JP2006274429A - Equipment for generating blast furnace overhead pressure recovery power - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide equipment for generating blast furnace overhead pressure recovery power capable of recovering a blast furnace overhead pressure as electrical energy without carelessly and emergently stopping a power generation gas turbine. <P>SOLUTION: Temperature detectors 17 for detecting the temperature in respective drainage pipes 14 are provided in the drainage pipes 14 placed between a drain tank 16 and orifices 15, and it is judged whether or not the orifices 15 tend to be stopped in accordance with the temperatures detected by the temperature detectors 17. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a blast furnace top pressure recovery power generation facility that recovers the top pressure of a blast furnace as electric energy.

  Since blast furnace gas (BFG; Blast Furnace Gas) discharged from the top of the blast furnace normally has a relatively high pressure of about 200 to 250 kPa, for example, FIG. A blast furnace top pressure recovery power generation facility as shown in FIG. 1 is installed in the steel works (see Patent Documents 1 to 3). In FIG. 3, reference numeral 10 denotes a blast furnace, 11 denotes a blast furnace gas inlet pipe having one end connected to the top of the blast furnace 10, and a power generation gas turbine 12 is connected to the other end of the blast furnace gas inlet pipe 11. Yes. Accordingly, the blast furnace gas discharged from the top of the blast furnace 10 is introduced into the power generation gas turbine 12 through the blast furnace gas inlet pipe 11, and the power generation gas turbine is placed in the middle of the blast furnace gas inlet pipe 11. A wet dust collector 13 is provided for removing dust in the blast furnace gas introduced into the blast furnace gas 12.

In such a blast furnace top pressure recovery power generation facility, when the blast furnace gas discharged from the top of the blast furnace 10 is introduced into the wet dust collector 13, a large amount of cleaning water for dust removal is formed as mist in the blast furnace gas. Mixed. When such blast furnace gas is introduced into the power generation gas turbine 12, mist in the gas becomes drainage and may accumulate in the turbine casing. Therefore, conventionally, drainage in the turbine casing is prevented by discharging the drain from the drainage pipes 14 (see FIG. 3) connected to each stage of the power generation gas turbine 12 to the outside of the power generation gas turbine 12. I am doing so. Further, in order to prevent the blast furnace gas introduced into the power generation gas turbine 12 from leaking into the atmosphere accompanying the drain, the flow rate of the drain is limited by the orifice 15 provided in the middle of the drain vent pipe 14. Yes. The drain discharged to the outside of the power generation gas turbine 12 through the drain pipe 14 is stored in a gas seal type drain tank 16.
JP-A-9-209909 Japanese Patent No. 2816923 JP-A-57-143408

The drain discharged from the power generation gas turbine 12 of such a blast furnace top pressure recovery power generation facility often contains dust such as iron and zinc that could not be removed by the wet dust collector 13. For this reason, when the drain containing such dust flows into the drain pipe 14, the dust in the drain accumulates with time on the upstream side (primary side) of the orifice 15, and the orifice 15 is blocked by the accumulated dust. May be. When the orifice 15 is in a closed state, the drain flow is completely blocked, so that the drain water level on the primary side rises. In this case, when the rise of the drain water level reaches the turbine blades, the turbine blades rotating at high speed are in the turbine state, and the turbine blades are significantly damaged. Therefore, the power generation gas turbine 12 is generated before the turbine blades are in the turbine state. An interlock that makes an emergency stop is activated. Therefore, in order to increase the power generation efficiency of the blast furnace top pressure recovery power generation facility, it is desirable to clean the drainage pipe before the orifice is completely closed. There was no way to detect whether the orifice had a tendency to close due to accumulated dust.
The present invention has been made in view of such circumstances, and a blast furnace top pressure recovery power generation facility capable of recovering the blast furnace top pressure as electric energy without inadvertently stopping the power generation gas turbine inadvertently. Is intended to provide.

  In order to achieve the above object, the present invention provides a blast furnace gas inlet pipe having one end connected to the top of a blast furnace, a power generation gas turbine connected to the other end of the blast furnace gas inlet pipe, and the blast furnace gas. A wet dust collector that removes dust in the blast furnace gas introduced into the power generation gas turbine from an inlet pipe in a front stage of the power generation gas turbine; and a plurality of drain extraction pipes that extract drain from the power generation gas turbine; In a blast furnace top pressure recovery power generation facility comprising a drain tank for storing drain from the drain pipe and an orifice provided in the middle of the drain pipe, the temperature in the drain pipe is detected A temperature detector is provided in the drain pipe between the drain tank and the orifice.

