KR20130034526A - Sensible heat collecting apparatus of furnace slag - Google Patents

Abstract

PURPOSE: An apparatus for collecting the sensible heat of furnace slag is provided to sensitively measure the heat exchange efficiency of a heat exchanger by installing a temperature sensor inside a heat storage device. CONSTITUTION: An apparatus for collecting the sensible heat of furnace slag comprises a heat storage device(120), a heat exchanger(130), a medium supplying device(140), and a blower(150). The heat storage device is arranged inside a slag flowing duct(110). The medium supplying device is connected to the heat exchanger to supply heat exchange mediums to the heat exchanger. The blower is connected to the heat storage device so that air in the slag flowing duct can be drawn into the heat storage device to store the heat of the air.

Description

Sensible heat recovery device of blast furnace slag {SENSIBLE HEAT COLLECTING APPARATUS OF FURNACE SLAG}

The present invention relates to a sensible heat recovery apparatus of the blast furnace slag to recover the sensible heat from the blast furnace slag to save energy.

In general, blast furnace slag is generated in molten iron manufacturing processes. Blast furnace slag may be discharged separately from the molten iron when the molten iron is taken out from the blast furnace. The blast furnace slag can be cooled by air or cooling water. The heat of such blast furnace slag may be released to the outside without being recovered.

Republic of Korea Patent Publication No. 2011-0053833 (published May 24, 2011) discloses a method for producing blast furnace slag cement and blast furnace slag cement produced by the method. It crushes the blast furnace slag and mixes the various components to produce cement.

Embodiments of the present invention to provide a sensible heat recovery apparatus of blast furnace slag that can recover the heat of the blast furnace slag and recycle.

According to one aspect of the invention, the heat storage device accommodated in the interior of the slag flow duct; A heat exchanger installed to pass through the heat storage device and configured to be heated by the heat storage device while the heat exchange medium flows; A medium supply device connected to the heat exchanger and supplying a heat exchange medium to the heat exchanger; And a blower connected to the heat storage device, wherein the air of the slag flow duct is sucked into the heat storage device to accumulate the heat storage device.

The heat storage device may include a case through which the heat exchanger passes; And a heat storage medium that is accommodated in the case and heats the heat exchanger by accumulating heat generated from the blast furnace slag.

The lower surface of the case may be formed of a porous structure to allow air to pass through.

A turbulence forming layer may be further included between the heat exchanger and the heat storage medium.

The heat exchanger may be a pipe in which a portion passing through the heat storage device is zigzag bent.

The apparatus may further include a controller for controlling the medium supply device and the blower.

And a first temperature sensor installed in the slag flow duct, and the controller may control the blower according to the temperature measured by the first temperature sensor to adjust the flow rate of air passing through the heat storage device.

The apparatus may further include a second temperature sensor installed in the heat storage device, and the controller may control the flow rate of the medium supply device and the flow rate of the blower according to the temperature measured by the second temperature sensor.

According to embodiments of the present invention, there is an effect that can be recovered by recycling the heat of the blast furnace slag.

1 is a view showing an embodiment of the sensible heat recovery apparatus of the blast furnace slag according to the present invention.
FIG. 2 is a view illustrating a case of a heat storage device of the sensible heat recovery device of FIG. 1.
FIG. 3 is a view illustrating the interior of the heat storage device of FIG. 2.
4 is a diagram illustrating a configuration connected to a control unit.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. In the following description of the present invention, if it is determined that the detailed description of the related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

Hereinafter, an embodiment of the sensible heat recovery apparatus of the blast furnace slag according to the present invention will be described in detail.

In a molten iron manufacturing process, iron ore is put into a blast furnace, and coke is put, hot air is blown in by blowing, and the molten iron is manufactured by burning. In blast furnaces, molten iron and blast furnace slag may be discharged separately.

