阅读说明：本技术 泡沫渣干式处理设备及其工作方式 (Dry type treatment equipment for foam slag and working mode thereof ) 是由 刘春茗 于 2021-08-17 设计创作，主要内容包括：本发明泡沫渣干式处理设备及其工作方式,涉及钢铁工业液态钢渣一次处理装置技术领域,尤其涉及液态泡沫渣的干法处理装置以及工作方法。本发明钢渣输送装置贯穿设置于整个冷却机的内部；中间包设置于冷却机的前端,其渣槽口部位于钢渣输送装置前端上部；防粘剂铺设器设置于冷却机的前端；冷却风机为多个设置于冷却机的一侧,其出风口分别与冷却机侧部的上风口和下分口相连通；鳞板输送机的一端分别设置于冷却机尾端料斗下方,另一端设置于渣与钢分离器相连接；渣与钢分离器的顶端通过管道与除尘器相连接；渣与钢分离器的底部设置有板式输送机；检测仪表设置于冷却机的不同位置,用于检测冷却机内部的运行情况。(The invention discloses a dry type treatment device for foam slag and a working mode thereof, relates to the technical field of primary treatment devices for liquid steel slag in the steel industry, and particularly relates to a dry type treatment device for liquid foam slag and a working method thereof. The steel slag conveying device is arranged in the whole cooling machine in a penetrating way; the tundish is arranged at the front end of the cooler, and the opening part of the slag groove of the tundish is positioned at the upper part of the front end of the steel slag conveying device; the anti-sticking agent laying device is arranged at the front end of the cooling machine; the cooling fans are arranged on one side of the cooler, and air outlets of the cooling fans are respectively communicated with an upper air inlet and a lower air outlet on the side part of the cooler; one end of the apron conveyor is respectively arranged below the hopper at the tail end of the cooler, and the other end of the apron conveyor is arranged on the slag-steel separator; the top end of the slag and steel separator is connected with a dust remover through a pipeline; a plate conveyor is arranged at the bottom of the slag and steel separator; the detecting instruments are arranged at different positions of the cooling machine and used for detecting the operation condition inside the cooling machine.)

1. A foamed slag dry treatment device is characterized by comprising: the device comprises a tundish (1), an anti-sticking agent laying device (2), a cooler (3), a steel slag conveying device (4), a cooling fan (5), a apron conveyor (6), a slag-steel separator (7), a dust remover (8), a plate conveyor (9) and a detection instrument;

the steel slag conveying device (4) penetrates through the whole cooling machine (3);

the tundish (1) is arranged at the front end of the cooler (3), and the opening part of the slag groove (11) is positioned at the upper part of the front end of the steel slag conveying device (4);

the anti-sticking agent laying device (2) is arranged at the front end of the cooling machine (3), and the outlet end of the anti-sticking agent laying device is arranged at the upper part of the front end of the steel slag conveying device (4) and is positioned at the front end of the opening part of the slag groove (11);

the cooling fans (5) are arranged on one side of the cooler (3), and air outlets of the cooling fans are respectively communicated with an upper air inlet (343) and a lower air outlet (344) on the side of the cooler (3) to cool the inside of the cooler (3);

one end of the apron conveyor (6) is respectively arranged below a hopper (35) at the tail end of the cooler (3), and the other end of the apron conveyor is arranged below the slag-steel separator (7) and used for conveying slag and steel into the slag-steel separator (7);

the top end of the slag and steel separator (7) is connected with a dust remover (8) through a pipeline;

a plate conveyor (9) is arranged at the bottom of the slag-steel separator (7);

the detecting instruments are arranged at different positions of the cooler (3) and used for detecting the operation condition inside the cooler (3).

2. The method of claim 1, wherein:

the main body of the cooler (3) is a shell (34);

the upper part of the shell (34) is sequentially provided with a high-temperature tuyere (31), a medium-temperature tuyere (32) and a low-temperature tuyere (33) from front to back;

a middle and high temperature section separation wall (341) is arranged on the inner side of the upper wall of the shell (34) between the high temperature tuyere (31) and the medium temperature tuyere (32);

a middle and low temperature section isolation wall (342) is arranged on the inner side of the upper wall of the shell (34) between the middle temperature tuyere (32) and the low temperature tuyere (33);

a plurality of pairs of upper air inlets (343) and lower air inlets (344) are uniformly distributed on one side wall of the shell (34); the pair of upper air inlets (343) and the lower air inlet (344) are connected with a cooling fan (5) through a pipeline;

a hopper (35) is arranged at the lower end of the tail part of the shell (34), and the hopper (35) is positioned at the lower part of the tail end of the steel slag conveying device (4);

and a discharge valve (36) is arranged at the bottom of the hopper (35).

3. The apparatus according to claim 1 or 2, wherein:

the steel slag conveying device (4) comprises: a steel slag conveyor (41), a casting die (42), a cold air chamber (43) under the die, a discharge valve (44), a material leakage conveyor (45) and a main transmission (46);

the steel slag conveyor (41) is arranged inside the shell (34);

a plurality of rows and columns of casting molds (42) are uniformly distributed on a conveying belt of the steel slag conveyor (41);

the main transmission (46) is arranged on a main transmission shaft at the rear end of the steel slag conveyor (41) and drives the steel slag conveyor (41) to rotate;

the lower part of the steel slag conveyor (41) is provided with lower mold cold air chambers (43) which are the same as the cooling fans (5) in number and are opposite to the positions of the upper air inlet (343) and the lower air inlet (344);

the lower part of the lower cold air chamber (43) of the mold is of a hopper-shaped structure, and the bottom of the hopper-shaped structure is provided with a discharge valve (44);

the material leaking conveyor (45) is arranged at the bottom in the shell (34), is positioned at the lower part of the cold air chamber (43) under the die, receives the material slag falling from the material leaking conveyor (45), and conveys the material slag to the hopper (35).

4. The casting device according to claim 1 or 2, characterized in that the slag groove (11) of the tundish (1) is inserted into the shell (34) from the front wall of the shell (34), the mouth of the slag groove is positioned above the first row of casting molds (42) in the horizontal state, and the casting molds (42) in the horizontal state of the first row are cast.

5. The device according to claim 1 or 2, characterized in that the anti-adhesive applicator (2) comprises: a compressed gas storage (21), an anti-sticking agent storage (22), a mixer (23), a pipeline and a valve;

the compressed gas storage device (21) and the anti-sticking agent storage device (22) are respectively connected with the mixer (23) through a pipeline and a valve;

the mixer (23) is provided with a spraying pipe (24), the spraying pipe (24) is inserted into the shell (34) from the upper wall of the front end of the shell (34), and the opening of the spraying pipe is positioned above the front row of casting molds (42) of the casting molds (42) opposite to the opening of the slag groove (11).

