KR101492731B1 - Circulating fluid bed boiler - Google Patents

Abstract

The present invention relates to a fluidized bed boiler capable of controlling thermal absorptance of an external heat exchanger. For an embodiment of the present invention, disclosed is the fluidized bed boiler comprising: a furnace which combusts a fuel; a cyclone which is connected to the furnace to collect a bed material; the external heat exchanger which is connected to the lower part of the cyclone to store the bed material and in which a heat exchanger tube absorbing heat from the bed material is formed; and a drain port which is connected between the external heat exchanger and the furnace and has a drain valve controlling the amount of the bed material to be supplied to the furnace.

Description

[0001] The present invention relates to a circulating fluid bed boiler,

The present invention relates to a fluidized bed boiler.

Unlike pulverized coal boilers, which have a heat exchanger that absorbs heat by high temperature (1,300 ° C or more) flue gas radiation and convection, the circulating fluidized bed boiler includes a heat exchanger that is heat transferred by layer material as well as radiation, convection of the flue gas. Unlike a pulverized coal-fired boiler, a circulating fluidized-bed boiler burns fuel at about 800 to 900 ° C without a flame and transfers the flue gas to a back-pass at a temperature of about 800 to 900 ° C. Accordingly, the circulating fluidized bed boiler has a heat distribution configuration that allows the heat generated in the combustion of the fuel to be absorbed by using the heat exchanger and the external heat exchanger in the furnace.

To this end, circulating fluidized bed boilers use wingwalls (evaporators, superheaters, etc.) and external heat exchangers as well as water cooling walls (evaporators) on the wall of the combustion furnace used in pulverized coal boilers. The external heat exchanger is manufactured in a different form for each fluidized-bed boiler manufacturer. The external heat exchanger is operated in the form of a bubbling fluidized bed and has a constant heat transfer coefficient (about 400 W / m ² K) There is an excellent feature in terms of control and driving rather than wingwolle. In the case of the Intrex used by Fosterwheeler, not only all the layer materials collected in the cyclone but also the layer material in the furnace are supplied through the inner circulation port and the sufficient layer material is injected into the Intrex and the outflow the amount of layer material present in Intrex is constantly maintained through a port called outflow, so that a certain amount of heat is transferred to the tube. In addition, Alstome uses the automatic control valve (ACV) to inject the desired amount of layer material into the Fluidized Bed Heat Exchanger (FBHE) to transfer the desired amount of heat transfer to the tube Were injected into the furnace.

However, in the case of Post Wheeler Intrex, the amount of layer material can be kept constant through the outflow port, but there is no way to control the amount of layer material. Therefore, excessive heat transfer occurs when a high-temperature layer material is supplied. In addition, Alstom can regulate the amount of layer material injected into the external heat exchanger through ACV, so that the desired heat transfer amount can be obtained irrespective of the temperature of the layer material, but the control of the opening determined by ACV is not accurate. The control operation is difficult and the failure of the ACV driving part often occurs and the heat transfer amount can not be accurately ensured.

Korean Patent Publication No. 10-2012-0075082 (Jul. 06, 2012)

The present invention provides a fluidized-bed boiler capable of controlling the amount of heat absorption of an external heat exchanger.

A fluidized-bed boiler according to the present invention comprises a combustion furnace for burning fuel; A cyclone connected to the combustion furnace to collect the layer material; An external heat exchanger connected to a lower portion of the cyclone to store the layer material and having a heat exchange tube for absorbing heat from the layer material; And a drain port connected between the external heat exchanger and the combustion furnace and having a drain valve for regulating the amount of the bed material supplied to the furnace.

The drain port may be connected to a lower portion of the external heat exchanger, and may be connected to a location where the cyclone is connected to the external heat exchanger.

When the amount of heat absorbed by the external heat exchanger is larger than the amount of heat absorbed by the external heat exchanger designed in advance, the opening degree of the drain valve is increased to increase the amount of the layer material supplied to the combustion furnace, Can be reduced.

When the amount of heat absorbed by the external heat exchanger is smaller than the amount of heat absorbed by the pre-designed external heat exchanger, the opening degree of the drain valve is reduced to reduce the amount of the layer material supplied to the furnace, Can be increased.

