UA76652C2 - A blast furnace water cooling system - Google Patents

Abstract

The invention relates to ferrous metallurgy, in particular - to the structure of the blast furnace water cooling system. A blast furnace water cooling system contains lower and upper zones of cooling with cooled elements, supply pipelines, supply main pipeline, supply collectors of lower and upper cooling zones, lateral pipelines of lower and upper cooling zones, lateral main pipeline and circulation pumps. The system also contains at least two vertical cooling sections, every of which is equipped with gathering main of lower cooling zone and gathering main of the upper cooling zone. The gathering main of the lower cooling zone is connected by pressure pipe with gathering main of the upper cooling zone, and gathering main of the upper cooling zone is connected through lateral main pipeline and circulation pumps with supply main pipeline. At that the system is equipped with expansion vessel, which is disposed above gathering mains of the upper cooling zone and is connected to lateral main pipeline, heat exchanger, which is disposed on lateral main pipeline, mechanism for water incorporation, which contains disposed in parallel pump and valve, which are connected to water source and suction manifolds of circulation pumps and through electric automatics they are connected to the sensor of water level in the expansion vessel, mechanism for making high gas pressure in the expansion vessel. The invention provides an increase of efficiency of the blast furnace cooling and simplification of the structure of water cooling system.

Description

Description of the invention

The invention relates to iron metallurgy and can be used for cooling blast furnaces.

A known device for water cooling of a blast furnace, which contains the lower and upper cooling zones with cooled elements, distribution manifolds, water supply and drainage pipelines, pumps, collection tank and coolers, which are connected to each other by pipelines. The collecting tank is equipped with a pipeline, which is connected to it at both ends and contains a filter and a pump built into it, and the coolers are made in the form of surface heat exchangers (Ass. USSR Mo 603363, IPC? C 21 V 7/10, 1978). The water heated in the cooled elements flows into open watering cans and flows through pipelines into the heated water collection tank, from which it is fed to the surface heat exchangers by pumps. The cooled water is fed back to the blast furnace in the lower cooling zone by pumps. The water in the collection tank is purified by passing it through a filter built into the pipeline, and the sludge is discharged into the sewer. Water consumption in the system is replenished by water replenishment devices. t The water cooling system of the proposed blast furnace and its analogue have the following essential features.

Both systems contain lower and upper cooling zones with cooled elements, distribution manifolds, water supply and drainage pipelines and pumps.

Obtaining the expected technical result when using an analogue is prevented by the following reasons.

The design of the cooling system for the cooled elements of the blast furnace in the form of a single vertical section, as well as the use of drain funnels, a collection tank for heated water, surface heat exchangers and filters for water purification complicates the design of the cooling system. In addition, such a system does not ensure, during the cooling process of the blast furnace, the maintenance of the optimal pressure of the cooled water in the cooled elements of the blast furnace, as well as at the inlet of the circulation pumps.

The closest in terms of features to the claimed invention is the device chosen as a prototype for blast furnace cooling (AS USSR Mo 1014897, IPC s 21 V 7/10, 1983). The known device contains lower and upper cooling zones with cooled elements, inlet pipelines, an underwater main pipeline, inlet manifolds of the lower and upper cooling zones, outlet pipelines of the lower and upper cooling zones, an outlet main pipeline and circulation pumps. Each cooling zone is equipped with a collecting funnel and a hydraulic column, which are interconnected by pipelines. Hydrocodones are connected to circulation pumps. The pump, connected to the hydro column of the lower zone, is installed in the pipeline M) of water supply to the entrance of the upper zone. The pump, connected to the hydro column of the upper zone, is installed in the pipeline, which is connected to the factory network of circulating water supply. Hydrocolumns are equipped with relay floats connected to pump valves. The height of the hydrocolumns is 0.5-1.0 m higher than the height of the corresponding (Se) outlet pipelines from the cooling zones. M

The water cooling system of the proposed blast furnace and the selected prototype have the following essential features. Both systems contain the lower and upper cooling zones with cooled elements, inlet pipelines, inlet main pipeline, inlet manifolds of the lower and upper cooling zones, outlet pipelines of the lower and upper cooling zones, outlet main « 20 pipeline and circulation pumps. -in

