KR20160073977A - Hot blast furnace facility - Google Patents

Abstract

The hot air furnace system is a hot air furnace; A combustion air pipe for sending combustion air to the hot air path; A fuel gas pipe for sending the blast furnace gas discharged from the blast furnace to a hot air furnace as a fuel gas in a hot air furnace; A flue pipe for discharging the exhaust gas from the hot wind path to the chimney; First preheating means connected to the flue tube for preheating one of the combustion air and the fuel gas by the heat recovered from the exhaust gas of the hot air passage through heat exchange; And a second preheater having a first heater for burning a part of the blast furnace gas and preheating the other of the combustion air and the fuel gas by heat generated in the first heater.

Description

{HOT BLAST FURNACE FACILITY}

The present invention relates to a hot air furnace for heating air to be sent to a furnace.

BACKGROUND ART [0002] There is known a hot air furnace facility for heating air (blast furnace air) which is conventionally sent to a blast furnace (see, for example, Patent Document 1). In the facility described in Patent Document 1, the blast furnace air is stepped up by a blower and sent to the hot air furnace, and is sent to the blast furnace through the hot air furnace. A heat exchanger is connected to the pipe connecting the blower and the hot air passage. In this heat exchanger, heat is recovered from the air whose temperature has risen due to the pressure increase by the blower. Further, the exhaust gas discharged from the hot air furnace is sent to the chimney. Other heat exchangers are connected to the piping connecting the chimney and the hot wind path. In this heat exchanger, heat is recovered from the exhaust gas of the hot air path. In the facility described in Patent Document 1, the fuel gas and the combustion air supplied to the hot air path by the heat recovered in the heat exchanger described above are preheated.

Japanese Patent Application Laid-Open No. 9-287013

In the above-described hot-air furnace facility, the blast furnace gas (BFG) discharged from the blast furnace may be supplied as the fuel gas to the hot-air furnace. Since the amount of heat of the blast furnace gas is relatively low, other fuels (for example, liquefied petroleum gas (LPG), coke oven gas (COG), etc.) are added to the blast furnace gas when the amount of heat is insufficient . Since the liquefied petroleum gas is relatively expensive and the coke oven gas is also used in other facilities, it is preferable that the amount of other fuels added to the blast furnace gas is small.

In the facility described in Patent Document 1, since the fuel gas and the combustion air are preheated by the heat recovered in the heat exchanger described above, the addition amount of the other fuel can be reduced, but it is required to develop a technology capable of further reducing the addition amount .

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and it is an object of the present invention to provide a hot air furnace facility capable of reducing the amount of other fuel added to blast furnace gas.

A hot air furnace apparatus according to one aspect of the present invention is a hot air furnace apparatus for heating furnace air, comprising: a hot air furnace for heating the furnace air; A combustion air pipe for sending combustion air to the hot air path; A fuel gas pipe for sending the blast furnace gas discharged from the blast furnace to a hot air furnace as a fuel gas in a hot air furnace; A flue pipe (flue pipe) for sending the exhaust gas discharged from the hot wind path to the chimney; First preheating means connected to the flue tube and connected to one of the combustion air pipe and the fuel gas pipe and preheating one of the combustion air and the blast furnace gas by the heat recovered from the exhaust gas of the hot air furnace through heat exchange; And a second heater connected to the other one of the combustion air pipe and the fuel gas pipe for burning a part of the blast furnace gas and for heating the other of the combustion air and the blast furnace gas by heat generated in the first heater, And a preheating means.

In one aspect of the present invention, one of the combustion air and the blast furnace gas is preheated by the heat recovered from the exhaust gas of the hot air furnace, and the other of the combustion air and the blast furnace gas burns a part of the blast furnace gas And is preheated by the heat of combustion generated. When the combustion heat generated by burning the blast furnace gas is used, it becomes possible to heat the combustion air or the blast furnace gas to a relatively high temperature. Therefore, the amount of other fuel added to the blast furnace gas can be reduced.

The first preheating means comprises: a first heat exchanger connected to the flue tube; A second heat exchanger connected to one pipe; A heat pipe for connecting the first heat exchanger and the second heat exchanger and sending the heat medium in the liquid state recovered from the first heat exchanger to the second heat exchanger; And a second heater connected to the heat pipe and heating the heat medium in a liquid state by heat generated by burning a part of the blast furnace gas. In this case, one of the combustion air and the blast furnace gas is heated by the heat generated by burning a part of the blast furnace gas, in addition to the heat recovered from the exhaust gas of the hot blast furnace. As described above, by using the combustion heat generated by burning the blast furnace gas, it is possible to heat the combustion air or the fuel gas to a relatively high temperature, so that the amount of other fuel added to the blast furnace gas can be reduced.