6. The device as claimed in claim 1 or 2, wherein the cooling fan (5) is connected with the upper air inlet (343) and the lower air inlet (344) through a one-to-two pipeline to supply air to the interior of the housing (34).

7. The apparatus according to claim 1 or 2, characterized in that said slag-steel separator (7) comprises: the device comprises a grizzly screen (71), a separation fan (72), a separation air pipe (73) and a sealing shell (74);

the grizzly screen (71) is arranged at the middle lower part in the sealed shell (74);

a plurality of separating air pipes (73) are arranged on the sealed shell (74), and the separating air pipes (73) are positioned at the lower part of the grizzly screen (71);

the separation fan (72) is communicated with the separation air pipe (73) through a pipeline, and supplies air to the inside of the sealed shell (74) to blow the steel and slag on the upper part of the lattice screen (71).

8. The oven according to claim 1 or 2, characterized in that the inner wall of the housing (34) is provided with a refractory material layer, so that the housing (34) can bear high-temperature radiation baking, and the cooler (3) can be repeatedly used for a long time.

9. The working mode of the dry type treatment equipment for the foamed slag is characterized by comprising the following steps:

A. laying an anti-sticking agent: starting an anti-sticking agent laying device (2) to lay anti-sticking agents into a casting mold (41) which runs in a no-load mode;

B. transferring steel slag: the molten slag liquid obtained at the smelting end point is transferred to the upper part of the tundish (1) from a slag pot and gradually poured into the tundish (1);

C. raw slag casting: in the cooler (3), a slag groove (11) obliquely arranged on the bottom surface of the tundish (1) passes through a shell (34) of the cooler (3) and enters the cooler (3); the raw slag liquid is directly cast in a casting mould (42) which is already laid with the anti-sticking agent through a slag groove (11), and the casting mould (42) is simultaneously cast in the width direction;

D. forced cooling and heat exchange: in the process that a casting die (42) bears the raw slag liquid and runs from an inlet to an outlet, ambient air blown by a cooling fan (5) enters a cooling machine (3) through an upper air inlet (343) and a lower air inlet (344) in the middle of the side surface of a shell (34) and carries out gas-liquid and gas-solid heat exchange and raw slag phase change heat exchange with the raw slag liquid; finally, the ambient atmospheric temperature rises to form hot flue gas, and the liquid raw slag liquid is gradually cooled;

E. separating slag from steel: the casting die (42) for casting the crude slag liquid is carried by the steel slag conveyor (41) to gradually move from a point I to a point II, the crude slag liquid and the die are continuously forced to be cooled by ambient atmosphere blown by a cooling fan (5) and entering from an air inlet (343) and a lower air inlet (342) arranged in the middle of the shell (34), and gas-liquid, gas-solid heat exchange and phase change heat exchange are carried out between air and the crude slag liquid; the principle of the heat exchange is operated according to the principle of 'self-powdering when meeting cold' of the foam slag, namely the lowest temperature in the cooler (3) needs to be controlled within the temperature range of 'self-powdering when meeting cold' of the foam slag, the foam slag is completely pulverized, the tailings and the slag steel are automatically separated in a casting die, and the slag steel in the slag is molded according to the shape of the casting die (42); along with the operation of the steel slag conveyor (41) and the continuous casting of the raw slag liquid, the temperature of the smoke gas in the shell (34) is gradually reduced from the point I to the point II; enters a hopper (35) and is discharged out of the cooler (3);

F. separating and recovering waste heat: the space inside the shell (34) and above the steel slag conveyor (41) is divided into a high-temperature section, a medium-temperature section and a low-temperature section by a medium-high temperature section isolation wall (341) and a medium-low temperature section isolation wall (342) in the shell (34); the high-temperature tuyere (31) is arranged at the high-temperature section, the medium-temperature tuyere (32) is arranged at the medium-temperature section, and the low-temperature tuyere (33) is arranged at the low-temperature section; after gas-liquid and gas-solid heat exchange is carried out between the ambient atmosphere and the raw slag liquid, the temperature of the ambient atmosphere rises to form hot flue gas and carry the waste heat of the raw slag liquid, and the hot flue gas is separated from the raw slag liquid and exists in a hot air form; hot air is respectively pumped out by a high-temperature air port (31), a medium-temperature air port (32) and a low-temperature air port (33), and after dust is removed by a dust remover, the cascade recovery of waste heat is realized;

G. and (4) finished product transportation: the cooler (4) carries a raw slag casting mould (42) and is driven by a main drive (46) to travel from an inlet to an outlet. When the original slag liquid carried in the first row of casting dies (42) is changed from a high-temperature liquid state into a high-temperature solid state under the continuous cooling action of the external cooling fan (5), the original slag liquid gradually enters a self-powdering temperature interval, the steel slag automatically turns powder when meeting cold in the temperature interval, the tailing powder is directly separated from the steel slag, and the steel slag and the tailing are automatically separated; in the process of continuously transporting towards the outlet, the tailings and the slag steel are naturally separated, but are positioned in the same casting die (42) and are continuously cooled by the ambient atmosphere; when the temperature is reduced to normal temperature, just at the casting die (42) of the steel slag conveyor (41), when the steel slag travels to the discharging position II, the casting die (42) is gradually changed from a horizontal upward bearing state to a reverse 180-degree downward bearing state, and the steel slag in the casting die (42) automatically separates from the casting die (42) and falls into the hopper (35) under the action of gravity; in order to prevent the unorganized outside cold air from entering the cooling machine (3), the discharge valve (36) is required to have a certain height, the discharge channel is naturally closed by the processed steel slag mixture, and the leakage of the ambient cold air into the cooling machine (3) is reduced to the maximum extent so as to avoid the temperature reduction of the waste heat smoke;

H. separating tailings from block steel: the mixture of the tailings and the slag steel which are unloaded by the unloading valve (36) and cooled to normal temperature is conveyed into the closed separator (7) by the apron conveyor (6) to be unloaded; the unloaded mixture is coupled on a grid sieve (71), ambient air blown by a separation fan (72) enters a sealed shell (74) through separation air pipes (73) uniformly distributed around the lower part of the grid sieve (71), and is blown upwards from the lower part of the grid sieve (71), and self-powder dust in the mixture is pumped out of a separator (7) under the negative pressure action of a dust remover fan (81) and enters a dust remover (8) for dust removal along with separation gas; due to the blocking of the grid sieve (71), the tailing powder mixed and attached to the surface of the slag steel block is collided and vibrated by the grid sieve (71), the self-powder dust is separated from attachments again, the environmental air blown by the separation fan (72) is blown away, and meanwhile, the tailing powder is sucked into the dust remover (8) under the negative pressure suction action of the dust removal fan (81) and is collected and stored in a centralized mode; the cast slag steel blocks fall into the bottom of the separator (7) to form a material layer with a certain thickness, and the material layer is directly conveyed out of a factory by a plate conveyor (9), or is sent to steel making, or is sent to a steel making raw material warehouse; the discharged tailing powder in the steel slag mixture is pumped out by the negative pressure of a dust removal fan in the falling process, enters a dust remover, is collected in a centralized manner, and is transported and stored in a unified manner;

