JP2023006603A - Combustion facility and control method for the same - Google Patents

Abstract

To provide a combustion facility capable of stably controlling combustion in a heating furnace and a furnace interior pressure.SOLUTION: A combustion facility 1 includes: a heating furnace 2 for burning a fuel gas supplied from a fuel supply passage 22 by using air supplied from an air supply passage 21; a flue 5 for discharging a combustion exhaust gas generated through the combustion in the heating furnace 2 to outside of the heating furnace 2; a smokestack 6 connected to the flue 5; an outside air communication passage 23 branched from the air supply passage 21 and communicated with outside air; and a bypass passage 24 branched from the outside air communication passage 23 and communicated with the flue 5 or a bottom part 7 of the smokestack 6. Excess air that has not been used for combustion in the heating furnace 2 is supplied to the flue 5 or the bottom part 7 of the smokestack 6 through the bypass passage 24.SELECTED DRAWING: Figure 1

Description

The present invention relates to combustion equipment and its control method.

Patent Literature 1 discloses a heating furnace provided with a flue for discharging combustion exhaust gas generated inside the heating furnace to the outside of the heating furnace.

Although not disclosed in Patent Document 1, a chimney is usually connected to the flue, and combustion exhaust gas is discharged out of the heating furnace by a draft (updraft) of the chimney.

JP 2014-48020 A

Since the suction force due to the chimney draft is determined by the height of the chimney, it is difficult to appropriately change it according to the amount of combustion. In other words, even if the combustion amount of the burner is reduced and the amount of flue gas discharged into the furnace is small, the chimney tries to suck the flue gas out of the furnace with a large suction force. Therefore, in the heating furnace, when the combustion amount of the burner is reduced, the combustion of the burner loses its balance, and there is a problem that it is difficult to stably control the combustion and the pressure inside the furnace.

On the other hand, when the combustion amount of the burner is reduced, the amount of combustion air required is also reduced, so part of the combustion air supplied by the blower is thrown out of the furnace by opening the bleed valve.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a combustion facility that stably controls combustion and furnace pressure even when the amount of combustion is reduced in a heating furnace.

In order to solve the above problems, a combustion facility according to one aspect of the present invention includes:
a heating furnace for burning fuel gas supplied from a fuel supply path with air supplied from an air supply path;
a flue for discharging combustion exhaust gas generated by combustion in the heating furnace to the outside of the heating furnace;
a chimney connected to the flue;
an outside air communication path branched from the air supply path and communicating with the outside air;
a bypass path branched from the outside air communication path and communicating with the flue or the bottom of the chimney,
Surplus air that has not been used for combustion in the heating furnace is supplied to the bottom of the flue or chimney through the bypass passage.

According to this invention, when the amount of combustion is small, surplus air that has been discarded outside the furnace is joined with the combustion exhaust gas through the bypass passage, thereby reducing the suction force of the draft of the chimney to the inside of the furnace. Combustion and pressure in the furnace can be stably controlled.

It is a figure explaining typically combustion equipment concerning one embodiment.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the combustion equipment 1 which concerns on this invention is described, referring drawings.

[Embodiment]
A combustion facility 1 according to one embodiment will be described with reference to FIG. FIG. 1 is a diagram schematically illustrating a combustion facility 1 according to one embodiment. In FIG. 1 , the white display of the valve indicates the open state of the valve, and the solid black display of the valve indicates the closed state of the valve.