The first preheating means includes a high temperature section connected to the flue tube; And a low temperature section connected to one pipe, and a heat pipe type heat exchanger that sends the medium evaporated in the high temperature section to the low temperature section and conveys the medium condensed in the low temperature section to the high temperature section. In the case of using the heat pipe type heat exchanger, the piping or the like for sending the heat medium is unnecessary compared with the case where heat exchange is performed by circulating the heat medium in a liquid state, so that facilities can be simplified.

The second preheating means includes a third heat exchanger connected to the other tube; And a heating gas pipe connecting the first heater and the third heat exchanger and sending a gas generated by burning a part of the blast furnace gas in the first heater to the third heat exchanger. According to this configuration, heat exchange between the gas generated in the first heater and the combustion air or the blast furnace gas can be performed in the third heat exchanger. In this case, it becomes possible to preheat the combustion air or the blast furnace gas to a higher temperature, as compared with, for example, a case where a heat medium such as petroleum hydrocarbon is used for heat exchange.

According to the present invention, it is possible to provide a hot air furnace facility capable of reducing the amount of other fuel added to the blast furnace gas.

Fig. 1 is a configuration diagram showing a hot air furnace facility according to the first embodiment. Fig.
2 is a configuration diagram showing a hot air furnace facility according to the second embodiment.
3 is a configuration diagram showing a hot air furnace facility according to the third embodiment.
4 is a configuration diagram showing a hot air furnace facility according to the fourth embodiment.
5 is a configuration diagram showing a hot air furnace facility according to the fifth embodiment.
6 is a configuration diagram showing a hot air furnace facility according to a comparative example.

Hereinafter, embodiments will be described in detail with reference to the drawings. In the description, the same or similar elements are denoted by the same reference numerals, and redundant explanations are omitted.

[First Embodiment]

Fig. 1 is a configuration diagram showing a hot air furnace facility according to the first embodiment. Fig. The hot air furnace installation 1A heats the air (blast furnace air) sent to the blast furnace (not shown). The hot air furnace facility 1A includes a plurality of (three in this case) hot air furnaces 2, a combustion air pipe 3, a fuel gas pipe 4, a flue pipe 5, a first preheating means 6A, (7A) and an air duct (8) for blast furnace.

The hot air path (2) heats the blast furnace air. The hot air path 2 has a combustion chamber 21, a heat storage chamber 22, and a communication pipe (communication pipe) 23. The combustion chamber 21 burns the fuel gas. The combustion chamber (21) is connected to the combustion air pipe (3) and the fuel gas pipe (4). The heat storage chamber (22) recovers heat from exhaust gas generated in the combustion chamber (21) and stores heat. The regenerator 22 communicates with the combustion chamber 21 through the communication pipe 23 and the exhaust gas generated in the combustion chamber 21 is introduced from the communication pipe 23. The hot air path (2) is provided with a pipe (24) for sending air for blast furnace to the blast furnace. The combustion temperature in the hot air path 2 is, for example, about 1450 占 폚.

The combustion air pipe (3) sends combustion air to each hot air path (2). The combustion air pipe (3) is connected to a combustion air blower (31) for blowing combustion air. The combustion air pipes 3 are branched into a plurality (here, three) in accordance with the number of the hot air paths 2. Each branched portion of the combustion air pipe 3 is connected to the combustion chamber 21 and sends the air blown out from the combustion air blower 31 to the combustion chamber 21 as combustion air. A valve V is provided at each branched portion of the combustion air pipe 3. The temperature of the combustion air to be introduced into the combustion air pipe 3 from the combustion air blower 31 (the temperature of the combustion air before the preheating) varies depending on, for example, the zone and is about 10 to 50 ° C.

The fuel gas pipe 4 sends the blast furnace gas (BFG) discharged from the blast furnace to each hot air furnace 2 as fuel gas. The fuel gas pipe 4 is connected to the blast furnace. The fuel gas pipes 4 are branched into a plurality (here, three) in accordance with the number of the hot air paths 2. Each branched portion of the fuel gas pipe 4 is connected to the combustion chamber 21, and sends the blast furnace gas to the combustion chamber 21. A valve V is provided at each branched portion of the fuel gas pipe 4.