I. detection control: the method comprises the steps that a certain position between a middle-temperature section and a low-temperature section is determined to be a 'self-cooling powder' temperature interval by detecting the temperature of a cold air chamber (42) under each die, the temperature of a high-temperature air port (31), a middle-temperature air port (32) and a low-temperature air port (33), the pressure under each chamber and the differential pressure between hot air ports, the 'self-cooling powder' condition of foam slag is monitored by a high-temperature section monitor in a detection instrument and is stabilized in a certain fixed area of a cooler (3), and the air quantity or the pressure of the cooling fan (5) is regulated through closed-loop control to stabilize the air quantity of the cooling fan (5) so that the foam slag powdering position interval is stabilized, but the foam slag powdering position interval does not move back and forth along the length direction of the cooler;

J. the steel slag enters a casting die (42), is driven by a cooler (3) to run towards an outlet side, and can splash down the steel slag outside the casting die (42) and fall into a cold air chamber (43) under the die in the cooling process, when accumulated materials in the hopper of the cold air chamber (43) under the die increase to a certain degree, a discharge valve (44) acts to discharge the accumulated ash to a leakage conveyor (45) in the running process, the leaked materials are conveyed to the hopper (35) of the cooler (3) by the leakage conveyor (45), and the steel slag is discharged out of the cooler (3) uniformly and is transferred to a next process.

K. A cold air chamber (43) below the casting mould (42) of the steel slag conveyor (3); one lower-mold cold air chamber (43) corresponds to one or more cooling fans (5); the lower-die cold air chamber (43) is used for dividing the steel slag conveyor (41) into a plurality of cooling sections, and the temperature of the cooling sections is gradually reduced from an inlet to an outlet; if do not have cold wind chamber (43) under the mould, then the cold wind that cooling blower (5) were blown is "turbulent" state within cooler (3), and the cooling wind between high temperature section, middle temperature section, the low temperature section interferes with each other, has reduced the cooling effect, and the gradient can't be guaranteed to the hot-blast temperature of hot-blast mouth, consequently, in order to guarantee the cooling effect, strengthens the cooling effect, sets up cold wind chamber (43) under the mould, supplies the wind respectively, reaches accurate control purpose.

Technical Field

The invention discloses a dry type treatment device for foam slag and a working mode thereof, relates to the technical field of primary treatment devices for liquid steel slag in the steel industry, and particularly relates to a dry type treatment device for liquid foam slag and a working method thereof.

Background

At present, the generally adopted processing method for steel slag obtained by smelting special steel and steel slag of refining furnaces such as alkaline electric arc furnaces, AOD, LF and the like is to take water with a tank, take non-explosion as a limit, remove slag after the temperature of the slag is reduced, and sort the slag steel dispersed in tailings. The water pumping and cooling process is characterized in that firstly, the required time is 5-7 days long, and the required time is 3-5 days short; secondly, a large amount of water vapor and dust can be generated in the water pumping process and the slag turning process, and hot air flow formed by waste heat rises to form local serious environmental pollution; if more molten steel exists in the tank, large slag lumps can be generated after the tank is provided with water, cooled and turned over, the situations of steel ladle and steel ladle slag are generated, and at the moment, a gun carriage is required to crush the large slag lumps, a large amount of dust can be generated in the crushing process of the gun carriage, and dust pollution is generated on the operation site; meanwhile, in the treatment process, the residual heat in the steel slag is completely discharged to the air in a heat pollution mode, so that a local heat island effect is caused.

The foam slag is directly hot-splashed and tilted to the ground in a slag field, and is naturally cooled in a natural environment; in the natural cooling process, the foam slag is pulverized naturally, the tailing powder and the slag steel are separated naturally in the pulverizing process, but the two are still mixed together; then, solid metal slag steel scattered in the tailing powder is sorted out, and serious dust pollution is generated in the sorting process.

The tailings which are self-pulverized when meeting cold can be generated under the natural air cooling condition, once the tailings meet the wind, the flying dust can fly away along with the wind, and the grass around the slag field can not grow at the place where the dust is scattered. Once it rains, the tailings will penetrate into the ground when it meets the rain, which not only pollutes the ground surface, but also pollutes the underground water quality.

The prior art CN 109136428A proposes a "dry method horizontal rotary type smelting steel slag treatment equipment and waste heat recovery method" to solve various problems brought by the natural cooling of the method of pumping water with a tank and the direct hot splashing method, but the method has the following problems:

1) temperature differential stress and necking stress are generated: the double-layer thick-wall cylinder can repeatedly bear large temperature difference stress due to uneven heating and can generate necking stress at the position provided with the reinforcing ring or the belt, thereby affecting the safety of a mechanical structure;

2) the crushing function effect is poor, and large steel sheets are produced: the inner wall surface of the inner cylinder is provided with a crushing column and is provided with a round hole; if the liquid slag enters the inner cylinder, the liquid slag can directly fall into the surface of the inner wall of the outer cylinder along the circular hole, and the falling liquid slag can be immediately spread on the surface of the inner wall of the outer cylinder to form sheet steel with a larger area; the large steel sheets can be jammed and blocked between the inner cylinder and the outer cylinder, and influence is caused on long-term, safe and stable production;

3) the size of the slag steel is uncertain, and the geometric shape is unshaped; if dry slag enters the equipment, the crushing column plays a role in the crushing function, but the crushing effect cannot be determined, because the shape of slag steel is basically determined during the dry slag, the slag steel rotates and rolls in the rotary inner cylinder, and the crushing effect of the crushing column on the slag steel is limited, so that the shape and the overall dimension of the slag steel are not determined, the slag steel can be left in the inner cylinder and cannot be discharged, and hidden troubles are caused for the subsequent slag steel discharge and burying;

4) sports equipment (parts) cannot be built with refractory materials: because the steel slag treatment equipment is rotary and movable, vibration can occur in the rotary process, and because the refractory material is required to avoid vibration occasions and mechanical vibration is not allowed to occur, the service life of the refractory material is short;

5) the double-layer thick-wall cylinder needs to bear and repeatedly alternate high-temperature radiation baking for a long time under a high-temperature condition, and the oxidation resistance of the material under the high-temperature state, the stability of the structural size under the high-temperature state and the reduction range of the mechanical property can influence the long-term, safe and stable operation of equipment;

in view of the problems in the prior art, it is necessary to develop a novel dry treatment apparatus for foamed slag and its operation method, so as to overcome the problems in the prior art.

