CN214881614U - Water circulation system and desulfurization sediment processing line are beaten with taking jar to desulfurization sediment - Google Patents

Abstract

The utility model provides a water-beating circulation system with a tank for desulfurizing slag and a desulfurizing slag treatment line, wherein the circulation system comprises a water-beating cooling area and an air-cooling slag-removing area; a desulphurization slag cooling module is arranged above the water pumping cooling area; a group of circulating trolley modules are placed in the water cooling area, and a first movable guide rail and a first hydraulic cylinder pushing machine are arranged at the head end of the base plate; a second movable guide rail and a second hydraulic cylinder pushing machine are arranged at the tail end of the base plate, a first movable ferry vehicle is arranged on the first movable guide rail, and a feeding trolley is arranged on the first movable ferry vehicle; and a second movable ferry vehicle is arranged on the second movable guide rail. In the utility model, the feeding trolleys on the first ferry are fed into the water-pumping cooling area one by one; and the circulating trolley fully cooled by the cooling water is driven out from the other end and matched with a second movable ferry, a second movable guide rail and a second hydraulic cylinder pushing machine to carry out rail changing operation, and the slag tank group enters an air cooling slag decanting area. Therefore, circulation of the water treatment line with the tank is realized, and the operation time is saved.

Description

Water circulation system and desulfurization sediment processing line are beaten with taking jar to desulfurization sediment

Technical Field

The utility model belongs to the technical field of the desulfurization sediment is handled, especially, relate to a water circulating system and desulfurization sediment processing line are beaten with taking jar to desulfurization sediment.

Background

As the largest steel producing country and consuming country in China, the solid waste generated in the steel production process also becomes a non-negligible part in the overall development of the environmental protection industry in China. About 100kg of steel slag is generated per 1t of steel produced according to the current steelmaking technology. The desulfurized slag is produced by removing harmful impurities such as sulfur, silicon and the like in steel making and molten steel secondary refining processes of steel factories.

At present, the domestic desulphurization slag treatment process of most steel mills adopts the following steps: pouring the water into a special slag pool for removing the slag after the water is pumped for a certain time with a tank in a spraying room. In the process of pumping water, the high-temperature liquid slag in the slag pot is cooled by water to generate a large amount of steam and dust, and in the prior art, the cooling module is adopted to cool and remove dust from the slag pot which pumps water to the slag pot. However, in the process of pumping water with a tank, after pumping water with a tank is usually performed on a batch of slag tanks, the batch of slag tanks are transferred, and a batch of new slag tanks are replenished for pumping water with a tank. Therefore, the circulation of the slag pot cannot be replenished, and therefore, the process takes a long time.

Disclosure of Invention

An object of the utility model is to provide a water circulating system and desulfurization sediment processing line are beaten with taking the jar to the desulfurization sediment, can realize the circulation supply of slag ladle and the circulation of desulfurization sediment is handled. In order to achieve the above purpose, the utility model adopts the following technical scheme:

a water circulation system is beaten with taking jar to desulfurization sediment includes: the substrate comprises a water-pumping cooling area and an air-cooling slag-removing area which are symmetrically arranged; a desulphurization slag cooling module is arranged above the water pumping cooling area; a group of circulating trolley modules distributed along the length direction of the water cooling area are placed in the water cooling area, and each circulating trolley module comprises a plurality of circulating trolleys which are parallel to each other; each circulating trolley is detachably provided with a slag tank group;

a first moving guide rail and a first hydraulic cylinder pushing machine are arranged at the head end of the base plate in the length direction, and the first moving guide rail is positioned between the base plate and the first hydraulic cylinder pushing machine; the first moving guide rail is positioned on the outer side of the base plate; the first moving guide rail is arranged along the width direction of the substrate; the output end of the first hydraulic cylinder pushing machine moves along the length direction of the base plate; the first hydraulic cylinder pushing machine is higher than the first moving guide rail and the base plate; a first movable ferry vehicle is arranged on the first movable guide rail, a feeding trolley is arranged on the first movable ferry vehicle, and a slag tank group is arranged on the feeding trolley; the feeding trolley and the circulating trolley have the same structure;