When the value obtained by dividing the heat absorption amount of the external heat exchanger by the designed amount of heat absorption of the external heat exchanger is larger than 1 plus the allowable heat absorption amount ratio, The amount of heat absorbed by the external heat exchanger can be reduced by increasing the amount of the material.

When the value obtained by dividing the heat absorption amount of the external heat exchanger by the designed amount of heat absorption of the external heat exchanger is smaller than the value obtained by subtracting the allowable heat absorption amount ratio from 1, the opening degree of the drain valve is made small, It is possible to increase the amount of heat absorbed by the external heat exchanger by reducing the amount of the material.

The apparatus may further include a connection port formed on a side surface of the external heat exchanger and connecting the external heat exchanger and the combustion furnace, wherein the connection port is located far from the cyclone connected to the external heat exchanger .

Further, the connection port may supply the layer material from which heat is recovered to the combustion furnace through the external heat exchanger.

In addition, the fluidized-bed boiler according to the present invention comprises a combustion furnace for burning fuel; A cyclone connected to the combustion furnace to collect the layer material; An external heat exchanger connected to a lower portion of the cyclone to store the layer material and having a heat exchange tube for absorbing heat from the layer material; A connection port formed on a side surface of the external heat exchanger and connected to the external heat exchanger and the furnace; And a sliding gate formed at a position where the external heat exchanger and the connection port are coupled to each other and controlling the height of the layer material stored in the external heat exchanger.

When the amount of heat absorbed by the external heat exchanger is greater than the amount of heat absorbed by the external heat exchanger designed in advance, the height of the sliding gate is decreased to decrease the height of the layer material contacting the heat exchanging tube, .

When the heat absorption amount of the external heat exchanger is smaller than the heat absorption amount of the external heat exchanger designed in advance, the height of the sliding gate is increased to increase the height of the layer material contacting the heat exchange tube, .

When the value obtained by dividing the amount of heat absorption of the external heat exchanger by the designed amount of heat absorption of the external heat exchanger is larger than the value obtained by adding the allowable heat absorption amount ratio to 1, the height of the sliding gate is lowered, The height of the material can be lowered to reduce the heat absorption amount of the external heat exchanger.

When the value obtained by dividing the heat absorption amount of the external heat exchanger by the designed amount of heat absorption of the external heat exchanger is smaller than the value obtained by subtracting the allowable heat absorption amount ratio from 1, the height of the sliding gate is increased, The height of the material can be increased to increase the heat absorption amount of the external heat exchanger.

The fluidized bed boiler according to an embodiment of the present invention includes a drain valve that can control the amount of the bed material injected from the external heat exchanger into the combustion furnace to control the amount of heat absorption of the external heat exchanger.

In addition, the fluidized bed boiler according to another embodiment of the present invention includes a sliding gate that can control the height of the layer material stored in the external heat exchanger, thereby controlling the amount of heat absorption of the external heat exchanger.

1 is a schematic view showing the construction of a fluidized-bed boiler according to an embodiment of the present invention.
2 is a schematic view showing the construction of a fluidized-bed boiler according to another embodiment of the present invention.
FIG. 3 is a schematic view for explaining the operation of the external heat exchanger shown in FIG. 2. FIG.
4 is a flow chart illustrating the control logic of the external heat exchanger in a fluidized bed boiler according to an embodiment of the present invention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

1 is a schematic view showing the construction of a fluidized-bed boiler according to an embodiment of the present invention.

Referring to FIG. 1, a fluidized-bed boiler 100 according to an embodiment of the present invention includes a combustion furnace 110, a cyclone 120, an external heat exchanger 130, a connection port 140, and a drain port 150 .

The furnace 110 combusts while flowing the fuel to generate a high temperature exhaust gas. The hot exhaust gas passes through the cyclone 120 and is transferred to a back pass.

The cyclone 120 is connected to the combustion furnace 110 and collects the layer material M scattering from the combustion furnace 110.