The calorific value of the blast furnace gas is, for example, about 2.93 to 3.56 MJ / m ³ . The temperature of the blast furnace gas introduced into the fuel gas pipe 4 from the blast furnace (the temperature of the blast furnace gas before the preheating) is, for example, about 10 to 50 占 폚. Further, in the present invention, the heat quantity is a high heat quantity.

The flue pipe (5) sends the exhaust gas discharged from the hot air path (2) to the chimney (9). The flue pipe (5) is connected to the chimney (9). The flue tube 5 is branched into a plurality of (three in this case) according to the number of the hot air paths 2 and is connected to each of the heat accumulating chambers 22. A valve V is provided in each of the branched portions of the flue tube 5.

The first preheating means 6A preheats the combustion air by the heat recovered from the exhaust gas of the hot air path 2 through heat exchange. The first preheating means 6A has a first heat exchanger 61, a heat pipe 62, a second heat exchanger 63 and a pump 64. [

The first heat exchanger (61) is connected to the flue pipe (5). The second heat exchanger (63) is connected to the combustion air pipe (3). The heat pipe 62 connects the first heat exchanger 61 and the second heat exchanger 63 and is connected between the first heat exchanger 61 and the second heat exchanger 63 in the form of a liquid heating medium , Petroleum hydrocarbons, etc.). The heat pipe 62 has a forward flow heat pipe 62a for sending the heat medium from the first heat exchanger 61 to the second heat exchanger 63 and a heat transfer pipe 62b for passing the heat medium from the second heat exchanger 63 to the first heat exchanger 63. [ And a returning heat pipe 62b for sending the heat to the heat exchanger 61. The pump 64 presses the heating medium. The pump 64 is connected to the backward heat pipe 62b.

A valve V is provided between the first heat exchanger 61 and the second heat exchanger 63 in the royal heat pipe 62a. A plurality of valves (V, V) are provided in the backward heat pipe (62b) between the first heat exchanger (61) and the pump (64). A plurality of valves V and V are provided between the pump 64 and the second heat exchanger 63 in the backward heat pipe 62b.

In the first heat exchanger (61), heat exchange is performed between the discharge gas of the hot air path (2) flowing through the flue (5) and the heat medium flowing through the heat pipe (62). Thus, the heat of the exhaust gas of the hot air path 2 flowing through the flue tube 5 is recovered by the heat medium flowing through the heat pipe 62. Heat exchange is performed between the heat medium flowing through the heat pipe 62 and the combustion air flowing through the combustion air pipe 3 in the second heat exchanger 63 so that the heat of the heat medium flowing through the heat pipe 62 The combustion air flowing through the combustion air pipe 3 is preheated.

The second preheating means 7A preheats the blast furnace gas by heat (combustion heat) generated by burning a part of the blast furnace gas. The second preheating means 7A includes a fuel gas branch pipe 71, a burner (first heater) 72, a burner air pipe 73, a burner air blower 74, a heating gas pipe 75, Lt; / RTI >

The fuel gas branch pipe (71) is a pipe branched from the fuel gas pipe (4). The fuel gas branch pipe 71 is connected to the burner 72. The fuel gas branch pipe (71) sends part of the blast furnace gas flowing through the fuel gas pipe (4) to the burner (72). The fuel gas branch pipe (71) is provided with a flow rate adjusting damper (D). The burner 72 burns the blast furnace gas sent from the fuel gas branch pipe 71.

The burner air pipe 73 connects the burner 72 and the air blower 74 for burner. The blower air blower 74 blows air for combustion from the burner 72. The air pipe 73 for burner sends the air blown out from the air blower 74 for burner to the burner 72. A flow rate control damper (D) is provided in the burner air pipe (73). The heating gas pipe (75) connects the burner (72) and the third heat exchanger (76). Thus, the heating gas pipe 75 sends the exhaust gas generated by burning the blast furnace gas in the burner 72 to the third heat exchanger 76.