a second moving guide rail and a second hydraulic cylinder pushing machine are arranged at the tail end of the base plate in the length direction, and the second moving guide rail is positioned between the base plate and the second hydraulic cylinder pushing machine; the second moving guide rail is positioned at the outer side of the base plate; the second moving guide rail is arranged along the width direction of the substrate; the output end of the second hydraulic cylinder pushing machine moves along the length direction of the base plate; the second hydraulic cylinder pushing machine is higher than the second moving guide rail and the base plate; the second hydraulic cylinder pushing machine and the first hydraulic cylinder pushing machine are positioned on two sides of a first central line formed by dividing the substrate into a water-pumping cooling area and an air-cooling dreg-waking area; and a second movable ferry vehicle is arranged on the second movable guide rail.

Preferably, the desulfurization slag cooling module comprises a plurality of desulfurization slag cooling units arranged in parallel, and each desulfurization slag cooling unit comprises a water inlet pipe and a dust hood communicated with the output end of the water inlet pipe.

Preferably, the first moving ferry car is detachably connected with the first moving guide rail; the second movable ferry vehicle is detachably connected with the second movable guide rail.

The utility model provides a desulfurization sediment processing line, includes the desulfurization sediment with taking the jar to beat water circulating system, still include a desulfurization sediment that connects the air cooling and awaken the sediment district and awaken sediment slag tapping system, this desulfurization sediment is awaken sediment slag tapping system and is included: the output end of the desulphurization slag decanting tank is connected with a hydraulic tipping sieve, and the output end of the hydraulic tipping sieve is connected with a screen hopper; the output end of the bottom of the undersize funnel is provided with a vibrating feeder, and a belt conveyor is arranged below the vibrating feeder.

Preferably, the output end of the desulfurized slag decanting pool is connected with the hydraulic tipping sieve through a loader.

Preferably, the hydraulic tipper further comprises an electromagnetic chuck crane disposed at the hydraulic tipper screen.

Compared with the prior art, the utility model has the advantages that:

(1) through the cooperation of the first hydraulic cylinder pushing machine, the first movable guide rail and the first movable ferry, the feeding trolleys on the first ferry are sequentially fed into the water-pumping cooling area until all stations in the water-pumping cooling area are full of slag tank groups. After the previous feeding trolley is sent into the water pumping cooling area, an operator is responsible for placing the next feeding trolley on the first movable ferry trolley; and the circulating trolley fully cooled by the cooling water is pulled out from the other end, the rail changing operation is carried out by matching with a second movable ferry, a second movable guide rail and a second hydraulic cylinder pusher at the other end, and the slag pot group enters an air cooling slag waking area. Therefore, circulation of the water treatment line with the tank is realized, and the operation time is saved.

(2) Through the supporting use mobile guide rail, the pay-off platform truck, remove ferry car and hydraulic pressure push away jar machine, the slag ladle that will carry the desulfurization sediment sends into desulfurization sediment cooling module in proper order, cooperate wet dust remover to carry out the new technology of taking a jar to beat water, the dust emission that produces of soaking of beating water in traditional desulfurization sediment processing procedure has effectively been avoided, in addition the factory building, vestibule realization totally enclosed, can follow source and propagation channel dual accuse dirt, effectively guaranteed the safety ring of desulfurization sediment overall process, no dust pollution, production site and all ring edge environment have greatly been improved, the difficult problem of domestic desulfurization sediment processing has been solved.

Drawings

FIG. 1 is a schematic view of a water circulation system with a tank for desulfurizing slag according to an embodiment of the present invention;

FIG. 2 is a left side view of FIG. 1;

FIG. 3 is a right side view of FIG. 1;

FIG. 4 is a block diagram of the cooling module for removing the desulfurized slag shown in FIG. 1;

FIGS. 5 to 9 are views showing the operation of the water circulating system with a tank for desulfurizing slag according to an embodiment of the present invention;

FIG. 10 is a side view of the ladle dewatering cooling process including a ladle dewatering circulation system for desulfurizing slag;

fig. 11 is a slag decanting and discharging system for desulfurized slag according to an embodiment of the present invention.

