN district (13), waste gas treating tank I (14), waste gas treating tank II (15), escape pipe (16), discharge (17), induced-draught fan (18), exhaustor I (19), exhaustor II (20), exhaustor III (21), control system (22),

The right side of heating furnace I (1) is provided with heating furnace II (2), heating furnace I (1) is connected with heating furnace II (2), heating furnace II (2) be provided above an escape pipe (16), heating furnace II (2) is connected with the escape pipe (16) being disposed there above; Heating furnace II (2) be arranged below temperature sensor I (3), heating furnace II (2) is connected with temperature sensor I (3);

The right side of heating furnace II (2) is provided with high temperature furnace I (4), and heating furnace II (2) is connected with high temperature furnace I (4), and the right side of high temperature furnace I (4) is provided with high temperature furnace II (5), and high temperature furnace I (4) is connected with high temperature furnace II (5); The top of high temperature furnace I (4) and high temperature furnace II (5) is provided with three escape pipes (16), high temperature furnace I (4) and high temperature furnace II (5) and is connected with three escape pipes (16) being disposed there above respectively;

Three escape pipes (16) that be provided above escape pipe (16) of heating furnace II (2), high temperature furnace I (4) and the top of high temperature furnace II (5) are respectively provided with are connected with discharge (17) all respectively, and discharge (17) is arranged on the top of heating furnace II (2), high temperature furnace I (4) and high temperature furnace II (5);

The right side of high temperature furnace II (5) is provided with cooling stove I (7), and high temperature furnace II (5) is connected with cooling stove I (7), and what cool down stove I (7) is arranged below temperature sensor II (6), and cooling stove I (7) is connected with temperature sensor II (6); The right side of cooling stove I (7) is provided with cooling stove II (9), and cooling stove I (7) is connected with cooling stove II (9);

The inside of cooling stove I (7) and cooling stove II (9) is provided with heat absorbing sheet (8), is separately positioned on cooling stove I (7) and is all connected with water inlet pipe (12) with the right-hand member of the heat absorbing sheet (8) of the inside of cooling stove II (9); The right side of cooling stove II (9) is provided with UTILIZATION OF VESIDUAL HEAT IN district (13), and water inlet pipe (12) is connected with UTILIZATION OF VESIDUAL HEAT IN district (13);

It is separately positioned on cooling stove I (7) to be all connected with outlet pipe (10) with the left end of the heat absorbing sheet (8) of the inside of cooling stove II (9), what cool down stove II (9) is arranged below circulating pump (11), outlet pipe (10) is connected with circulating pump (11), and circulating pump (11) is connected with UTILIZATION OF VESIDUAL HEAT IN district (13); What cool down stove I (7) is provided above induced-draught fan (18), and induced-draught fan (18) is arranged on the right side of discharge (17), and discharge (17) is connected with induced-draught fan (18);

The top of cooling stove II (9) is respectively arranged with waste gas treating tank I (14) and waste gas treating tank II (15), waste gas treating tank II (15) is arranged on the right side of waste gas treating tank I (14), induced-draught fan (18) is connected with waste gas treating tank I (14) by exhaustor I (19), waste gas treating tank I (14) is connected with waste gas treating tank II (15) by exhaustor II (20), exhaustor III (21) is arranged on the top of waste gas treating tank II (15), and exhaustor III (21) is connected with waste gas treating tank II (15);

Temperature sensor I (3), temperature sensor II (6), circulating pump (11), induced-draught fan (18) are connected with control system (22) all respectively.