The third heat exchanger (76) is connected to the fuel gas pipe (4). The third heat exchanger (76) performs heat exchange between the exhaust gas of the burner (72) and the blast furnace gas flowing through the fuel gas pipe (4). The blast furnace gas flowing through the fuel gas pipe 4 is preheated by the heat of the exhaust gas of the burner 72 (combustion heat generated by burning a part of the blast furnace gas). The third heat exchanger 76 is connected to the chimney 10 and the exhaust gas of the burner 72 used for heat exchange is sent to the chimney 10.

The blast furnace air pipe (8) sends the blast furnace air to the hot wind furnace (2). The blast furnace air pipe (8) is connected to the blast furnace air blower (81). The blast furnace air pipes 8 are branched into a plurality (here, three) in accordance with the number of the hot air furnaces 2, and are connected to the respective heat accumulating chambers 22. A valve (V) is installed at each branched portion of the blast furnace air pipe (8). The blast furnace air pipe 8 sends the air blown out from the blast furnace air blower 81 to each of the heat storage rooms 22 as blast furnace air.

In the hot air furnace 1A as described above, for example, the heat is accumulated in the hot air path 2 of a part (for example, two) of the plurality of hot air paths 2, The blast furnace air is heated in the hot blast furnace 2 at a predetermined temperature.

Specifically, in the hot air furnace 2 in which heat is accumulated, combustion air is introduced into the combustion chamber 21 from the combustion air pipe 3, and the blast furnace gas is introduced from the fuel gas pipe 4 to burn the blast furnace gas. The exhaust gas generated in the combustion chamber 21 is introduced into the regenerator 22 through the communication pipe 23 so that the heat of the exhaust gas is recovered by the regenerator 22. The exhaust gas that has passed through the heat storage chamber 22 is sent to the chimney 9 through the flue pipe 5.

At this time, in the first preheating means 6A, heat exchange is performed between the exhaust gas of the hot air path 2 and the heat medium in the first heat exchanger 61. [ As a result, the heat of the exhaust gas of the hot air path 2 is recovered. Heat exchange is performed between the heating medium and the combustion air in the second heat exchanger (63). Thereby, the combustion air is preheated. Then, preheated combustion air is introduced into the combustion chamber 21.

Further, in the second preheating means 7A, the blast furnace gas sent from the fuel gas branch pipe 71 in the burner 72 is burned. The third heat exchanger 76 performs heat exchange between the exhaust gas of the burner 72 and the blast furnace gas. Thus, the blast furnace gas is preheated. Then, the preheated blast furnace gas is introduced into the combustion chamber 21.

For example, when the amount of heat of the blast furnace gas is about 3.56 MJ / m ³ , it is not necessary to add another fuel to the blast furnace gas if the combustion air is preheated to 70 ° C or higher and the blast furnace gas to 70 ° C or higher. That is, the hot air furnace can be operated only by the combustion of BFG (BFG full combustion). Further, for example, when the amount of heat of the blast furnace gas is about 2.93 MJ / m ³ , if the combustion air is preheated to 355 ° C or higher and the blast furnace gas to 355 ° C or more, no additional fuel is added to the blast furnace gas. In this way, it is considered to carry out the optimum design according to the calorific value of the blast furnace gas.

In the hot air path (2) where the blast furnace air is heated, the blast furnace air is introduced from the blast furnace air pipe (8) into the heat storage chamber (22). The blast furnace air heated by the heat accumulated in the heat storage chamber 22 is sent from the pipe 24 to the blast furnace. When the heat accumulation amount of the hot air path 2 in which the blast furnace air is heated is reduced to a predetermined value or less, the hot air path 2 for heating the blast furnace air and the hot air path 2 for heat accumulating are switched do.

As described above, in the hot air furnace 1A of the present embodiment, the combustion air is preheated by the heat recovered from the exhaust gas of the hot air path 2, and the combustion heat of the blast furnace gas do. When the combustion heat generated by burning the blast furnace gas is used, the blast furnace gas can be heated to a relatively high temperature. Therefore, the amount of other fuel added to the blast furnace gas can be reduced. That is, the consumption amount of the fuel different from the blast furnace gas can be reduced.

Here, the heating medium of the first preheating means 6A is, for example, petroleum hydrocarbon as described above, and if it is heated too much, the heating medium may change and viscosity or the like may change. Therefore, it is preferable that the heating medium of the first pre-heating means 6A is used at a predetermined temperature or lower. Therefore, for example, in the case of the preheating means for preheating both the combustion air and the blast furnace gas, the combustion air and the blast furnace gas can only be preheated to relatively low temperatures.