As shown in FIG. 1 , the combustion facility 1 includes a heating furnace 2 , a flue 5 and a chimney 6 . The heating furnace 2 combusts fuel gas with combustion air by means of a plurality of combustion burners 3 to heat the material to be heated to a predetermined temperature. The heating furnace 2 is, for example, a continuous heating furnace 2 in hot rolling equipment. In the continuous heating furnace 2, for example, a slab (slab), which is a material to be heated and is charged into the heating furnace 2, is conveyed by a walking beam as a conveying means, and is preheated in the heating furnace 2. , heating zone and soaking zone in sequence. In addition, in the heating furnace 2, the exhaust heat of the combustion exhaust gas is recovered by a heat storage medium during the exhaust while the combustion and the exhaust are alternately repeated within the heating furnace 2, and the heat stored in the heat storage medium is recovered during the combustion. It is also possible to install a regenerative burner that preheats the combustion air by

The flue 5 is an exhaust path that is connected to the heating furnace 2 and discharges combustion exhaust gas generated by combustion in the heating furnace 2 to the outside of the heating furnace 2 . One side of the flue 5 is connected to the top of the furnace 2 and the other side of the flue 5 is connected to the bottom 7 of the chimney 6 . Here, the bottom portion 7 of the chimney 6 is not limited to the bottom surface of the chimney 6 and may be a side surface near the bottom of the chimney 6 .

A furnace pressure control damper 18 is provided in the flue 5 . The furnace pressure control damper 18 is arranged on the side of the heating furnace 2 in the flue 5 so that the pressure of the heating furnace 2 is balanced with the suction force due to the draft of the chimney 6 (hereinafter referred to as the draft force of the chimney 6). It has the function of controlling pressure. The chimney 6 is connected to the flue 5 and serves as an exhaust path for discharging combustion exhaust gas flowing through the flue 5 to the outside.

The air supply path 21 of the combustion burner 3 is provided with an air supply blower 11 for taking in outside air (hereinafter referred to as outside air). The air supply path 21 is branched into a plurality of branched air paths corresponding to the plurality of combustion burners 3 . A combustion air control valve 14 is provided in each of the branch air paths. The combustion air control valve 14 controls combustion air flowing through the air supply path 21 .

A fuel gas on-off valve 12 for supplying or stopping the fuel gas is provided in the fuel supply path 22 of the combustion burner 3 . The fuel supply path 22 branches into a plurality of branch gas paths corresponding to the plurality of combustion burners 3 . A fuel gas control valve 15 is provided in each of the branch gas paths. The fuel gas control valve 15 controls fuel gas flowing through the fuel supply path 22 . A flow meter 13 is provided between the fuel gas on-off valve 12 and the fuel gas control valve 15 in the fuel supply path 22 . The flow meter 13 measures the flow rate of fuel gas flowing through the fuel supply path 22 .

By opening the combustion air control valve 14 to supply combustion air to the combustion burner 3 and by opening the fuel gas control valve 15 to supply fuel gas to the combustion burner 3, the fuel gas is combusted with the combustion air. As a result, a flame is generated and flue gas is generated.

The air supply path 21 is connected to an outside air communication path 23 that branches before (upstream side) the combustion air control valve 14 and communicates with the outside air. A bypass valve 16 is provided in the outside air communication path 23 . When the amount of combustion in the heating furnace 2 is large, the bypass valve 16 is closed and the entire amount of air supplied from the air supply path 21 is used for combustion as combustion air.

A bleed valve 17 is provided on the downstream side (outside air side) of the bypass valve 16 in the outside air communication path 23 . The bleed valve 17 has a function of releasing surplus air that is not used for combustion in the heating furnace 2 and becomes excessive to the outside air when the combustion amount is small.

When both the bypass valve 16 and the bleed valve 17 are opened, the air flowing through the outside air communication path 23 is released to the outside air. When the amount of combustion in the heating furnace 2 is small, the bypass valve 16 is opened and the bleed valve 17 is closed so that the air flowing through the outside air communication path 23 flows through the bypass path 24 . Therefore, the air supplied from the air supply path 21 becomes combustion air and surplus air.