Disclosure of Invention

The natural cooling of the site proposed according to the above prior art destroys the environment; the prior dry cooling treatment has the technical problems of poor crushing effect, non-uniform specification and size of steel slag, easy damage of equipment, short service life and the like, and provides the dry treatment equipment for the foam slag and a working mode thereof. The invention mainly utilizes the steel slag conveyor with the casting die with the standard size to cool the steel slag through the cooler while conveying the steel slag, and then completely separates and absorbs slag powder through the slag-steel separator, thereby achieving the purposes of thorough slag-powder separation, uniform steel slag size, stable and safe equipment operation and long-term use.

The technical means adopted by the invention are as follows:

a foamed slag dry treatment apparatus includes: the device comprises a tundish, an anti-sticking agent laying device, a cooler, a steel slag conveying device, a cooling fan, a apron conveyor, a slag-steel separator, a dust remover, a plate conveyor and a detection instrument;

further, the steel slag conveying device penetrates through the whole cooling machine;

furthermore, the tundish is arranged at the front end of the cooler, and the slag notch opening part of the tundish is positioned at the upper part of the front end of the steel slag conveying device;

furthermore, the anti-sticking agent laying device is arranged at the front end of the cooling machine, and the outlet end of the anti-sticking agent laying device is arranged at the upper part of the front end of the steel slag conveying device and is positioned at the front end of the opening part of the slag groove;

furthermore, a plurality of cooling fans are arranged on one side of the cooler, and air outlets of the cooling fans are respectively communicated with an upper air inlet and a lower air outlet on the side part of the cooler to cool the inside of the cooler;

furthermore, one end of the apron conveyor is respectively arranged below the hopper at the tail end of the cooler, and the other end of the apron conveyor is arranged on the slag-steel separator to convey the slag and the steel into the slag-steel separator;

further, the top end of the slag and steel separator is connected with a dust remover through a pipeline;

further, a plate conveyor is arranged at the bottom of the slag and steel separator;

further, the detecting instruments are arranged at different positions of the cooling machine and used for detecting the operation condition inside the cooling machine.

Further, the main body of the cooling machine is a shell;

furthermore, a high-temperature air port, a medium-temperature air port and a low-temperature air port are sequentially arranged on the upper part of the shell from front to back;

furthermore, a middle-high temperature section separation wall is arranged on the inner side of the upper wall of the shell between the high-temperature tuyere and the medium-temperature tuyere;

furthermore, a middle-low temperature section isolation wall is arranged on the inner side of the upper wall of the shell between the middle-temperature tuyere and the low-temperature tuyere;

furthermore, a plurality of pairs of upper air inlets and lower air inlets are uniformly distributed on one side wall of the shell; the pair of upper air ports and the lower air ports are connected with a cooling fan through a pipeline;

further, a hopper is arranged at the lower end of the tail part of the shell and is positioned at the lower part of the tail end of the steel slag conveying device;

further, the bottom of the hopper is provided with a discharge valve.

Further, the steel slag conveying device comprises: the steel slag casting device comprises a steel slag conveyor, a casting die, a lower die cold air chamber, a discharge valve, a material leakage conveyor and a main transmission;

further, the steel slag conveyor is arranged inside the shell;

furthermore, a plurality of rows and columns of casting molds are uniformly distributed on a conveying belt of the steel slag conveyor;

further, the main transmission is arranged on a main transmission shaft at the rear end of the steel slag conveyor to drive the steel slag conveyor to rotate;

furthermore, the lower part of the steel slag conveyor is provided with lower mold cold air chambers with the same number as that of the cooling fans, and the lower mold cold air chambers are opposite to the positions of the upper air opening and the lower air opening;

furthermore, the lower part of the cold air chamber under the die is of a hopper-shaped structure, and the bottom of the hopper-shaped structure is provided with a discharge valve;

furthermore, the material leaking conveyor is arranged at the bottom in the shell, is positioned at the lower part of the cold air chamber under the die, receives the material slag falling from the material leaking conveyor and conveys the material slag to the hopper.

Furthermore, the slag groove of the tundish is inserted into the shell from the front wall of the shell, the opening part of the slag groove is positioned above the first row of casting molds in the horizontal state, and the casting molds in the horizontal state of the first row are cast.

Further, the anti-sticking agent applicator includes: the device comprises a compressed gas storage, an anti-sticking agent storage, a mixer, a pipeline and a valve;

further, the compressed gas storage device and the anti-sticking agent storage device are respectively connected with the mixer through a pipeline and a valve;

furthermore, the mixer is provided with a spraying pipe, the spraying pipe is inserted into the shell from the upper wall of the front end of the shell, and the opening of the spraying pipe is positioned above the casting dies in the front row of the casting dies opposite to the opening of the slag groove.

Furthermore, the cooling fan is communicated with the upper air inlet and the lower air inlet through a one-to-two pipeline to supply air to the interior of the shell.

Further, the slag-steel separator includes: the device comprises a grid sieve, a separation fan, a separation air pipe and a sealing shell;

further, the grizzly screen is arranged at the middle lower part in the sealing shell;

furthermore, a plurality of separation air pipes are arranged on the sealing shell, and the separation air pipes are positioned at the lower part of the grizzly;

furthermore, the separation fan is communicated with the separation air pipe through a pipeline, and supplies air to the inside of the sealed shell to blow the steel and slag on the upper part of the grizzly.

Furthermore, the inner wall of the shell is adhered and built with a refractory material layer, so that the shell can bear high-temperature radiation baking, and the cooler is ensured to be repeatedly used for a long time.