The analysis of the technical properties of the prototype, determined by its features, shows that the following reasons prevent obtaining the expected technical result when using it. :z» Execution of the cooling system of the cooled elements of the blast furnace as a single vertical cooling section with annular pipelines for the lower and upper cooling zones, as well as the use of 415 drain funnels, high hydrocolumns of the lower and upper cooling zones, an additional pump connected to -1 hydrocolumn of the lower zone and installed in the water supply pipeline at the entrance of the upper zone, and the connection of the hydro column of the upper zone to the factory network of circulating water supply with technical water complicates (o) the design of the cooling system of the blast furnace. The absence of a closed circuit for cooling water prevents the use of chemically pure water for cooling the blast furnace, which reduces the cooling efficiency due to the formation of low thermal conductivity deposits on the walls of the cooled elements during cooling with technical water.

The basis of the invention is the technical task of creating such a blast furnace water cooling system, in which improvements by introducing new elements and new connections between elements would allow, when using the invention, to ensure the achievement of a technical result, which consists in increasing the efficiency of blast furnace cooling and simplified designs of the water cooling system.

The proposed blast furnace water cooling system is characterized by such essential (Ф) features sufficient to achieve the expected technical result. The system includes the lower and upper cooling zones with cooled elements, inlet pipelines, inlet main pipeline, inlet manifolds of the lower and upper cooling zones, outlet pipelines of the lower and upper cooling zones, outlet main pipeline and circulation pumps.

The water cooling system of the proposed blast furnace contains at least two vertical cooling sections. Each vertical cooling section is equipped with a collection manifold of the lower cooling zone and a collection collector of the upper cooling zone. The collection manifold of the lower cooling zone is connected by a pressure pipeline to the inlet manifold of the upper cooling zone, and the collection collector in the upper cooling zone is connected through the outlet main pipeline and circulation pumps to the inlet main pipeline. A heat exchanger is installed on the outlet main pipeline to cool the water returning to the inlet main pipeline. In addition, the system is equipped with an expansion tank, which is located above the collective collectors of the upper cooling zone and is connected to the branch pipeline. The system is also equipped with a device for introducing water, which contains a pump and a valve installed in parallel, connected to the water source and the suction manifolds of the circulation pumps and electrically connected to the water level sensor in the expansion tank. The system is also equipped with a device for creating increased gas pressure in the expansion tank.

In some cases of use, the water cooling system of the claimed blast furnace 7/o is characterized by the fact that: - it contains four vertical cooling sections; - the device for creating increased gas pressure contains a valve that is connected to the gas source and to the expansion tank and is connected to the gas pressure sensor in the expansion tank through electro-automatics.

When using the invention, it is expected to achieve a technical result, which consists in increasing the cooling efficiency of the blast furnace by 7/5 and simplifying the design of the water cooling system.

There is such a cause-and-effect relationship between the essential features of the claimed water cooling system of the blast furnace and the technical result achieved. The presence in the cooling system of the cooled elements of the blast furnace is not one vertical cooling section, but at least two similar vertical cooling sections, each of which is equipped with a collective collector of the lower cooling zone and a collective collector of the upper cooling zone and, at the same time, a collective collector of the lower cooling zone with is connected by a pressure pipeline to the subducting collector of the upper cooling zone, and the collective collector of the upper cooling zone is connected through the discharge main pipeline and circulation pumps to the subduction main pipeline, and the installation of a heat exchanger on the discharge main pipeline for cooling the water returning to the subduction main pipeline allows c 25 to create at least two closed closed circuits for cooling water, jointly cooling the blast furnace in height from two opposite sides. Equipment of the system with an expansion tank, which is located above i) collective collectors of the upper cooling zone and is connected to the outlet main pipeline, a device for creating increased gas pressure in the expansion tank, a device for introducing water into the system, which contains a pump and a valve installed in parallel, which connected to the water source and the suction manifolds of the circulation pumps and connected to the water level sensor in the expansion tank through electro-automatics, allows to ensure the optimal pressure in each closed circuit of the cooling system of the blast furnace, as well as at the inlet of the circulation pumps and to maintain it at a given level in the process of blast furnace cooling. The supply of water under pressure in the expansion tank to the inlet of the circulation pumps allows them, adding their pressure, to use the water pressure for the purpose. The creation of closed closed ise) 35 circuits for cooling water allows the use of chemically pure water for cooling the blast furnace, which increases the cooling efficiency by preventing the formation of low heat-conducting deposits on the walls of the cooled elements of the blast furnace. Execution of the cooling system of the cooled elements of the blast furnace, at least from two vertical cooling sections and ensuring optimal pressure in the process of cooling the blast furnace in each closed cooling circuit and at the inlet of circulation pumps « 40 without using a system of drain funnels with hydro columns and pumps connected to them simplifies the design of the blast furnace cooling system.