The device comprises a base plate 1, a circulating trolley 2, a first moving ferry vehicle 3, a first hydraulic cylinder pushing machine 4, a feeding trolley 5, a second moving ferry vehicle 6, a second moving guide rail 7, a second hydraulic cylinder pushing machine 8, a desulphurization residue cooling module 9, a residue tank group 10, a first moving guide rail 11, a base rail 12, a casting bridge crane 13, an electromagnetic chuck crane 14, an operation platform 15, a loading machine 16, a hydraulic tilting screen 17, an undersize funnel 18, a vibrating feeder 19, a belt conveyor 20, an iron remover 21, a metering scale 22 and a desulphurization residue waking pool 23.

Detailed Description

The present invention will now be described in more detail with reference to the drawings, in which preferred embodiments of the invention are shown, it being understood that one skilled in the art could modify the invention herein described while still achieving the beneficial effects of the invention. Accordingly, the following description should be construed as broadly as possible to those skilled in the art and not as limiting the invention.

As shown in FIGS. 1 to 10, a water circulating system with a tank for desulfurizing slag includes: the device comprises a base plate 1, a first hydraulic cylinder pushing machine 4, a first moving guide rail 11, a first moving ferry 3, a feeding trolley 5, a second hydraulic cylinder pushing machine 8, a second moving guide rail 7 and a second moving ferry 6.

The base plate 1 is used for bearing a slag pot which is in a process of watering the slag pot with the slag pot and a slag pot which is already subjected to the process of watering the slag pot with the slag pot. The substrate 1 comprises a water-filling cooling area and an air-cooling slag-removing area which are symmetrically arranged; a desulfurized slag cooling module 9 is arranged above the water-pumping cooling area; a group of circulating trolley 2 modules distributed along the length direction of the water cooling area are placed in the water cooling area, and the circulating trolley 2 modules comprise a plurality of circulating trolleys 2 which are parallel to each other; each circulating trolley 2 is detachably provided with a slag pot group 10; the circulating trolley 2 has the functions of: under the push of the first hydraulic cylinder pushing machine 4, the water enters the second movable ferry 6 from the water cooling area, and then the water is carried to the second hydraulic cylinder pushing machine 8 by the second movable ferry 6, and then the water is carried to the air cooling slag waking area by the second hydraulic cylinder pushing machine 8, namely the hydraulic cylinder pushing machine.

A first movable guide rail 11 and a first hydraulic cylinder pushing machine 4 are arranged at the head end of the base plate 1 in the length direction, and the first movable guide rail 11 is positioned between the base plate 1 and the first hydraulic cylinder pushing machine 4; the first moving guide 11 is located outside the base plate 1; the first moving guide 11 is provided along the width direction of the substrate 1; the output end of the first hydraulic cylinder pushing machine 4 moves along the length direction of the substrate 1; the first hydraulic cylinder pushing machine 4 is higher than the first moving guide rail 11 and the base plate 1; a first movable ferry vehicle 3 is arranged on the first movable guide rail 11, a feeding trolley 5 is arranged on the first movable ferry vehicle 3, and a slag pot group 10 is arranged on the feeding trolley 5; the feeding trolley 5 and the circulating trolley 2 have the same structure. Wherein the first mobile ferry 3 is detachably connected with the first mobile rail 11. In this embodiment, the slag pot group 10 on and above the feed carriage 5 is fed as a supply to the water cooling zone. The replenishment is completed by an operator, namely before the rail replacement process of the water cooling area and the air cooling slag waking area is started, a feeding trolley 5 is placed on the first movable ferry 3, a slag tank group 10 is arranged on the feeding trolley 5, the slag tank group 10 is fully distributed in the water cooling area, the first movable ferry 3 enters a first hydraulic cylinder pushing machine 4 under the driving of a first movable guide rail 11, the feeding trolley on the first movable ferry 3 is pushed to the water cooling area by the first hydraulic cylinder pushing machine 4, then the first movable ferry 3 returns, and the operator places another feeding trolley loaded with the slag tank group 10 on the first movable ferry 3, so that the cyclic replenishment is realized.