Further, the instrumentation JCYB includes: cooling air temperature LFT, hot air temperature RFT, material temperature WLT, cold air pressure LFY, hot air pressure RFY, differential pressure CY and a high-temperature industrial monitor JSQ;

further, the cooling air temperature LFT includes: the air temperature LT1 of the upper air inlet and the air temperature LT2 of the lower air inlet; respectively arranged on the upper air inlet and the lower air inlet;

further, the hot blast temperature RFT includes: high-temperature air temperature RT1, medium-temperature air temperature RT2 and low-temperature air temperature RT 3; respectively arranged on a high-temperature tuyere, a medium-temperature tuyere and a low-temperature tuyere;

further, the material temperature WLT includes: tundish temperature bottom LW1, cooler discharge temperature LE 2; respectively arranged at the tundish and the hopper;

further, the cool air pressure LFY includes: the upper tuyere wind pressure LFY1 and the lower tuyere wind temperature LFY 2; respectively arranged on the upper air inlet and the lower air inlet;

further, the hot air pressure RFY includes: high-temperature wind pressure RFY1, medium-temperature wind pressure RFY2 and low-temperature wind pressure RFY 3; respectively arranged on a high-temperature tuyere, a medium-temperature tuyere and a low-temperature tuyere;

further, the differential pressure CY includes: differential pressure CYZD between the high-temperature section and the medium-temperature section, and differential pressure CYDD between the medium-temperature section and the low-temperature section; respectively arranged on the middle and high temperature section separation wall and the middle and low temperature section separation wall;

further, the high temperature industrial monitor JSQ includes: a tundish monitor JSZB, a high-temperature segment monitor JSGW, a middle-temperature segment monitor JSZW and a low-temperature segment monitor JSDW; respectively arranged in the high temperature area, the middle temperature area and the low temperature area of the tundish and the shell.

Further, the working mode of the foamed slag dry-type treatment equipment comprises the following steps:

A. laying an anti-sticking agent: starting an anti-sticking agent laying device to lay the anti-sticking agent in the casting mould which runs in no load;

B. transferring steel slag: the molten slag liquid obtained at the smelting end point is transferred to the upper part of the tundish from the slag pot and gradually poured into the tundish;

C. raw slag casting: in the cooler, a slag groove obliquely arranged on the bottom surface of the tundish penetrates through the shell of the cooler and enters the cooler; directly casting the raw slag liquid in a casting mould with the anti-sticking agent through a slag groove, and simultaneously casting the casting mould in the width direction;

D. forced cooling and heat exchange: in the process that a casting die bears the raw slag liquid and runs from an inlet to an outlet, ambient air blown by a cooling fan enters a cooling machine through an upper air port and a lower air port in the middle of the side surface of a shell, and gas-liquid and gas-solid heat exchange and raw slag phase change heat exchange are carried out between the ambient air and the raw slag liquid; finally, the ambient atmospheric temperature rises to form hot flue gas, and the liquid raw slag liquid is gradually cooled;

E. separating slag from steel: the casting mould which carries the casting raw slag liquid by the steel slag conveyor gradually moves from a point I to a point II, the raw slag liquid and the mould are continuously forced to be cooled by ambient air which is blown in by a cooling fan and enters from an air inlet and a lower air inlet which are arranged in the middle of the shell, and gas-liquid, gas-solid heat exchange and phase change heat exchange are carried out between the air and the raw slag liquid; the principle of the heat exchange is operated according to the principle of 'self-powdering when meeting cold' of the foam slag, namely the lowest temperature in the cooling machine is required to be controlled within the temperature range of 'self-powdering when meeting cold' of the foam slag, the foam slag is completely pulverized, tailings and slag steel are automatically separated in a casting die, and the slag steel in the slag is molded according to the shape of the casting die; along with the operation of the steel slag conveyor and the continuous casting of the raw slag liquid, the temperature of the smoke gas in the shell is gradually reduced from the high point to the low point from the I point; entering a hopper and discharging out of the cooler;

F. separating and recovering waste heat: the space inside the middle and high temperature section separation wall and the space above the steel slag conveyor in the shell are divided into a high temperature section, a middle temperature section and a low temperature section; the high-temperature tuyere is arranged at the high-temperature section, the medium-temperature tuyere is arranged at the medium-temperature section, and the low-temperature tuyere is arranged at the low-temperature section; after gas-liquid and gas-solid heat exchange is carried out between the ambient atmosphere and the raw slag liquid, the temperature of the ambient atmosphere rises to form hot flue gas and carry the waste heat of the raw slag liquid, and the hot flue gas is separated from the raw slag liquid and exists in a hot air form; hot air is pumped out from the high-temperature air port, the medium-temperature air port and the low-temperature air port respectively, and after dust is removed by a dust remover, the cascade recovery of waste heat is realized;

G. and (4) finished product transportation: the cooler bears the raw slag casting mould and runs from the inlet to the outlet through the main transmission. When the original slag liquid loaded in the first row of casting moulds is changed into a high-temperature solid state from a high-temperature liquid state under the continuous cooling action of an external cooling fan, the original slag liquid gradually enters a self-powdering temperature interval, steel slag is subjected to self-powdering when meeting cold in the temperature interval, tailing powder is directly separated from the steel slag, and the steel slag and the tailing are automatically separated; in the process of continuously transporting towards the outlet, the tailing powder and the slag steel are naturally separated, but are co-located in the same casting mold and continuously cooled by the ambient atmosphere; when the temperature is reduced to normal temperature, just at the casting die of the steel slag conveyor, when the steel slag conveyor moves to the discharging position II, the casting die is gradually changed from a horizontal upward bearing state to a reverse 180-degree downward state, and the steel slag in the casting die automatically breaks away from the casting die and falls into a hopper under the action of gravity; in order to prevent the unorganized outside cold air from entering the cooling machine, the discharge valve is required to have a certain height, the discharge channel is naturally closed by the processed steel slag mixture, and the leakage of the ambient cold air into the cooling machine is reduced to the maximum extent so as to avoid the temperature reduction of the waste heat and the smoke;

H. separating tailings from block steel: the mixture of the tailings and the slag steel which are unloaded through the discharge valve and cooled to the normal temperature is conveyed to the closed separator by the apron conveyor to be unloaded; the unloaded mixture is coupled on a grid sieve, ambient air blown by a separation fan enters a sealed shell through separation air pipes uniformly distributed around the lower part of the grid sieve, and is blown upwards through the lower part of the grid sieve, and self-powder dust in the mixture is pumped out of a separator along with separation gas under the negative pressure action of a dust remover fan 81 and enters a dust remover for dust removal; due to the blocking of the grid sieve, the tailing powder mixed and attached to the surface of the slag steel block is collided and vibrated by the grid sieve, the self-powder dust is separated from attachments again, the environmental air blown by the separation fan is blown away, and meanwhile, the tailing powder is sucked into the dust remover under the negative pressure suction action of the dust removal fan 81, captured and collected and stored in a centralized manner; the cast slag steel blocks fall into the bottom of the separator to form a material layer with a certain thickness, and the material layer is directly conveyed out of a factory by a plate conveyor, or is sent to steel making, or is sent to a steel making raw material warehouse; the discharged tailing powder in the steel slag mixture is pumped out by the negative pressure of a dust removal fan in the falling process, enters a dust remover, is collected in a centralized manner, and is transported and stored in a unified manner;