On the other hand, the present embodiment includes a first preheating means 6A for preheating combustion air and a second preheating means 7A for preheating the blast furnace gas. The second preheating means 7A connects the third heat exchanger 76 connected to the fuel gas pipe 4 and the burner 72 to the third heat exchanger 76 and supplies a part of the blast furnace gas And a heating gas pipe (75) for sending the generated gas to the third heat exchanger (76). The second preheating means 7A of the present embodiment preheats the blast furnace gas by performing heat exchange between the exhaust gas generated in the burner 72 and the blast furnace gas without using a heating medium such as petroleum hydrocarbon. Therefore, the blast furnace gas can be preheated to a higher temperature compared with the case of using a heating medium such as petroleum hydrocarbon.

[Second Embodiment]

The hot air furnace installation of the second embodiment will be described. 2 is a configuration diagram showing a hot air furnace facility according to the second embodiment. The hot air furnace installation 1B according to the present embodiment is different from the hot air furnace installation 1A according to the first embodiment (see Fig. 1) in that, in the first preheating means 6B, the blast furnace gas is preheated And that the combustion air is preheated instead of the blast furnace gas in the second preheating means 7B.

Specifically, in the hot air furnace installation 1B, the second heat exchanger 63 of the first pre-heating unit 6B is connected to the fuel gas pipe 4 instead of the combustion air pipe 3. The third heat exchanger 76 of the second preheating means 7B is connected to the combustion air pipe 3 instead of the fuel gas pipe 4.

In the hot air furnace installation 1B, heat exchange is performed between the heating medium and the blast furnace gas in the second heat exchanger 63 of the first preheating means 6B, whereby the blast furnace gas is preheated. In the third heat exchanger (76) of the second preheating means (7B), heat exchange is performed between the exhaust gas generated in the burner (72) and the combustion air, so that the combustion air is preheated.

In the hot air furnace installation 1B of this embodiment, the blast furnace gas is preheated by the heat recovered from the exhaust gas of the hot air furnace 2. [ Further, the combustion air is preheated by the combustion heat generated by burning a part of the blast furnace gas. When the combustion heat generated by burning the blast furnace gas is used, the combustion air can be heated to a relatively high temperature. Therefore, the amount of other fuel added to the blast furnace gas can be reduced. That is, the consumption amount of the fuel different from the blast furnace gas can be reduced.

The second preheating means 7B does not use a heating medium such as petroleum hydrocarbon but performs heat exchange between the exhaust gas of the burner 72 and the combustion air to preheat the combustion air. Therefore, the combustion air can be preheated to a high temperature as compared with the case of using a heating medium such as petroleum hydrocarbon.

[Third embodiment]

The hot air furnace installation of the third embodiment will be described. 3 is a configuration diagram showing a hot air furnace facility according to the third embodiment. The hot air furnace installation 1C according to the present embodiment differs from the hot air furnace installation 1A according to the first embodiment (see Fig. 1) in that the first preheating means 6C has a second heater 65 Is the point.

Specifically, the second heater 65 heats the heating medium by the combustion heat generated by burning a part of the blast furnace gas. The second heater 65 is connected to the royal furnace tube 62a. The second heater 65 includes a burner 65a and a heat exchange portion 65b.

In the burner 65a, a part of the blast furnace gas and combustion air are introduced to burn the blast furnace gas. In the heat exchanging section 65b, heat is exchanged between the gas heated by the burner 65a and the heat medium sent from the first heat exchanger 61. [ In this manner, the heat medium is heated by the heat of the gas heated by the burner 65a. The heated heat medium is sent to the second heat exchanger (63).

A pump 66 may be connected to the upstream portion of the second heater 65 in the royal furnace tube 62a.

The hot air furnace facility 1C of the present embodiment has the same effect as the hot air furnace facility 1A of the first embodiment. In addition, in the hot air furnace facility 1C, the combustion air is heated by the combustion heat generated by burning a part of the blast furnace gas in addition to the heat recovered from the exhaust gas of the hot air furnace 2. [ Therefore, the combustion air can be heated to a relatively high temperature, and the amount of other fuel added to the blast furnace gas can be reduced. That is, the consumption amount of the fuel different from the blast furnace gas can be reduced.