A second moving guide rail 7 and a second hydraulic cylinder pushing machine 8 are arranged at the tail end of the base plate 1 in the length direction, and the second moving guide rail 7 is positioned between the base plate 1 and the second hydraulic cylinder pushing machine 8; the second moving guide 7 is positioned outside the base plate 1; the second moving guide 7 is provided along the width direction of the substrate 1; the output end of the second hydraulic cylinder pushing machine 8 moves along the length direction of the substrate 1; the second hydraulic cylinder pushing machine 8 is higher than the second moving guide rail 7 and the base plate 1; the second hydraulic cylinder pushing machine 8 and the first hydraulic cylinder pushing machine 4 are positioned on two sides of a first central line formed by dividing the water-pumping cooling area and the air-cooling slag-waking area of the substrate 1; a second movable ferry vehicle 6 is arranged on the second movable guide rail 7; the second moving carriage 6 is detachably connected to the second moving rail 7.

In this embodiment, the first moving ferry 3 and the second moving ferry 6 may be a bearing plate, or wheels may be disposed at the bottom. The feeding trolley 5 and the circulating trolley 2 can be a bearing plate, and wheels can be arranged at the bottom of the feeding trolley to facilitate smooth pushing of the hydraulic cylinder pushing machine.

In the embodiment, the first hydraulic cylinder pushing machine 4 and the second hydraulic cylinder pushing machine 8 are respectively powered by a hydraulic station.

In this embodiment, the desulfurization slag cooling module 9 includes a plurality of desulfurization slag cooling units arranged in parallel, and each desulfurization slag cooling unit includes a water inlet pipe and a dust hood communicated with an output end of the water inlet pipe.

In the present embodiment, the first moving guide 11 and the second moving guide 7 are the same in structure; the first moving guide rail 11 and the second moving guide rail 7 respectively move along the corresponding base guide rails, for example, the second moving guide rail 7 moves along the base guide rail 12; the first moving rail 11 and the base rail are both prior art.

The working principle of the water circulating system with the tank for the desulfurized slag is as follows, and is shown in figures 5-9:

filling a water-pumping cooling area:

slag liquid generated after the molten iron is desulfurized floats on the surface of the molten iron, and the slag liquid is partially raked into a slag pot by a slag raking machine. The slag pot is transported to a desulphurization slag treatment workshop by using a flat car, and is sequentially hoisted to the feeding trolley 5 by a casting bridge crane 13.

The feeding trolleys 5 on the first ferry are sequentially sent into the water-fetching cooling area through the matching of the first hydraulic cylinder pushing machine 4, the first movable guide rail 11 and the first movable ferry 3 until all stations in the water-fetching cooling area are full of the slag pot group 10. After the previous feeding trolley 5 is sent into the water cooling area, an operator is responsible for placing the next feeding trolley 5 on the first movable ferry 3.

The rail changing process of the water-pumping cooling area and the air-cooling slag-removing area comprises the following steps:

the circulating trolley 2 which is fully cooled by cooling water is pulled out from the other end, the second movable ferry 6, the second movable guide rail 7 and the second hydraulic cylinder pushing machine 8 at the other end are matched for rail changing operation, and the slag pot group 10 enters an air cooling slag waking area. In the filling process of the water cooling area, the feeding trolley 5 enters the water cooling area, and the rail replacing process is generally called as a circulating trolley 2, so that the feeding trolley 5 always borne on the first ferry can be distinguished conveniently.