The molten iron may be discharged to Torpedo Ladle Car and then transferred to the steelmaking process. The blast furnace slag may be discharged to the slag flow duct 110 in a molten state. Blast furnace slag can be divided into aggregate slag and water slag by cooling method.

1 is a view showing an embodiment of the sensitized heat recovery device of the blast furnace slag according to the present invention, Figure 2 is a view showing a case of the heat storage device of the sensible heat recovery device, Figure 3 shows the interior of the heat storage device. 4 is a diagram illustrating a configuration connected to a control unit.

1 to 4, the sensible heat recovery apparatus 100 of the blast furnace slag may include a heat storage device 120, a heat exchanger 130, a medium supply device 140, and a blower 150.

Blast furnace slag discharged from the blast furnace may be discharged to the slag flow duct 110. Blast furnace slag may be discharged to the slag flow duct 110 at a temperature of about 1500 ℃. Blast furnace slag can ensure sufficient fluidity even if cooled to a temperature of about 1300 ℃.

The duct cover 111 may be disposed above the slag flow duct 110. The duct cover 111 may shield the outside air from flowing into the slag flow duct 110.

The slag flow duct 110 may be connected to the slag cooling or sprinkling plant. A slag flow path may be formed in the slag flow duct 110 to allow the blast furnace slag to flow in a molten state. The slag flow duct 110 may be formed in various forms. In addition, the slag flow duct 110 may be formed of a heat resistant material that is not melted by the temperature of the molten slag.

The heat storage device 120 may be received inside the slag flow duct 110. The heat storage device 120 may include a case 121 and a heat storage medium 125.

The heat exchanger 130 may pass through the case 121. The lower surface 121a of the case 121 may be formed in a porous structure through which air may be introduced, and the upper surface 121c and the side surface 121b of the case 121 may be formed as closed surfaces to prevent air from entering. . The discharge tube 123 may be formed on the upper surface 121c of the case 121 to discharge the air introduced into the case 121.

The heat storage medium 125 may be accommodated in the case 121 and heat the heat exchanger 130 by accumulating heat generated from the molten slag. The heat storage medium 125 may be formed in a spherical shape. The heat storage medium 125 having the same size may be accommodated in the case 121, or the heat storage medium 125 having a different size may be accommodated. A gap may be formed between the heat storage medium 125 to allow air to pass therethrough.

The turbulence forming layer 127 may be formed on the heat storage medium 125. The turbulence forming layer 127 may be formed by stacking turbulence forming members. The turbulence forming layer 127 may be disposed between the heat exchanger 130 and the heat storage medium 125.

The turbulence forming member may have a comb-toothed shape in which a plurality of combs are formed in a straight center body. The turbulence forming member may be applied in various forms as long as it causes turbulence. When the temperature of the heat storage medium 125 increases, the turbulence forming member may slightly spread the comb teeth, and when the temperature of the heat storage medium 125 decreases, the comb teeth may be slightly folded toward the center body.

The heat exchanger 130 may be installed to pass through the heat storage device 120. The heat exchange medium may be heated while the heat exchange medium flows inside the heat exchanger 130.

The heat exchanger 130 may be a pipe in which a portion passing through the heat storage device 120 is bent zigzag. The bent portion of the heat exchanger 130 may be formed on the same plane. The heat exchanger 130 may be disposed above the heat storage device 120. The heat exchanger 130 is zigzag to increase the heat exchange time and heat exchange area of the heat exchange medium.

The medium supply device 140 may be connected to one side of the heat exchanger 130 to supply a heat exchange medium to the heat exchanger 130. As the heat exchange medium, water or air may be applied. When the heat exchange medium is water, a pump may be applied to the medium supply device 140. When the heat exchange medium is air, a blower may be applied to the medium supply device 140.

The heat exchanger 130 may be supplied to a steam facility or a power generation facility through a pipe (not shown). Therefore, it is possible to contribute to energy reduction by producing a high temperature heating medium and utilizing it in a steam facility or a power generation facility.