I. detection control: the method comprises the steps of determining a certain position between a middle-temperature section and a low-temperature section as a cold self-powdering temperature interval by detecting the temperature of a cold air chamber under each die, the temperature of a high-temperature air port, a middle-temperature air port and a low-temperature air port, the pressure under each chamber and the differential pressure between hot air ports, monitoring the cold self-powdering condition of foam slag by a high-temperature section monitor in a detection instrument to stabilize the foam slag in a certain fixed area of a cooler, stabilizing the air volume of the cooler by closed-loop control and adjusting the air volume or pressure of the cooler to stabilize the air volume of the cooler so as to stabilize the powdering position interval of the foam slag, wherein the temperature of the cold air chamber under each die, the temperature of the high-temperature air port, the temperature of the middle-temperature air port and the low-temperature air port, and the pressure under each chamber are not moved back and forth along the length direction of the cooler;

J. the steel slag enters a casting die, is driven by a cooler to run towards an outlet side, and can splash outside the casting die and fall into a cold air chamber under the die in the cooling process, when the accumulated material in a hopper of the cold air chamber under the die is increased to a certain degree, a discharge valve acts to discharge the accumulated ash to a material leaking conveyor in the running process, the material leaking conveyor conveys the material leaking to the hopper of the cooler, and the material leaking conveyor is uniformly discharged out of the cooler to be transferred to a next process.

K. A cold air chamber under the casting mould is arranged below the casting mould of the steel slag conveyor; one lower mold cold air chamber corresponds to one or more cooling fans; the lower cooling chamber of the mold is used for dividing the steel slag conveyor into a plurality of cooling sections, and the temperature of the cooling sections is gradually reduced from an inlet to an outlet; if there is not the cold wind room under the mould, then the cold wind that cooling blower bloated into can be "turbulent flow" state in the cooler, and the cooling wind between high temperature section, middle temperature section, the low temperature section interferes with each other, has reduced the cooling effect, and the gradient can't be guaranteed to the hot-blast temperature of hot-blast mouth, consequently, in order to guarantee the cooling effect, strengthens the cooling effect, sets up the cold wind room under the mould, supplies wind respectively, reaches accurate control purpose.

Compared with the prior art, the invention has the following advantages:

1. the liquid foam slag dry processing equipment and the working mode thereof provided by the invention overcome the problems of secondary pollution (dust, water vapor, mixture of the dust and the water vapor, surface water quality, underground water quality, local heat island, sludge and other various forms) caused by using liquid water as a refrigerant in the prior art;

2. according to the liquid foam slag dry processing device and the working mode thereof, a gun carriage crushing link in the traditional secondary processing link is omitted, dust pollution caused by large slag crushing and slag steel sorting in the traditional secondary processing link is thoroughly eliminated, and all energy consumption in the secondary processing link is saved;

3. according to the liquid steel slag dry processing device and the working mode thereof, only one separator, a dust remover and other auxiliary equipment completely replace the traditional equipment in the whole process of secondary processing, so that the occupied area is greatly saved, the processing period is shortened, the efficiency is improved, and the investment and the operation cost are reduced;

4. the liquid steel slag dry processing device and the working mode thereof provided by the invention solve the problems in the prior art CN 109136428A.

In conclusion, the technical scheme of the invention solves the problem of secondary pollution caused by cooling the conventional equipment in the prior art by using liquid water as a refrigerant and adopting a water pumping method with a tank; the problems of dust pollution and various secondary pollution caused by natural cooling by a direct hot splashing method with air as a refrigerant in the conventional treatment method in the prior art are solved; and the problem in CN 109136428A.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a view A-A of FIG. 1 in accordance with the present invention;

FIG. 3 is a crystal transition phase diagram of the foamed slag of the present invention;

FIG. 4 is a schematic view of the anti-adhesion agent laying device of the present invention;

FIG. 5 is a view B-B of FIG. 2 according to the present invention.

In the figure:

1. a tundish 11 and a slag groove;

2. an anti-sticking agent laying device 21, a compressed gas storage 22, an anti-sticking agent storage 23, a mixer 24 and an ejection pipe;

3. the cooling machine 31, the high-temperature tuyere 32, the medium-temperature tuyere 33, the low-temperature tuyere 34, the shell 341, the middle and high-temperature section partition wall 342, the middle and low-temperature section partition wall 343, the upper tuyere 344, the lower tuyere 35, the hopper 36 and the discharge valve;

4. the steel slag conveying device 41, the steel slag conveyor 42, the casting die 43, the lower die cold air chamber 44, the discharge valve 45, the material leakage conveyor 46 and the main transmission;

5. a cooling fan;

6. a apron conveyor;

7. a slag and steel separator 71, a grid 72, a separation fan 73, a separation air pipe 74 and a sealed shell;

8. a dust remover 81 and an induced draft fan;

9. a slat conveyor.

Detailed Description

It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the invention, its application, or uses. 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.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of exemplary embodiments according to the invention. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, and it should be understood that when the terms "comprises" and/or "comprising" are used in this specification, they specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof, unless the context clearly indicates otherwise.

The relative arrangement of the components and steps, the numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present invention unless specifically stated otherwise. Meanwhile, it should be understood that the sizes of the respective portions shown in the drawings are not drawn in an actual proportional relationship for the convenience of description. Techniques, methods, and apparatus known to those of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate. In all examples shown and discussed herein, any particular value should be construed as merely illustrative, and not limiting. Thus, other examples of the exemplary embodiments may have different values. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, further discussion thereof is not required in subsequent figures.

In the description of the present invention, it is to be understood that the orientation or positional relationship indicated by the directional terms such as "front, rear, upper, lower, left, right", "lateral, vertical, horizontal" and "top, bottom", etc., are generally based on the orientation or positional relationship shown in the drawings, and are used for convenience of description and simplicity of description only, and in the absence of any contrary indication, these directional terms are not intended to indicate and imply that the device or element so referred to must have a particular orientation or be constructed and operated in a particular orientation, and therefore should not be considered as limiting the scope of the present invention: the terms "inner and outer" refer to the inner and outer relative to the profile of the respective component itself.

Spatially relative terms, such as "above … …," "above … …," "above … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". The device may be otherwise variously oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

It should be noted that the terms "first", "second", and the like are used to define the components, and are only used for convenience of distinguishing the corresponding components, and the terms have no special meanings unless otherwise stated, and therefore, the scope of the present invention should not be construed as being limited.