The external heat exchanger 130 is connected to the lower portion of the cyclone 120 to store the collected layer material M in the cyclone 120. In addition, the external heat exchanger 130 includes a heat exchange tube 131 for absorbing heat from the layer material M. The heat exchange tube 131 may be formed in a zigzag shape so as to widen an area in contact with the layer material M in a state where the heat exchange tube 131 is immersed in the layer material M stored in the external heat exchanger 130. Water or steam may circulate through the heat exchange tube 131 to absorb heat from the layer material M.

The connection port 140 is connected between the external heat exchanger 130 and the combustion furnace 110. Specifically, one end of the connection port 140 is connected to a side of the external heat exchanger 130, and the other end is connected to a lower end of the combustion furnace 110. The connection port 140 is connected to a side surface of the external heat exchanger 130 that is remote from the connection of the cyclone 120. Accordingly, the layer material M injected from the cyclone 120 reaches the connection port 140 through the heat exchange tube 131 of the external heat exchanger 130 to recover heat. The connection port 140 recycles the layer material M from which heat has been recovered from the external heat exchanger 130 to the combustion furnace 110.

The drain port 150 is connected between the external heat exchanger 130 and the combustion furnace 110. Specifically, one end of the drain port 150 is connected to a lower surface of the external heat exchanger 130, and the other end is connected to a lower portion of the furnace 110. The drain port 150 is connected to a lower surface of the external heat exchanger 130 where the cyclone 120 is connected. Accordingly, the layer material M injected from the cyclone 120 and not yet recovered heat reaches the drain port 150. The drain port 150 includes a drain valve 151 for regulating the amount of the layer material M injected into the combustion furnace 110. The amount of heat absorption of the external heat exchanger 130 can be adjusted by adjusting the opening degree of the drain valve 151. If the opening degree of the drain valve 151 is reduced, the amount of the layer material M injected into the combustion chamber 110 decreases and the amount of the layer material M stored in the external heat exchanger 130 becomes relatively small. The amount of heat absorbed by the external heat exchanger 130 is increased. If the opening degree of the drain valve 151 is increased, the amount of the layer material M injected into the combustion chamber 110 increases, and the layer material M stored in the external heat exchanger 130 relatively increases The amount of heat absorption of the external heat exchanger 130 is reduced.

Therefore, when the amount of heat absorption absorbed by the external heat exchanger 130 is compared with a desired amount of heat absorption, when the amount of heat absorbed by the external heat exchanger 130 is insufficient, the opening degree of the drain valve 151 is reduced, When the amount of heat absorbed by the external heat exchanger 130 is greater than a desired amount of heat absorption, the opening degree of the drain valve 151 is increased to increase the amount of heat absorbed by the external heat exchanger 130 130 can be reduced.

As described above, the fluidized-bed boiler 100 according to an embodiment of the present invention includes the drain valve 151 that can control the amount of the layer material M injected into the combustion furnace 110 from the external heat exchanger 130 The heat absorption amount of the external heat exchanger 130 can be adjusted.

2 is a schematic view showing the construction of a fluidized-bed boiler according to another embodiment of the present invention. FIG. 3 is a schematic view for explaining the operation of the external heat exchanger shown in FIG. 2. FIG.

The fluidized bed boiler 200 shown in FIG. 2 is similar to the fluidized bed boiler 100 shown in FIG. Therefore, only differences will be described below.

Referring to FIG. 2, a fluidized-bed boiler 200 according to another embodiment of the present invention includes a combustion furnace 110, a cyclone 120, an external heat exchanger 130, a connection port 140, and a sliding gate 250 .

The sliding gate 250 is formed between the external heat exchanger 130 and the connection port 140. Specifically, the sliding gate 250 is formed at a position where the connection port 140 is coupled to the side of the external heat exchanger 130, and can be slid up and down. Further, the sliding gate 250 can control the amount of heat absorption of the external heat exchanger 130 by adjusting the height.

3, when the height h of the sliding gate 250 is lowered, the height of the layer material M stored in the external heat exchanger 130 is lowered, The amount of heat absorption of the external heat exchanger 130 is reduced since the area in which the tube 131 is in contact with the layer material M is reduced. When the height h of the sliding gate 250 is increased to increase the height of the layer material M stored in the external heat exchanger 130 and the heat exchange tube 131 is heated to a temperature higher than the temperature of the layer material M, The amount of heat absorbed by the external heat exchanger 130 is increased.