The blower 150 may be connected to the discharge tube 123 of the heat storage device 120. The blower 150 may allow the air in the slag flow duct 110 to be sucked into the heat storage device 120 to heat the heat storage device 120. Air sucked into the blower 150 may be discharged to the outside of the slag flow duct 110 or re-introduced into the slag flow duct 110.

The controller 160 may be further included to control the media supply device 140 and the blower 150. The controller 160 may appropriately control the flow rate of the heat exchange medium or the air by adjusting the driving speeds of the medium supply device 140 and the blower 150.

The slag flow duct 110 may further include a first temperature sensor 171. Since the first temperature sensor 171 is disposed in the slag flow duct 110, the temperature of the blast furnace slag may be sensitively measured.

The first temperature sensor 171 measures the internal temperature of the slag flow duct 110. The signal related to the temperature measured by the first temperature sensor 171 may be transmitted to the controller 160.

The controller 160 may control the blower 150 according to the temperature measured by the first temperature sensor 171 to adjust the flow rate of air passing through the heat storage device 120.

For example, when the temperature measured by the first temperature sensor 171 is in the range of 1400 ≦ t ≦ 1500 ° C., the controller 160 rotates the blower 150 at a high speed to supply air to the heat storage device 120. The flow rate can be increased. This is because the slag fluidity of the slag flowing in the slag flow duct 110 is sufficiently high, even if a large amount of air is discharged from the slag flow duct 110.

In addition, when the temperature measured by the first temperature sensor 171 is in the range of 1300 <t <1400 ° C., the controller 160 rotates the blower 150 at a low speed to adjust the flow rate of the air supplied to the heat storage device 120. Can be reduced. This is to relatively reduce the temperature drop of the blast furnace slag because the temperature of the blast furnace slag flowing in the slag flow duct 110 is low.

In addition, when the temperature measured by the first temperature sensor is 1300 ° C. or less, the medium supply device 140 and the blower 150 may be stopped. This is to prevent the molten blast furnace slag from deteriorating the fluidity in the slag flow duct 110.

The second temperature sensor 175 may be further included in the heat storage device 120. Since the second temperature sensor 175 is disposed inside the heat storage device 120, the heat exchange efficiency of the heat exchanger 130 may be sensitively measured.

The controller 160 may control the flow rate of the medium supply device 140 and the flow rate of the blower 150 according to the temperature measured by the second temperature sensor 175.

For example, when the temperature measured by the second temperature sensor 175 is 1000 ° C. or more, the controller 160 may control the medium supply device 140 and the blower 150 to rotate at high speed to increase both flow rates. have. In this case, the blower 150 may increase the temperature of the heat storage device 120 by sucking hot air from the slag flow duct 110 to the heat storage device 120. When the temperature of the heat storage device 120 is increased, the heat exchange efficiency of the heat exchanger 130 may be increased. Therefore, even if the medium supply device 140 supplies a large amount of heat exchange medium to the heat exchanger 130, the heat exchange medium can be sufficiently heated.

In addition, when the temperature measured by the second temperature sensor 175 is less than 1000 ° C, the controller 160 may control the medium supply device 140 and the blower 150 to rotate at low speed to reduce both flow rates. In this case, the blower 150 may relatively reduce the temperature of the heat storage device 120 by relatively inhaling hot air from the slag flow duct 110 to the heat storage device 120. When the temperature of the heat storage device 120 is relatively reduced, the heat exchange efficiency of the heat exchanger 130 may also be reduced. Accordingly, the medium supply device 140 may supply a relatively small amount of heat exchange medium to the heat exchanger 130 to heat the heat exchange medium.

If the temperature measured by the second temperature sensor is 800 ° C. or less, the medium supply device 140 and the blower 140 may be stopped and the blower 140 may be continuously operated. This is to increase the temperature of the heat storage device 120.