As shown in the figure, the invention provides a dry treatment device for foamed slag, which comprises: the device comprises a tundish 1, an anti-sticking agent laying device 2, a cooler 3, a steel slag conveying device 4, a cooling fan 5, a apron conveyor 6, a slag-steel separator 7, a dust remover 8, a plate conveyor 9 and a detection instrument; the steel slag conveying device 4 penetrates through the whole cooling machine 3; the tundish 1 is arranged at the front end of the cooler 3, and the opening part of a slag groove 11 of the tundish is positioned at the upper part of the front end of the steel slag conveying device 4; the anti-sticking agent laying device 2 is arranged at the front end of the cooling machine 3, and the outlet end of the anti-sticking agent laying device is arranged at the upper part of the front end of the steel slag conveying device 4 and is positioned at the front end of the opening part of the slag groove 11; the cooling fans 5 are arranged on one side of the cooler 3, and air outlets of the cooling fans are respectively communicated with an upper air inlet 343 and a lower air outlet 344 on the side part of the cooler 3 to cool the inside of the cooler 3; one end of the apron conveyor 6 is respectively arranged below the hopper 35 at the tail end of the cooler 3, and the other end of the apron conveyor is arranged on the slag-steel separator 7 to convey the slag and the steel into the slag-steel separator 7; the top end of the slag and steel separator 7 is connected with a dust remover 8 through a pipeline; a plate conveyor 9 is arranged at the bottom of the slag and steel separator 7; the detecting instruments are arranged at different positions of the cooler 3 and used for detecting the operation condition inside the cooler 3.

The main body of the cooler 3 is a housing 34; the upper part of the shell 34 is provided with a high-temperature tuyere 31, a medium-temperature tuyere 32 and a low-temperature tuyere 33 from front to back in sequence; a middle and high temperature section isolation wall 341 is arranged on the inner side of the upper wall of the shell 34 between the high temperature tuyere 31 and the middle temperature tuyere 32; a middle and low temperature section isolation wall 342 is arranged on the inner side of the upper wall of the shell 34 between the middle temperature tuyere 32 and the low temperature tuyere 33; a plurality of pairs of upper wind ports 343 and lower wind ports 344 are uniformly distributed on one side wall of the shell 34; a pair of the upper and lower vents 343 and 344 are connected to a cooling fan 5 through a duct; a hopper 35 is arranged at the lower end of the tail part of the shell 34, and the hopper 35 is positioned at the lower part of the tail end of the steel slag conveying device 4; the bottom of the hopper 35 is provided with a discharge valve 36.

The steel slag conveying device 4 includes: a steel slag conveyor 41, a casting die 42, a lower die cold air chamber 43, a discharge valve 44, a material leakage conveyor 45 and a main transmission 46; the steel slag conveyor 41 is arranged inside the shell 34; a plurality of rows and columns of casting molds 42 are uniformly distributed on a conveying belt of the steel slag conveyor 41; the main transmission 46 is arranged on a main transmission shaft at the rear end of the steel slag conveyor 41 and drives the steel slag conveyor 41 to rotate; the lower part of the steel slag conveyor 41 is provided with lower mold cold air chambers 43 the number of which is the same as that of the cooling fans 5, and the lower mold cold air chambers are opposite to the positions of the upper air inlet 343 and the lower air inlet 344; the lower part of the lower mold cold air chamber 43 is of a hopper-shaped structure, and the bottom of the hopper-shaped structure is provided with a discharge valve 44; the material leaking conveyor 45 is arranged at the bottom in the shell 34, is positioned at the lower part of the cold air chamber 43 under the die, receives the material slag falling from the material leaking conveyor 45, and conveys the material slag to the hopper 35.

The slag groove 11 of the tundish 1 is inserted into the shell 34 from the front wall of the shell 34, the mouth of the slag groove is positioned above the first row of casting dies 42 in the horizontal state, and the casting dies 42 in the horizontal state of the first row are cast.

The anti-sticking agent laying device 2 comprises: a compressed gas storage 21, an anti-sticking agent storage 22, a mixer 23, pipes and valves; the compressed gas storage 21 and the anti-sticking agent storage 22 are respectively connected with the mixer 23 through pipelines and valves; the mixer 23 is provided with a discharge pipe 24, and the discharge pipe 24 is inserted into the housing 34 from the upper wall of the front end of the housing 34, and the mouth thereof is positioned above the casting die 42 in the front row of the casting die 42 opposite to the mouth of the slag chute 11.

The cooling fan 5 is connected to the upper air inlet 343 and the lower air inlet 344 through a one-to-two pipe, and supplies air to the inside of the casing 34.

The slag-steel separator 7 comprises: a grid 71, a separation fan 72, a separation air pipe 73 and a sealing shell 74; the grizzly 71 is arranged at the middle lower part in the sealed shell 74; a plurality of separation air pipes 73 are arranged on the sealed shell 74, and the separation air pipes 73 are positioned at the lower part of the grizzly 71; the separation fan 72 is connected to a separation air duct 73 through a duct, and blows steel and slag on the upper portion of the lattice 71 by supplying air into the sealed case 74.

The inner wall of the shell 34 is adhered and laid with a refractory material layer, so that the shell 34 can bear high-temperature radiation baking, and the cooler 3 is ensured to be repeatedly used for a long time.

The working mode of the foam slag dry-type treatment equipment comprises the following steps:

A. laying an anti-sticking agent: starting the anti-sticking agent laying device 2 to lay the anti-sticking agent into the casting mold 41 which runs in a no-load mode;

B. transferring steel slag: the molten slag liquid obtained at the smelting end point is transferred to the upper part of the tundish 1 from a slag pot and gradually poured into the tundish 1;

C. raw slag casting: in the cooler 3, the slag groove 11 obliquely arranged on the bottom surface of the tundish 1 passes through the shell 34 of the cooler 3 and enters the cooler 3; the raw slag liquid is directly cast in the casting mold 42 with the anti-sticking agent already laid through the slag groove 11, and the casting mold 42 is simultaneously cast in the width direction;

D. forced cooling and heat exchange: in the process that the casting die 42 carries the raw slag liquid and runs from the inlet to the outlet, the ambient atmosphere blown by the cooling fan 5 enters the cooling machine 3 through the upper air inlet 343 and the lower air inlet 344 in the middle of the side surface of the shell 34, and gas-liquid and gas-solid heat exchange and raw slag phase change heat exchange are carried out between the ambient atmosphere and the raw slag liquid; finally, the ambient atmospheric temperature rises to form hot flue gas, and the liquid raw slag liquid is gradually cooled;