  According to the blast furnace top pressure recovery power generation facility according to the present invention, the temperature detector for detecting the temperature in the drain vent pipe is provided in the drain vent pipe between the drain tank and the orifice. It is possible to detect from the temperature detected by the temperature detector whether or not the orifice tends to be blocked by dust accumulated on the surface. This makes it possible to clean the drain pipe before the orifice is completely closed, such as when the blast furnace is shut down for a short time. The pressure can be recovered as electrical energy.

Hereinafter, an embodiment of the present invention will be described with reference to FIG. 1 and FIG. 2, but the same parts as those shown in FIG. 3 are denoted by the same reference numerals, and detailed description thereof will be omitted.
FIG. 1 is a diagram showing a schematic configuration of a blast furnace top pressure recovery power generation facility according to an embodiment of the present invention. As shown in the figure, a secondary side drain removal between a drain tank 16 and an orifice 15 is shown. The pipe 14 is provided with a temperature detector 17 that detects the temperature in the drain pipe 14. As shown in FIG. 2, the temperature detector 17 has a rod-shaped temperature detector 17 a, and the temperature detector 17 a is inserted into the drain pipe 14 from the through hole 18 formed in the drain pipe 14. Has been inserted. The temperature detector 17 has a temperature display unit 17b (see FIG. 2), and the temperature detected by the temperature detection unit 17a is displayed on the temperature display unit 17b.

  As described above, when the temperature detector 17 for detecting the temperature in the drain pipe 14 is provided in the drain pipe 14 between the drain tank 16 and the orifice 15, the orifice 15 is caused by dust accumulated in the drain pipe 14. Can be detected from the temperature detected by the temperature detector 17. That is, since the temperature of the blast furnace gas introduced into the power generation gas turbine 12 is generally about 65 ° C., the temperature in the drain drain pipe 14 on the primary side between the power generation gas turbine 12 and the orifice 15 is the same. Although the temperature is reached, it is known from operating experience that when the orifice 15 is closed, the secondary side of the orifice 15 blocks the flow of drain, so that the temperature decreases to near the atmospheric temperature. Therefore, in the above-described embodiment, it can be detected from the temperature detected by the temperature detector 17 whether or not the orifice 15 has a tendency to be blocked, so that the drain 15 is drained before the orifice 15 is completely closed. Since the cleaning operation of the extraction pipe 14 can be performed when the blast furnace 10 is stopped for a short time, the blast furnace top pressure can be recovered as electric energy without causing the power generation gas turbine 12 to stop urgently.

  As a result of testing with a power generation gas turbine having three drainage pipes (diameter 100A), the temperature indication value of the temperature detector provided in the first drainage pipe is 65 ° C., and the second drainage pipe. The temperature indication value of the temperature detector provided in the temperature detector was 55 ° C., and the temperature indication value of the temperature detector provided in the third drainage pipe was 45 ° C. As a result of measuring the temperature in the drain drain pipe again after two months have passed, only the temperature in the first drain drain pipe decreases to 5 ° C, and the second and third drain drains. There was no temporal change in the temperature in the pipe. As a result, it was possible to recognize that the drainage pipe at the first stage had a tendency to block.

  The present invention is not limited to the embodiment described above. For example, in the above-described embodiment, the operation monitor observes the indication value of the temperature detector 17 to recognize whether or not the orifice 15 tends to be blocked. However, the temperature in the drain pipe is detected. As a means, a temperature detector such as a thermistor may be used, and the output of the temperature detector may be input to an operation control device (not shown) so as to recognize whether or not the orifice 15 has a tendency to close. .

It is a figure which shows schematic structure of the blast furnace top pressure recovery power generation equipment which concerns on one Embodiment of this invention. It is a figure which shows schematic structure of the temperature detector shown in FIG. It is a figure which shows schematic structure of the conventional blast furnace top pressure recovery power generation equipment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Blast furnace 11 Blast furnace gas inlet pipe 12 Power generation gas turbine 13 Wet dust collector 14 Drain drain pipe 15 Orifice 16 Drain tank 17 Temperature detector

Claims (1)

A blast furnace gas inlet pipe connected at one end to the furnace top of the blast furnace, a power generation gas turbine connected to the other end of the blast furnace gas inlet pipe, and a blast furnace introduced into the power generation gas turbine from the blast furnace gas inlet pipe A wet dust collector that removes dust in the gas at the front stage of the power generation gas turbine, a plurality of drain extraction pipes for extracting drain from the power generation gas turbine, and a drain tank for storing drain from the drain extraction pipe And a blast furnace top pressure recovery power generation facility comprising an orifice provided in the middle of the drain pipe,
A blast furnace top pressure recovery power generation facility characterized in that a temperature detector for detecting the temperature in the drain pipe is provided in the drain pipe between the drain tank and the orifice.

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