(1) A feeding trolley 5 (a slag tank group 10 is arranged on the feeding trolley 5), the slag tank group 10 is fully distributed in the water cooling area, and the second movable ferry 6 moves to a position right facing the water cooling area; as shown in fig. 5;

(2) the first hydraulic cylinder pushing machine 4 extends out, a circulating trolley 2 close to the first hydraulic cylinder pushing machine 4 in a water cooling area for applying thrust is pushed, the circulating trolley 2 far away from the first hydraulic cylinder pushing machine 4 in the water cooling area is pushed onto the second movable ferry 6, and as shown in fig. 5, a station close to the first hydraulic cylinder pushing machine 4 in the water cooling area is vacated; the second movable ferry vehicle 6 is arranged to move towards the air cooling slag wake-up area;

(3) the first hydraulic cylinder pushing machine 4 and the first movable ferry 3 return to the original position, and an operator places a new feeding trolley 5 on the first movable ferry 3; at this time, the second moving ferry 6 carries the circulating trolley 2 to a position opposite to the air-cooling slag-removing area, as shown in fig. 6;

(4) the first movable ferry 3 carries the feeding trolley to a position opposite to the water pumping cooling area, at the moment, the second hydraulic push cylinder extends out and applies thrust to the circulating trolley 2 on the second movable ferry 6, and the circulating trolley 2 is pushed into the air cooling slag removing area, as shown in fig. 7;

(5) the first hydraulic cylinder pushing machine 4 extends out and applies thrust to the feeding trolley on the first movable ferry 3, and the feeding trolley is pushed to an idle station in the water pumping cooling area (in the step 2) to realize primary replenishment, as shown in fig. 8; at this time, the second hydraulic cylinder pushing machine 8 is reset, and the second movable ferry 6 on the second movable guide rail 7 is provided with the circulating trolley 2, as shown in fig. 8;

(6) the first hydraulic cylinder pushing machine 4 is reset, the first movable ferry 3 is reset, namely, is positioned at the position opposite to the air cooling slag waking area, and an operator puts a feeding trolley 5 on the first movable ferry 3 again for recycling. Finally, the air cooling slag decanting area is uniformly distributed with full slag pot groups 10, and at the moment, a water pumping circulation with a pot is finished, as shown in fig. 9.

This embodiment has still provided a desulfurization sediment processing line, and the desulfurization sediment is with taking the jar to beat water circulating system, still includes a desulfurization sediment of connecting the air cooling and awakening the sediment district and drench the sediment slag-tap system, as shown in fig. 11, this desulfurization sediment drenches sediment slag-tap system and includes: a desulfurized slag decanting tank 23, the output end of the desulfurized slag decanting tank 23 is connected with a hydraulic tipping sieve 17, and the output end of the hydraulic tipping sieve 17 is connected with a screen hopper 18; the output end of the bottom of the sifting hopper 18 is provided with a vibrating feeder 19, and a belt conveyor 20 is arranged below the vibrating feeder 19. Wherein, the upper end of the sifting hopper 18 is clamped on the operation platform 15.

In the embodiment, the input end of the desulphurization slag decanting tank 23 is provided with a casting bridge crane 13, and the output end of the desulphurization slag decanting tank 23 is connected with a hydraulic tipping sieve 17 through a loader 16.

In this embodiment, further comprises an electromagnetic chuck crane 14 disposed at the hydraulic dump screen 17.

The working principle of the desulphurization slag circulating treatment system is as shown in 11: when a flat car for transporting slag cans arrives, a new slag can is placed into a treatment line of a water-pumping cooling area filling process by using a casting bridge crane 13, the slag can in the air cooling slag-decanting area is lifted, the desulfurized slag in the slag-decanting area is poured into a desulfurized slag-decanting tank 23 on one side, which is positioned on the operation plane 15, for decanting, and the empty slag can is placed on the flat car and returns to steel making to form a process cycle.