E. separating slag from steel: as the steel slag conveyor 41 carries the casting mold 42 for casting the raw slag liquid to gradually move from the point I to the point II, the raw slag liquid and the mold are continuously forced to be cooled by the ambient atmosphere blown in by the cooling fan 5 and entering from the air inlet 343 arranged in the middle of the shell 34 and the lower air inlet 342, and gas-liquid, gas-solid heat exchange and phase change heat exchange are carried out between the air and the raw slag liquid; the principle of the heat exchange is operated according to the principle of 'self-powdering when meeting cold' of the foam slag, namely the lowest temperature in the cooler 3 is required to be controlled within the temperature range of 'self-powdering when meeting cold' of the foam slag, the foam slag is completely pulverized, tailings and slag steel are automatically separated in a casting die, and the slag steel in the slag is molded according to the shape of the casting die 42; along with the operation of the steel slag conveyor 41 and the continuous casting of the raw slag liquid, the temperature of the smoke gas in the shell 34 is gradually reduced from the point I to the point II; enters the hopper 35 and is discharged out of the cooler 3;

F. separating and recovering waste heat: the middle-high temperature section separation wall 341 and the middle-low temperature section separation wall 342 in the shell 34 divide the space in the shell 34 and above the steel slag conveyor 41 into a high temperature section, a middle temperature section and a low temperature section; the high-temperature tuyere 31 is arranged at a high-temperature section, the medium-temperature tuyere 32 is arranged at a medium-temperature section, and the low-temperature tuyere 33 is arranged at a low-temperature section; after gas-liquid and gas-solid heat exchange is carried out between the ambient atmosphere and the raw slag liquid, the temperature of the ambient atmosphere rises to form hot flue gas and carry the waste heat of the raw slag liquid, and the hot flue gas is separated from the raw slag liquid and exists in a hot air form; hot air is respectively pumped out from the high-temperature tuyere 31, the medium-temperature tuyere 32 and the low-temperature tuyere 33, and after dust is removed by a dust remover, the waste heat gradient recovery is realized;

G. and (4) finished product transportation: the cooler 4 carries a raw slag casting mould 42 which is driven by a main drive 46 from an inlet to an outlet. When the raw slag liquid carried in the first row of casting dies 42 is changed from a high-temperature liquid state into a high-temperature solid state under the continuous cooling action of the external cooling fan 5, the raw slag liquid gradually enters a self-powder temperature interval, the steel slag is self-powdered when meeting cold in the temperature interval, the tailing powder is directly separated from the steel slag, and the steel slag and the tailing are automatically separated; in the process of continuously transporting towards the outlet, the tailings and the slag steel are naturally separated, but are positioned in the same casting die 42 and are continuously cooled by the ambient atmosphere; when the temperature is reduced to normal temperature, just at the casting die 42 of the steel slag conveyor 41, when the steel slag travels to the discharging position II, the casting die 42 is gradually changed from a horizontal upward bearing state to a reverse 180-degree downward bearing state, and the steel slag in the casting die 42 automatically separates from the casting die 42 and falls into the hopper 35 under the action of gravity; in order to prevent the unorganized outside cold air from entering the cooling machine 3, the discharge valve 36 is required to have a certain height, the discharge channel is naturally closed by the processed steel slag mixture, and the leakage of the ambient cold air into the cooling machine 3 is reduced to the maximum extent so as to avoid the temperature reduction of the waste heat smoke;

H. separating tailings from block steel: the mixture of the tailings and the slag steel which are unloaded through the unloading valve 36 and cooled to the normal temperature is conveyed into the closed separator 7 by the apron conveyor 6 to be unloaded; the discharged mixture is coupled on a grid 71, ambient air blown by a separation fan 72 enters a sealed shell 74 through separation air pipes 73 uniformly distributed around the lower part of the grid 71 and is blown upwards through the lower part of the grid 71, and self-powder dust in the mixture is pumped out of a separator 7 under the negative pressure action of a dust remover fan (8') along with separation gas and enters a dust remover 8 for dust removal; due to the blocking of the grid sieve 71, the tailings powder mixed and attached to the surface of the slag steel block is collided and vibrated by the grid sieve 71, the self-powder dust is separated from attachments again, the environmental air blown by the separation fan 72 is blown away, and meanwhile, the tailings powder is sucked into the dust remover 8 under the negative pressure suction action of the dust removal fan 81, collected and concentrated; the cast slag steel blocks fall into the bottom of the separator 7 to form a material layer with a certain thickness, and the material layer is directly conveyed out of a factory by a plate conveyor 9, or is subjected to steel making, or is conveyed to a steel making raw material warehouse; the discharged tailing powder in the steel slag mixture is pumped out by the negative pressure of a dust removal fan in the falling process, enters a dust remover, is collected in a centralized manner, and is transported and stored in a unified manner;

I. detection control: the temperature of each lower mold cold air chamber 42, the temperature of each high temperature air port 31, the medium temperature air port 32, the low temperature air port 33, the pressure under each chamber and the differential pressure between each hot air port are detected, a certain position between the medium temperature section and the low temperature section is determined as a 'self-powdering when encountering cold' temperature section, the 'self-powdering when encountering cold' condition of the foamed slag is monitored by a high temperature section monitor in a detection instrument, so that the foamed slag is stabilized in a certain fixed area of a cooler 3, and the air quantity or the pressure of the cooling fan 5 is regulated through closed-loop control to stabilize the air quantity of the cooling fan 5, so that the foamed slag powdering position section is stabilized, but the foamed slag powdering position section does not move back and forth along the length direction of the cooler;

J. the steel slag enters the casting die 42, is driven by the cooler 3 to run towards the outlet side, and can splash outside the casting die 42 and fall into the cold air chamber 43 under the die in the cooling process, when the accumulated material in the hopper of the cold air chamber 43 under the die increases to a certain degree, the discharge valve 44 acts to discharge the accumulated ash to the material leaking conveyor 45 in the running process, the material leaking conveyor 45 conveys the accumulated ash to the hopper 35 of the cooler 3, and the accumulated material is uniformly discharged out of the cooler 3 to be transferred to the next process.

K. A lower-die cold air chamber 43 is arranged below the pouring die 42 of the steel slag conveyor 3; one lower-mold cold air chamber 43 corresponds to one or more cooling fans 5; the function of the cold air chamber 43 under the mold is to divide the steel slag conveyor 41 into a plurality of cooling sections, and the temperature of the cooling sections is gradually reduced from the inlet to the outlet; if do not have cold wind chamber 43 under the mould, then the cold wind that 5 drums into of cooling blower can be "turbulent flow" state within cooler 3, and the cooling wind between high temperature section, middle temperature section, the low temperature section interferes with each other, has reduced the cooling effect, and the gradient can't be guaranteed to the hot-blast temperature of hot-blast mouth, consequently, in order to guarantee the cooling effect, strengthens the cooling effect, sets up cold wind chamber 43 under the mould, supplies the wind respectively, reaches accurate control purpose.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.