A bypass route 24 branches off from the outside air communication route 23 . One end of the bypass path 24 is connected between the bypass valve 16 and the bleed valve 17 in the outside air communication path 23 . The other end of the bypass line 24 is connected to the bottom 7 of the flue 5 or chimney 6 . Therefore, the bypass path 24 communicates the outside air communication path 23 with the flue 5 or the bottom 7 of the chimney 6 . At the bottom 7 of the flue 5 or chimney 6 the surplus air joins the flue gas through a bypass line 24 .

In the embodiment shown in FIG. 1, the other end of bypass line 24 is connected to flue 5 . As described above, the furnace pressure control damper 18 is provided on the side of the heating furnace 2 in the flue 5 . Then, for example, the bypass path 24 is connected to the chimney 6 side of the furnace pressure control damper 18 . That is, in the flue 5, the installation location of the furnace pressure control damper 18 and the connection location of the bypass route 24 are separated. As a result, the furnace pressure in the heating furnace 2 is less likely to be affected by surplus air flowing through the bypass passage 24 .

Controller 10 is electrically connected to flow meter 13 and bleed valve 17 . The controller 10 is configured using, for example, a computer including a CPU (Central Processing Unit), RAM (Random Access Memory), and ROM (Read Only Memory). The controller 10 receives fuel gas flow rate data measured by the flow meter 13 . The controller 10 controls the opening degree of the bleed valve 17 based on the fuel gas flow rate data. When the bleed valve 17 is closed, the excess air is fed through the bypass line 24 to the bottom 7 of the flue 5 or chimney 6 . When the bleed valve 17 is opened, surplus air is released to the outside air through the outside air communication path 23 .

The controller 10 measures the flow rate of the fuel gas with the flow meter 13 and controls the bleed valve 17 based on the flow rate of the fuel gas measured by the flow meter 13 . When the flow rate of the fuel gas measured by the flowmeter 13 is small, the controller 10 determines that the combustion amount of the combustion burner 3, that is, the combustion amount in the heating furnace 2 is small, and the amount of exhaust gas discharged is also small. do. Since the flow rate of the air supplied to the air supply path 21 by the air supply blower 11 is substantially constant, surplus air is generated when the combustion amount in the heating furnace 2 is small.

When the controller 10 judges that the amount of combustion in the heating furnace 2 is small, it controls the opening of the bleed valve 17 to be small. Surplus air is supplied to the bottom 7 of the flue 5 or chimney 6 via a bypass line 24 and joins the flue gas generated by combustion in the furnace 2 . As the controller 10 performs control to reduce the degree of opening of the bleed valve 17, the flow rate of surplus air flowing through the bypass path 24 increases. As the flow rate of surplus air supplied to the flue 5 or the bottom 7 of the chimney 6 through the bypass passage 24 increases, the draft force of the chimney 6 that draws in and discharges the flue gas in the furnace decreases. Moreover, since the surplus air has a lower temperature than the combustion exhaust gas, it suppresses the draft force of the chimney 6 . As a result, even when the amount of combustion is small, the combustion in the heating furnace 2 and the pressure inside the furnace can be stably controlled.

Although specific embodiments and numerical values of the present invention have been described, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope of the present invention.

The present invention and embodiments are summarized as follows.

Combustion equipment 1 according to one aspect of the present invention,
a heating furnace 2 that burns the fuel gas supplied from the fuel supply path 22 with the air supplied from the air supply path 21;
a flue 5 for discharging combustion exhaust gas generated by combustion in the heating furnace 2 to the outside of the heating furnace 2;
a chimney 6 connected to the flue 5;
an outside air communication path 23 branched from the air supply path 21 and communicating with the outside air;
A bypass path 24 branched from the outside air communication path 23 and communicating with the flue 5 or the bottom portion 7 of the chimney 6,
Surplus air not used for combustion in the heating furnace 2 is supplied to the bottom portion 7 of the flue 5 or the chimney 6 through the bypass passage 24 .

According to the above configuration, when the combustion amount is small, surplus air joins the flue gas through the bypass passage 24, so that the combustion in the heating furnace 2 and the pressure inside the furnace can be stably controlled.