The desulfurized slag in the desulfurized slag decanting tank 23 is carried to the hydraulic tipping sieve 17 or the floor sieve by the loader 16 after being fully decanted. The large slag iron on the sieve is selected by an electromagnetic chuck crane 14 and returned to the steel-making for consumption; after the undersize materials are processed by the procedures of screening, magnetic separation and the like, the selected iron is also returned to the steel-making consumption for use, and the rest tailings are sold.

The main span plant of the desulfurization slag treatment line is 154 meters long and 36 meters wide, and the auxiliary span plant is 44 meters long and 33 meters wide. The step-type trolley system, the movable ferry vehicle system and the hydraulic cylinder pushing system are matched for use, the slag pot with the desulphurization slag is sequentially conveyed to the bottom of the dust hood, and the wet dust remover is matched for water pumping with the pot.

1 75/32t casting bridge cranes 13 are arranged in the main span plant for the operation of discharging, loading, lifting and deslagging the desulphurization slag tank. Two sets of trolley stations are arranged in the main span east side semi-range workshop, 13 are arranged in the main span east side semi-range workshop, each circulating trolley 2 (feeding trolley 5) can carry 3 slag pots, and 78 tank stations (except the feeding trolley 5 on the first movable ferry 3) are arranged in total.

39 tank positions on the south side are provided with tank water-pumping cooling areas, a fixed dust hood and a spray pipe are arranged above the tank positions, and 2 30-ten thousand air quantity sieve tube immersion wet dust collectors are matched to ensure ultralow emission during the water pumping of the desulfurization slag with the tanks; the 39 tank positions on the north side are the air cooling slag-removing areas with tanks.

The trolley system comprises a movable ferry and a set of hydraulic trolley systems (a hydraulic station and the movable ferry) which are respectively arranged at two end heads of the substrate 1 and are used for trolley track changing operation of the tank-carrying trolley between a water-filling cooling area and an air cooling slag-removing area, and complete desulphurization slag treatment line circulation is formed in a matching manner.

4 desulfuration residue decanting pools 23 are arranged in the main span west half-width workshop, one residue pool is used for airing and decanting residues, and the other residue pool is used for deslagging, so that the two purposes are achieved. And (3) pouring the desulfurized slag in the air-cooling slag decanting area into a desulfurized slag decanting pool 23 by using a casting bridge crane 13, and then continuously returning the slag pot to the steelmaking workshop for slag charging. Each desulphurization slag pool can be stored for 1 day, namely the desulphurization slag can be separated in the slag pool for about 16-24 hours.

An outlet of the desulphurization slag decanting tank 23 faces to an auxiliary bay plant, slag is discharged by a loader 16, the decanted desulphurization slag is shoveled onto a hydraulic overturning sieve, and large slag irons on the sieve are selected by an electromagnetic chuck crane 14 and returned to be consumed in steel making; after the iron of the undersize material is selected by an iron remover, the selected iron is also returned to the steel-making for use, and the residual tailings are weighed by 22 and sold. The desulphurization slag water-cooling slag-smoldering, slag-pouring, airing slag-removing, floor screening and belt conveyor 20 external conveying and loading operations are all completed in a desulphurization slag treatment workshop.

The desulfurization slag treatment line adopts an advanced domestic hydraulic cylinder pushing system to push a stepping desulfurization slag tank-carrying trolley (a feeding trolley 5 on a first movable ferry 3 and a circulating trolley 2 in a water-pumping cooling area), a fixed dust hood is arranged above the circulating trolley 2 in the water-pumping cooling area, water is pumped with a tank and a wet dust removal process is matched, the emission of dust generated by water-pumping soaking in the traditional desulfurization slag treatment process is effectively avoided, meanwhile, the treatment line factory building adopts a fully-closed steel structure and a stainless steel color tile form and is matched with 2 30 ten thousand screen pipe immersion wet dust collectors, the safety, environmental protection and dust pollution prevention in the whole desulfurization slag treatment process are effectively ensured through source dust control and fully-closed shed dust suppression of the treatment line, the production site and the surrounding environment are greatly improved, and good environmental benefit and ecological benefit are generated. Meanwhile, the desulfurization slag treatment process further reduces the production cost, reduces the discharge of industrial wastewater, reduces the treatment cost of the industrial wastewater and generates good economic benefit.