The optimal implementation of the cooling system of the cooled elements of the blast furnace is four;" similar vertical sections of cooling, because simplifying the design of each individual section simplifies the design of the entire water cooling system, in which four separate vertical sections 45 of a similar design jointly cover the blast furnace in height from four opposite sides. -I Equipping the device for creating increased gas pressure in the expansion tank with a valve that is connected to the gas source and the expansion tank and is connected to the pressure sensor through electro-automatic

Me. of gas in the expansion tank ensures optimal pressure during cooling of the blast furnace

He" of cooling water in the cooled elements of the blast furnace, as well as at the inlet of the circulation pumps. 50 The essence of the invention is explained by the graphic material, which shows the schematic diagram of the water cooling system 1 of the blast furnace with the image of one of the four vertical sections.

Ge On the presented schematic diagram of the blast furnace water cooling system, the following elements are indicated by positions: 1 - lower cooling zone; 5B 2 - upper cooling zone;

C - water pipelines; (F) 4 - water pipelines; ka 5 - subducting main pipeline; 6 - underwater collector; at 7 - risers; 8 - underwater collector; 9 - risers; - outlet pipelines; 11 - collective collector; 65 12 - pressure pipeline; 13 - outlet pipelines;

14 - collective collector; 15 - outlet main pipeline; 16 - heat exchanger; 17 - circulation pump; 18 - expansion tank; 19 - pump; - valve; 21 - water source; 70 22 - water level sensor; 23 - gas source; 24 - valve; - gas pressure sensor.

In a specific example, the blast furnace water cooling system (see drawing) that is claimed 7/5 contains four separate vertical cooling sections of a similar design, which together cover the blast furnace in height from four opposite sides. Each vertical section of the cooling system contains a lower cooling zone 1 and an upper cooling zone 2 with cooled elements connected to the inlet pipelines C and 4, respectively. Cooling water is supplied to the system through the main inlet pipeline 5 common to all four sections. Cooling elements of the lower zone 2о cooling 1 are connected by underwater pipelines C to the underwater collector 6. The underwater main pipeline 5 is connected to the underwater collectors of each of the four vertical sections through the risers 7.

The underwater collector b of this vertical cooling section is connected to the underwater main pipeline 5 through the riser 7. The cooled elements of the upper cooling zone 2 are connected by underwater pipelines 4 to the underwater collector 8. To drain the heated water from the four vertical sections of the cooling system into the outlet main pipeline, risers 9. To remove the heated water from the cooled elements of the lower cooling zone 1, outlet pipelines 10 are installed, which are connected to (8) collecting manifold 11. Collecting collector 11 is connected by a pressure pipeline 12 to the inlet manifold 8 of the upper cooling zone 2. For for the removal of heated water from the cooled elements of the upper cooling zone 2, outlet pipelines 13 are installed, which are connected to the collection collector 14. The collection collector 14 is connected through the riser 9 to the outlet main pipeline 15, on which a heat exchanger 16 for cooling water is installed, that returns to the sub-main and pipeline. The outlet main pipeline 15 is connected through the circulation pump 17 to the supply main pipeline 5 for the formation of a closed cooling circuit in each vertical section. The cooling system is equipped with an expansion tank 18, which is located above the collective collectors 14 of the upper cooling zone 2 and ise) connected to the outlet main pipeline 15. In addition, the water cooling system of the blast furnace is equipped with a device for introducing water into the cooling system containing a pump 19 and a valve 20 are installed in parallel, which are connected to the water source 21 and the suction manifolds of the circulation pumps 17 and are connected to the water level sensor 22 in the expansion tank 18 through electrical automation. The cooling system is also equipped with a device for creating increased gas pressure in the expansion tank tanks 18. Nitrogen was used to create "higher gas pressure." The gas source 23 is connected to the valve 24, which is connected to the gas pressure sensor 25 in the expansion tank 18 and is connected to the expansion tank to connect it to the gas source 23. Cooling of the blast furnace using the claimed water cooling system is carried out as follows. First, the cooling system with the open air valve on the expansion tank 18