In addition, in the combustion equipment 1 of one embodiment,
The flue 5 has a furnace pressure control damper 18 on the side of the heating furnace 2 for controlling the pressure in the heating furnace 2,
The bypass path 24 is connected closer to the stack 6 than the furnace pressure control damper 18 is.

According to the above embodiment, the furnace pressure in the heating furnace 2 is less likely to be affected by surplus air supplied through the bypass passage 24 .

In addition, in the combustion equipment 1 of one embodiment,
a flow meter 13 for measuring the flow rate of the fuel gas flowing through the air supply path 21;
a bleed valve 17 provided in the outside air communication path 23;
A controller 10 is further provided for controlling the bleed valve 17 based on the flow rate of the fuel gas measured by the flow meter 13 .

According to the above embodiment, automatic control of combustion can be realized at low cost.

Moreover, since the flow meter 13 and the bleed valve 17 are usually already provided in the combustion equipment 1, there is no need to newly provide them. As a result, it is possible to stably burn even a small combustion amount at low cost simply by newly providing the bypass passage 24 in the conventional structure.

In addition, in the combustion equipment 1 of one embodiment,
The controller 10 controls the opening of the bleed valve 17 to decrease as the flow rate of the fuel gas decreases.

According to the above embodiment, the surplus air merges with the flue gas to reduce the draft force of the chimney 6 with respect to the flue gas in the furnace.

A control method for combustion equipment 1 according to another aspect of the present invention includes:
In the above-described combustion facility 1, the opening degree of the bleed valve 17 is controlled to decrease as the flow rate of the fuel gas decreases, thereby increasing the flow rate of the surplus air flowing through the bypass passage 24 and increasing the flow rate of the heating furnace 2. It is characterized by reducing the suction force due to the draft of the chimney 6 against.

According to the above embodiment, the surplus air merges with the flue gas to reduce the draft force of the chimney 6 with respect to the flue gas in the furnace.

REFERENCE SIGNS LIST 1 Combustion equipment 2 Heating furnace 3 Combustion burner 5 Flue 6 Chimney 7 Bottom 10 Controller 11 Air supply blower 12 Fuel gas on-off valve 13 Flow meter 14 Combustion air control valve 15 Fuel Gas control valve 16 Bypass valve 17 Bleed valve 18 Furnace pressure control damper 21 Air supply path 22 Fuel supply path 23 Outside air communication path 24 Bypass path

Claims (5)

a heating furnace for burning fuel gas supplied from a fuel supply path with air supplied from an air supply path;
a flue for discharging combustion exhaust gas generated by combustion in the heating furnace to the outside of the heating furnace;
a chimney connected to the flue;
an outside air communication path branched from the air supply path and communicating with the outside air;
a bypass path branched from the outside air communication path and communicating with the flue or the bottom of the chimney,
A combustion facility, wherein surplus air that has not been used for combustion in the heating furnace is supplied to the bottom of the flue or the chimney through the bypass passage. The flue has a furnace pressure control damper on the heating furnace side for controlling the pressure in the heating furnace,
2. The combustion facility according to claim 1, wherein said bypass path is connected closer to said chimney than said furnace pressure control damper. a flow meter for measuring the flow rate of the fuel gas flowing through the air supply path;
a bleed valve provided in the outside air communication path;
3. The combustion facility according to claim 1, further comprising a controller that controls said bleed valve based on the flow rate of fuel gas measured by said flow meter. 4. The combustion facility according to claim 3, wherein the controller controls the degree of opening of the bleed valve to decrease as the flow rate of the fuel gas decreases. 4. The combustion equipment according to claim 3, wherein the lower the flow rate of the fuel gas, the more the flow rate of the surplus air flowing through the bypass passage is increased by performing control to decrease the opening degree of the bleed valve, and the heating furnace A control method for combustion equipment, characterized in that the suction force due to the draft of the chimney against the is reduced.

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