The above description is only for the preferred embodiment of the present invention, and does not limit the present invention. Any technical personnel who belongs to the technical field, in the scope that does not deviate from the technical scheme of the utility model, to the technical scheme and the technical content that the utility model discloses expose do the change such as the equivalent replacement of any form or modification, all belong to the content that does not break away from the technical scheme of the utility model, still belong to within the scope of protection of the utility model.

Claims (6)

1. The utility model provides a water circulating system is beaten with taking jar to desulfurization sediment which characterized in that includes: the substrate comprises a water-pumping cooling area and an air-cooling slag-removing area which are symmetrically arranged; a desulphurization slag cooling module is arranged above the water pumping cooling area; a group of circulating trolley modules distributed along the length direction of the water cooling area are placed in the water cooling area, and each circulating trolley module comprises a plurality of circulating trolleys which are parallel to each other; each circulating trolley is detachably provided with a slag tank group;

a first moving guide rail and a first hydraulic cylinder pushing machine are arranged at the head end of the base plate in the length direction, and the first moving guide rail is positioned between the base plate and the first hydraulic cylinder pushing machine; the first moving guide rail is positioned on the outer side of the base plate; the first moving guide rail is arranged along the width direction of the substrate; the output end of the first hydraulic cylinder pushing machine moves along the length direction of the base plate; the first hydraulic cylinder pushing machine is higher than the first moving guide rail and the base plate; a first movable ferry vehicle is arranged on the first movable guide rail, a feeding trolley is arranged on the first movable ferry vehicle, and a slag tank group is arranged on the feeding trolley; the feeding trolley and the circulating trolley have the same structure;

a second moving guide rail and a second hydraulic cylinder pushing machine are arranged at the tail end of the base plate in the length direction, and the second moving guide rail is positioned between the base plate and the second hydraulic cylinder pushing machine; the second moving guide rail is positioned at the outer side of the base plate; the second moving guide rail is arranged along the width direction of the substrate; the output end of the second hydraulic cylinder pushing machine moves along the length direction of the base plate; the second hydraulic cylinder pushing machine is higher than the second moving guide rail and the base plate; the second hydraulic cylinder pushing machine and the first hydraulic cylinder pushing machine are positioned on two sides of a first central line formed by dividing the substrate into a water-pumping cooling area and an air-cooling dreg-waking area; and a second movable ferry vehicle is arranged on the second movable guide rail.

2. The water circulating system for desulfurizing slag with the tank according to claim 1, wherein the desulfurizing slag cooling module comprises a plurality of desulfurizing slag cooling units arranged in parallel, and the desulfurizing slag cooling unit comprises a water inlet pipe and a dust hood communicated with an output end of the water inlet pipe.

3. The system of claim 1, wherein the first mobile ferry vehicle is detachably connected to the first mobile rail; the second movable ferry vehicle is detachably connected with the second movable guide rail.

4. A desulfurized slag treatment line comprising the water circulating system with tank for desulfurized slag according to any one of claims 1 to 3, further comprising a desulfurized slag decanting and tapping system connected to the air-cooled slag decanting area, the desulfurized slag decanting and tapping system comprising: the output end of the desulphurization slag decanting tank is connected with a hydraulic tipping sieve, and the output end of the hydraulic tipping sieve is connected with a screen hopper; the output end of the bottom of the undersize funnel is provided with a vibrating feeder, and a belt conveyor is arranged below the vibrating feeder.

5. The desulfurization slag processing line according to claim 4, wherein the output end of the desulfurization slag decanting tank is connected to the hydraulic tipping screen through a loader.

6. The desulfurization slag processing line of claim 4, further comprising an electromagnetic chuck crane disposed at the hydraulic tipping screen.

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