[Fourth Embodiment]

The hot air furnace installation of the fourth embodiment will be described. 4 is a configuration diagram showing a hot air furnace facility according to the fourth embodiment. The hot air furnace installation 1D according to the present embodiment differs from the hot air furnace installation 1B according to the second embodiment in that the first preheating means 6D has a second heater 65 Is the point. The configuration of the second heater 65 is the same as that of the third embodiment (see Fig. 3).

The hot air furnace installation 1D of the present embodiment has the same effect as the hot air furnace installation 1B of the second embodiment. Further, in the hot air furnace installation 1D, the blast furnace gas is heated by the combustion heat generated by burning a part of the blast furnace gas, in addition to the heat recovered from the exhaust gas of the hot blast furnace 2. Therefore, the blast furnace gas can be heated to a relatively high temperature, and the amount of other fuels added to the blast furnace gas can be reduced. That is, the consumption amount of the fuel different from the blast furnace gas can be reduced.

[Fifth Embodiment]

The hot air furnace installation of the fifth embodiment will be described. 5 is a configuration diagram showing a hot air furnace facility according to the fifth embodiment. The hot air furnace installation 1E according to the present embodiment is different from the hot air furnace installation 1A according to the first embodiment (see Fig. 1) in that the first preheating means 6E is a heat pipe type heat exchanger .

Specifically, the first preheating means 6E has a high temperature portion 67 and a low temperature portion 68. [ The high temperature part (67) is connected to the flue pipe (5). The low temperature section (68) is connected to the combustion air pipe (3). A medium having volatility circulates between the high temperature section (67) and the low temperature section (68).

In the high temperature section 67, heat exchange occurs between the exhaust gas of the hot air path 2 and the liquid medium, and the medium is evaporated by the heat of the exhaust gas of the hot air path 2. The vaporized medium is sent to the low temperature part (68). In the low temperature section (68), heat exchange is performed between the gaseous medium and the combustion air, and the combustion air is preheated by the heat of the gaseous medium. The heat-deprived medium is condensed and sent to the high temperature part (67).

In the hot air furnace installation 1E of this embodiment, the combustion air is preheated by the heat recovered from the exhaust gas of the hot air path 2, and the blast furnace gas is preheated by the combustion heat generated by burning a part of the blast furnace gas. Therefore, the blast furnace gas is heated to a relatively high temperature, so that the amount of other fuels added to the blast furnace gas can be reduced.

The first preheating means 6E has a high temperature portion 67 provided in the flue tube 5 and a low temperature portion 68 provided in the combustion air pipe 3 and is configured to send the medium evaporated in the high temperature portion 67 to the low temperature portion 68 And at the same time, the medium condensed in the low temperature section (68) is sent to the high temperature section (67). In the first preheating means 6E, piping or the like for sending the heating medium is unnecessary as compared with the case where heat exchange is performed by circulating the heating medium in the liquid state, so that the facility can be simplified.

Although the embodiments have been described above, the present invention is not necessarily limited to the above-described embodiments, and various modifications are possible without departing from the gist of the invention.

The constitution, the number and the material of each element are not limited to the constitution, the number and the material in the above embodiment, and can be suitably changed.

[Example]

Hereinafter, the present invention will be described in detail with reference to Examples and Comparative Examples, but the present invention is not limited to the following Examples.

[Evaluation Calculation]

For the hot air furnace installations 1A to 1D of Figs. 1 to 4, various temperatures were calculated based on preconditions similar to actual operation data (Examples 1 to 4). Further, various temperatures were calculated for the hot air furnace 100 according to the comparative example of Fig. 6 (comparative example).

As shown in FIG. 6, the hot air furnace 100 according to the comparative example does not have the preheating means (the second preheating means, the second heater) using the combustion of the blast furnace gas. In the hot air furnace facility 100, a fourth heat exchanger 69 of the first preheating means 60 is provided in the fuel gas pipe 4. The fourth heat exchanger 69 is connected to a tube branched from the royal furnace tube 62a and a tube branched from the backward heat tube 62b. In the hot air furnace facility 100, both the combustion air and the blast furnace gas are preheated by the first preheating means 60.

In each example, the precondition is as follows. In the comparative example, since the required combustion temperature could not be obtained in the hot air furnace only with the blast furnace gas, coke oven gas (COG) was added to the blast furnace gas (to be described in detail later). Table 1 shows the calculation results.