Therefore, when the heat absorption amount absorbed by the external heat exchanger 130 is compared with the desired heat absorption amount, the height h of the sliding gate 250 is increased when the heat absorption amount absorbed by the external heat exchanger 130 is insufficient When the amount of heat absorbed by the external heat exchanger 130 is greater than a desired amount of heat absorption, the height h of the sliding gate 250 is lowered to increase the amount of heat absorbed by the external heat exchanger 130, The amount of heat absorbed by the external heat exchanger 130 can be reduced.

As described above, the fluidized-bed boiler 200 according to another embodiment of the present invention includes the sliding gate 250 that can adjust the height of the layer material M stored in the external heat exchanger 130, so that the external heat exchanger 130 ) Can be adjusted.

4 is a flow chart illustrating the control logic of the external heat exchanger in a fluidized bed boiler according to an embodiment of the present invention. The operation of the external heat exchanger shown in Figs. 1 and 2 will be described in detail with reference to the control logic of Fig. Here, it is assumed that the opening degree of the drain valve 151 is 50% or the height of the sliding gate 250 is 50%.

First, the necessary heat absorption amount of the external heat exchanger is inputted, and then the heat absorption amount of the external heat exchanger in the present operating condition is calculated (see S1 and S2).

In addition, when the ratio of the actual heat absorption amount of the external heat exchanger to the heat absorption amount of the design external heat exchanger satisfies the allowable heat absorption amount ratio (for example, 0.01) (S3 to S6) If the allowable heat absorption rate is greater than or less than the allowable heat absorption rate, the drain valve 151 or the sliding gate 250 is adjusted to adjust the heat distribution load (see S7 to S10). Here, calculation of the heat absorption amount of the actual external heat exchanger is well known to those skilled in the art, and therefore, detailed description thereof will be omitted.

On the other hand, the heat absorption ratio to the external heat exchanger is calculated by the following equation (1). (See S3)

[Equation 1]

If DQ _{heatexchanger} is larger than 1 in Equation 1, it means that more heat is absorbed by the actual heat exchanger than the design value. Conversely, if it is smaller than 1, it means that the actual heat exchanger absorbs less heat than the design value .

That is, if the DQ _{heatexchanger} is larger than the value obtained by adding the allowable heat absorption ratio to 1, the drain valve 151 is further opened or the height of the sliding gate 250 is decreased to reduce the heat absorption amount of the external heat exchanger (see S7 and S8) .

Further, if the DQ _{heatexchanger} is smaller than the value obtained by subtracting the allowable heat absorption ratio from 1, the drain valve 151 is further _closed or the height of the sliding gate 250 is increased to increase the heat absorption amount of the external heat exchanger (refer to S9 and S10) .

As described above, the present invention is a control method that can be adjusted when the heat distribution load during operation is not matched, so that the drain valve 151 or the sliding gate 250 can be controlled by comparing the actual heat absorption amount obtained by the external heat exchanger with the designed heat absorption amount, To reduce or increase the amount of heat absorbed by the external heat exchanger. Therefore, the fluidized bed boiler according to the embodiment of the present invention is simple in structure and can control the heat absorption amount of the external heat exchanger.

The present invention is not limited to the above-described embodiments, but may be modified in various other forms without departing from the spirit of the present invention as claimed in the following claims. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

100: Fluidized bed boiler 110: Combustion furnace
120: Cyclone 130: External heat exchanger
131: heat exchange tube 140: connection port
150: drain port 151: drain valve
250: Sliding gate

Claims (13)