In addition, when the temperature measured by the first temperature sensor is 1300 ° C. or less and the temperature measured by the second temperature sensor is 800 ° C. or less, both the medium supply device 140 and the blower 140 may be stopped.

The operation of the blast furnace slag sensible heat recovery device according to the present invention configured as described above will be described.

Blast furnace slag may be discharged from the blast furnace to the slag flow duct 110. The blast furnace slag may flow along the slag flow duct 110.

The controller 160 operates the blower 140 to suck hot air into the heat storage device 120. As the blower 140 operates, the heat storage device 120 may be heated to a high temperature by being continuously in thermal contact with the hot air. In this case, since the heat storage device 120 is heated by the hot air sucked by the blower 140, the heat storage device 120 may be thermally stored in a short time.

The first temperature sensor 171 measures the internal temperature of the slag flow duct 110, and the second temperature sensor 175 measures the temperature of the heat storage medium 125 accommodated in the heat storage device 120.

When the temperature measured by the second temperature sensor 175 is 800 ° C. or more, the controller 160 operates the medium supply device 140 to supply the heat exchange medium to the heat exchanger 130. The heat exchange medium may be discharged after being heated in the heat exchanger 130 and used in a steam facility or a power generation facility. When the temperature measured by the second temperature sensor 175 is maintained at 800 ° C. or higher (121 a), the heat exchange medium may be continuously supplied to the heat exchanger 130.

When the temperature measured by the first temperature sensor 171 is 1300 ° C. or less, since the blast furnace slag is difficult to secure fluidity, the blower 150 may be stopped. As the blower 150 is stopped, air of the slag flow duct 110 does not flow into the heat storage device 120. Therefore, since the temperature fall of the slag flow duct 110 is relatively delayed, the fluidity of the blast furnace slag can be prevented from deteriorating.

By recovering the sensible heat of the blast furnace slag as described above can be utilized where hot air or hot water, such as steam facilities or power generation equipment is required.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

110: slag flow duct 120: heat storage device
121: case 125: heat storage medium
127: turbulent forming layer 130: heat exchanger
140: medium supply device 150: blower
160: control unit 171: first temperature sensor
172: second temperature sensor

Claims (8)

A heat storage device received inside the slag flow duct;
A heat exchanger installed to pass through the heat storage device and configured to be heated by the heat storage device while the heat exchange medium flows;
A medium supply device connected to the heat exchanger and supplying a heat exchange medium to the heat exchanger; And
And a blower connected to the heat storage device, wherein the air in the slag flow duct is sucked into the heat storage device to accumulate the heat storage device.
The method of claim 1,
The heat storage device,
A case through which the heat exchanger passes; And
The sensation heat recovery apparatus of the blast furnace slag is accommodated in the case, and includes a heat storage medium for heating the heat exchanger by accumulating heat generated in the blast furnace slag.
The method of claim 2,
The lower surface of the case is a sensation heat recovery apparatus of the blast furnace slag, characterized in that formed in a porous structure so that air passes.
The method of claim 2,
Apparatus for sensible heat recovery of blast furnace slag further comprises a turbulent flow forming layer between the heat exchanger and the heat storage medium.
The method of claim 1,
The heat exchanger is a sensation heat recovery device for blast furnace slag, characterized in that the portion passing through the heat storage device is a pipe bent in a zigzag.
The method of claim 1,
A blast furnace slag sensible heat recovery device further comprising a control unit for controlling the medium supply device and the blower.
The method according to claim 6,
A first temperature sensor installed in the slag flow duct;
The controller controls the blower according to the temperature measured by the first temperature sensor to adjust the flow rate of the air passing through the heat storage device sensible heat recovery apparatus of the blast furnace slag.
The method according to claim 6,
Further comprising a second temperature sensor installed inside the heat storage device,
The controller controls the flow rate of the blast furnace slag and the flow rate of the blower in accordance with the temperature measured by the second temperature sensor.

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