It is filled through the valve 20 of the water inlet device with chemically clean water from the water source 21. After reaching the specified water level in the expansion tank 18 according to the signal of the water level sensor 22, the valve 20 is also closed in the expansion tank 18, after it is purged with nitrogen, the necessary excess is created me) pressure of nitrogen, supplying it from the gas source 23 through the valve 24. Then, after reaching the optimal pressure

The flow of cooling water in the cooled elements of the blast furnace, as well as at the inlet of the circulation pumps, includes the circulation pumps 17. The supply of water under pressure to the inlet of the circulation pumps 17 allows them, adding their own pressure, to use the water pressure for the purpose. Cooling water from common for all four vertical sections

The cooling water of the subducting main pipeline 5 through the risers 7, subducting collectors 6 and subducting pipelines З is supplied to the cooled elements of the lower cooling zone 1. After passing through the lower cooling zone 1, the water heated to 32C flows through the discharge pipelines 10 into the collective collectors 11. Next

From the collective collector 11 of the corresponding vertical section, the cooling water through the pressure pipeline 12, inlet manifold 8 and inlet pipelines 4 is supplied to the cooled elements of the upper cooling zone 2. into collective collectors 14, from which through risers 9 it flows into the outlet main pipeline 15, on which the heat exchanger 16 is installed. cooling the cooled elements of the blast furnace with chemically pure water increases the cooling efficiency by preventing the formation of low heat-conducting deposits on the walls of the cooled elements of the blast furnace.

If in the process of cooling the blast furnace, the water level in the expansion tank 18 drops to the first 65 working level, then the valve 20 opens at the command of the water level sensor 22 and the system is filled with water from the water source 21. When the water level in the expansion tank 18 drops to the second working level , then at the command of the water level sensor 22, the pump 19 is turned on and the system is replenished with water from the water source 21 until the set level is restored. The system is supplied with water in the suction manifold of the circulation pump 17, and not in the expansion tank 18, which also simplifies the design of the system and its operation. The necessary excess pressure of nitrogen in the expansion tank 18 is maintained by supplying nitrogen from the gas source 23 to the expansion tank through the valve 24 at the command of the gas pressure sensor 25.

The use of the proposed blast furnace water cooling system makes it possible to increase the cooling efficiency of the blast furnace by simplifying the design of the system.

Claims (3)

The formula of the invention 1. The water cooling system of the blast furnace, which contains the lower and upper cooling zones with cooled elements, subducting pipelines, subducting main pipeline, subducting collectors of the lower and upper cooling zones, outlet pipelines of the lower and upper cooling zones, outlet main pipeline and circulation pumps, which characterized by the fact that it contains at least two vertical cooling sections, each of which is equipped with a lower cooling zone header and an upper cooling zone header, the lower cooling zone header being connected by a pressure pipe to the upper cooling zone inlet header, and the header of the upper cooling zone is connected through the outlet main pipeline and circulation pumps to the inlet main pipeline, the system is also equipped with an expansion tank, which is located above the collective collectors of the upper cooling zone and is connected to the outlet main a pipeline, a heat exchanger, which is installed on the outlet main pipeline, a device for introducing water, which contains a pump and a valve installed in parallel, which are connected to the water source and the intake manifolds of the circulation pumps and are connected to the water level sensor in expansion tank, a device for creating increased gas pressure in the expansion tank. at 2. A system according to claim 1, characterized in that it contains four vertical cooling sections. 3. The system according to claim 1 or claim 2, which is characterized by the fact that the device for creating increased gas pressure contains a valve that is connected to the gas source and the expansion tank and is connected to the gas pressure sensor in the expansion tank via electro-automatic . IF) (Se) (Se) - - and? -i (o) (o) 1 Ko) ime) 60 b5