A combustion furnace for burning fuel;
A cyclone connected to the combustion furnace to collect the layer material;
An external heat exchanger connected to a lower portion of the cyclone to store the layer material and having a heat exchange tube for absorbing heat from the layer material; And
And a drain port connected between the external heat exchanger and the combustion furnace and having a drain valve for regulating the amount of the bed material supplied to the furnace,
When the heat absorption amount of the external heat exchanger is larger than the heat absorption amount of the external heat exchanger designed in advance,
Wherein the opening degree of the drain valve is increased to increase the amount of the layer material supplied to the combustion furnace to reduce the heat absorption amount of the external heat exchanger. The method according to claim 1,
Wherein the drain port is connected to a lower portion of the external heat exchanger, and the cyclone is connected to a portion corresponding to a portion where the cyclone is connected to the external heat exchanger. delete The method according to claim 1,
When the heat absorption amount of the external heat exchanger is smaller than the heat absorption amount of the external heat exchanger designed in advance,
Wherein the amount of the layer material supplied to the combustion furnace is reduced by decreasing the opening degree of the drain valve to increase the heat absorption amount of the external heat exchanger. A combustion furnace for burning fuel;
A cyclone connected to the combustion furnace to collect the layer material;
An external heat exchanger connected to a lower portion of the cyclone to store the layer material and having a heat exchange tube for absorbing heat from the layer material; And
And a drain port connected between the external heat exchanger and the combustion furnace and having a drain valve for regulating the amount of the bed material supplied to the furnace,
When the value obtained by dividing the amount of heat absorption of the external heat exchanger by the amount of heat absorption of the designed external heat exchanger is larger than the value obtained by adding the allowable heat absorption amount ratio to 1,
Wherein the opening degree of the drain valve is increased to increase the amount of the layer material supplied to the combustion furnace to reduce the heat absorption amount of the external heat exchanger. 6. The method of claim 5,
When the value obtained by dividing the heat absorption amount of the external heat exchanger by the heat absorption amount of the designed external heat exchanger is smaller than the value obtained by subtracting the allowable heat absorption amount ratio from 1,
Wherein the amount of the layer material supplied to the combustion furnace is reduced by decreasing the opening degree of the drain valve to increase the heat absorption amount of the external heat exchanger. The method according to claim 1,
And a connection port formed on a side surface of the external heat exchanger for connecting the external heat exchanger and the combustion furnace,
Wherein the connection port is located remote from where the cyclone is connected to the external heat exchanger. The method according to claim 1,
Wherein the connection port supplies the heat recovered layer material to the combustion furnace through the external heat exchanger. A combustion furnace for burning fuel;
A cyclone connected to the combustion furnace to collect the layer material;
An external heat exchanger connected to a lower portion of the cyclone to store the layer material and having a heat exchange tube for absorbing heat from the layer material;
A connection port formed on a side surface of the external heat exchanger and connected to the external heat exchanger and the furnace; And
And a sliding gate formed at a position where the external heat exchanger and the connection port are coupled to each other and controlling the height of the layer material stored in the external heat exchanger,
When the heat absorption amount of the external heat exchanger is larger than the heat absorption amount of the external heat exchanger designed in advance,
Wherein the height of the sliding gate is lowered to lower the height of the layer material contacting the heat exchange tube to reduce the heat absorption amount of the external heat exchanger. delete 10. The method of claim 9,
When the heat absorption amount of the external heat exchanger is smaller than the heat absorption amount of the external heat exchanger designed in advance,
Wherein the height of the sliding gate is increased to increase the height of the layer material contacting the heat exchange tube to increase the heat absorption amount of the external heat exchanger. A combustion furnace for burning fuel;
A cyclone connected to the combustion furnace to collect the layer material;
An external heat exchanger connected to a lower portion of the cyclone to store the layer material and having a heat exchange tube for absorbing heat from the layer material;
A connection port formed on a side surface of the external heat exchanger and connected to the external heat exchanger and the furnace; And
And a sliding gate formed at a position where the external heat exchanger and the connection port are coupled to each other and controlling the height of the layer material stored in the external heat exchanger,
When the value obtained by dividing the amount of heat absorption of the external heat exchanger by the amount of heat absorption of the designed external heat exchanger is larger than the value obtained by adding the allowable heat absorption amount ratio to 1,
Wherein the height of the sliding gate is lowered to lower the height of the layer material contacting the heat exchange tube to reduce the heat absorption amount of the external heat exchanger. 13. The method of claim 12,
When the value obtained by dividing the heat absorption amount of the external heat exchanger by the heat absorption amount of the designed external heat exchanger is smaller than the value obtained by subtracting the allowable heat absorption amount ratio from 1,
Wherein the height of the sliding gate is increased to increase the height of the layer material contacting the heat exchange tube to increase the heat absorption amount of the external heat exchanger.

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