Example Temperature of combustion air: 20 ℃

Example Temperature of blast furnace gas: 40 ℃

Combustion temperature in hot air furnace: 1450 ℃

Temperature of the exhaust gas in the hot air passage before passing through the first heat exchanger: 250 DEG C

Temperature after passing through the first heat exchanger of the exhaust gas of the hot air furnace: 150 DEG C

Temperature of the heating medium of the first preheating unit before passing through the first heat exchanger: 100 DEG C

Temperature after passing through the first heat exchanger of the heating medium of the first preheating means: 200 DEG C

Temperature after passing through the second heater of the heating medium of the first preheating means: 300 占 폚 (Examples 3 and 4 only)

Calorific value of blast furnace gas: 2.96 MJ / m ³

Calorific value of coke oven gas: 16.72 MJ / m ³ (Comparative example only)

Comparative Example Example 1
(Fig. 1) Example 2
(Fig. 2) Example 3
(Fig. 3) Example 4
(Figure 4) After preheating
Temperature of combustion air (℃)
125
200
560
250
480 After preheating
Temperature of blast furnace gas (℃)
125
410
200
385
250 COG Addition Rate (%) 8.0 - - - -

As shown in Table 1, in Examples 1 to 4, at least one of the combustion air and the blast furnace gas was preheated by the combustion heat generated by burning a part of the blast furnace gas, Both the combustion air and the blast furnace gas could be preheated to a higher temperature than the example.

As described above, the heating medium of the first preheating means is, for example, petroleum hydrocarbon, and if it is heated too much, the heating medium may change and viscosity or the like may change. Therefore, the heating medium of the first preheating means was used at 300 DEG C or lower. Therefore, in the comparative example in which both the combustion air and the blast furnace gas are preheated by the first preheating means, the temperatures of both the combustion air and the blast furnace gas after the preheating are lower than those of Examples 1 to 4. Therefore, in the comparative example, it was necessary to add a coke oven gas having a heat amount higher than that of the blast furnace gas to the blast furnace gas in order to obtain the required combustion temperature (1450 ° C) in the hot wind furnace.

According to the present invention, it is possible to provide a hot air furnace facility capable of reducing the amount of other fuel added to the blast furnace gas.

1A ~ 1E: Hot air furnace facility
2: Hot air furnace
3: Air pipe for combustion
4: Fuel gas pipe
5: year tube
6A to 6E: a first preheating means
7A, 7B: a second preheating means
9: Chimney
61: first heat exchanger
62: fruit tube
63: second heat exchanger
65: second heater
67:
68: low temperature part
72: Burner (first heater)
75: Heated gas pipe
76: Third heat exchanger

Claims (4)

In a hot air furnace system for heating furnace air,
A hot air path for heating the blast furnace air;
A combustion air pipe for sending combustion air to the hot air passage;
A fuel gas pipe for sending the blast furnace gas discharged from the blast furnace to the hot air furnace as fuel gas of the hot blast furnace;
A flue pipe (flue pipe) for sending exhaust gas discharged from the hot air path to a chimney;
And one of the combustion air pipe and the fuel gas pipe is connected to the flue pipe and is connected to one of the combustion air pipe and the fuel gas pipe and is preheated by the heat recovered from the exhaust gas of the hot air path through heat exchange A first preheating means; And
And a first heater for burning a part of the blast furnace gas and connected to the other one of the combustion air duct and the fuel gas duct so that the combustion air and the other one of the blast furnace gas And a second preheating unit for preheating the heated air. The method according to claim 1,
Wherein the first preheating means comprises:
A first heat exchanger connected to the flue tube;
A second heat exchanger connected to the one pipe;
A heat pipe for connecting the first heat exchanger and the second heat exchanger and sending a heat medium in a liquid state recovered from the first heat exchanger to the second heat exchanger; And
And a second heater connected to the heat pipe and heating the heating medium in the liquid state by heat generated by burning a part of the blast furnace gas. The method according to claim 1,
The first preheating unit may include a heat pipe having a high temperature part connected to the flue pipe and a low temperature part connected to the one pipe and sending the medium evaporated in the high temperature part to the low temperature part, Heat exchanger, hot air furnace facility. 4. The method according to any one of claims 1 to 3,
Wherein the second preheating means comprises:
A third heat exchanger connected to the other pipe; And
And a heating gas pipe connected to the first heat exchanger and the third heat exchanger, for sending a gas generated by burning a part of the blast furnace gas in the first heater to the third heat exchanger.

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