KR20190094803A - Gas gas heater - Google Patents

Abstract

The present invention relates to a gas gas heater, which comprises: a first heat exchanger for absorbing heat from exhaust gas flowing from a boiler to a desulfurization facility; a second heat exchanger for heating the exhaust gas flowing from the desulfurization facility to a stack side with the heat absorbed by the first heat exchanger; and a dummy heat exchanger provided on an upstream side of the first heat exchanger in a flow direction of the exhaust gas. Accordingly, corrosion of a tube can be prevented.

Description

Gas Gas Heater {GAS GAS HEATER}

The present invention relates to a gas gas heater, and more particularly to a gas gas heater equipped with a device for protecting a heat exchanger constituting the gas gas heater.

In general, a gas gas heater (GGH) for controlling the exhaust gas to an appropriate temperature is used in a desulfurization facility such as a thermal power plant. Gas gas heaters are classified into a leak type and a non-leakage type according to whether or not the gas leaks. Among them, the non-sulfur type gas gas heater includes a first heat exchanger for cooling the high-temperature exhaust gas discharged from the boiler and a second heat exchanger for heating the exhaust gas, and a tube is used as a heat exchange element of each heat exchanger. The exhaust gas is cooled by emitting heat to the heat exchange fluid flowing through the tube and inside the tube, or is heated by absorbing heat from the heat exchange fluid.

However, in the conventional gas and gas heaters, ash generated in the combustion process in the boiler is contained in the exhaust gas in a large amount, such that the ash contacts the tube and the tube is corroded.

Accordingly, an object of the present invention is to provide a gas gas heater that can prevent corrosion of the tube.

The present invention, the first heat exchanger for absorbing heat from the exhaust gas flowing from the boiler to the desulfurization facility to achieve the above object; A second heat exchanger for heating the exhaust gas flowing from the desulfurization facility to the stack side by the heat absorbed by the first heat exchanger; It provides a gas gas heater comprising a; dummy heat exchanger provided upstream of the first heat exchanger in the flow direction of the exhaust gas.

The first heat exchanger, the first frame to form the appearance of the first heat exchanger; And a first tube supported by the first frame, through which the exhaust gas flows through the outside, and through which a heat exchange fluid passes.

The dummy heat exchanger may include: a dummy frame forming an exterior of the dummy heat exchanger; And a dummy tube supported by the dummy frame and through which exhaust gas flows to the outside.

The dummy tube may be formed to overlap the first tube in the flow direction of the exhaust gas.

The dummy tube may be formed of a plurality of stages in the flow direction of the exhaust gas.

The inside of the dummy tube is formed in a hollow, the hollow tube may be formed so that the heat exchange fluid does not pass.

The dummy heat exchanger may be detachably formed to the first heat exchanger.

The dummy frame may include a hook protrusion, and the first frame may include a hook groove into which the hook protrusion is inserted.

The hook protrusion extends toward the first heat exchanger and is bent in the direction of gravity, and the hook groove may be intaglio in the direction of gravity.

The hook protrusion may be formed in plural, and the hook groove may be formed in the same number as the plurality of hook protrusions.

The dummy frame may further include a gripping lifting lug.

The lifting lugs may be nested in the dummy frame and hinged to the dummy frame to protrude from the dummy frame in a direction opposite to gravity when gripping.

Gas gas heater according to the present invention, the first heat exchanger for absorbing heat from the exhaust gas flowing from the boiler to the desulfurization facility; A second heat exchanger for heating the exhaust gas flowing from the desulfurization facility to the stack side by the heat absorbed by the first heat exchanger; By including a dummy heat exchanger provided upstream of the first heat exchanger in the flow direction of the exhaust gas, it is possible to prevent corrosion of the tube.

1 is a system diagram showing a gas gas heater according to an embodiment of the present invention;
2 is a cross-sectional view illustrating a first heat exchanger and a dummy heat exchanger in the gas gas heater of FIG. 1;
3 is a cross-sectional view illustrating that the dummy heat exchanger of FIG. 2 is detached from the first heat exchanger;
4 is a cross-sectional view showing a lifting lug provided in the dummy heat exchanger of FIG.
5 is a cross-sectional view illustrating a first heat exchanger and a dummy heat exchanger in a gas gas heater according to another embodiment of the present invention.

Hereinafter, a gas gas heater according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a system diagram showing a gas gas heater according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a first heat exchanger 100 and a dummy heat exchanger 300 of the gas gas heater of FIG. 3 is a cross-sectional view illustrating that the dummy heat exchanger 300 of FIG. 2 is detached from the first heat exchanger 100. 4 is a cross-sectional view illustrating a lifting lug 314 provided in the dummy heat exchanger 300 of FIG. 2, and FIG. 5 is a dummy view of the first heat exchanger 100 and a dummy in a gas gas heater according to another embodiment of the present invention. It is sectional drawing which shows the heat exchanger 300. FIG.

As shown in these figures, the gas gas heater according to an embodiment of the present invention is a first heat exchanger 100 for absorbing heat from the exhaust gas flowing from the boiler 10 to the desulfurization facility 20, the first The second heat exchanger 200 for heating the exhaust gas flowing from the desulfurization facility 20 to the stack 30 by the heat absorbed by the heat exchanger 100 and the first heat exchanger 100 in the flow direction of the exhaust gas. It may include a dummy heat exchanger 300 provided upstream of the).

The first heat exchanger 100 may include a first frame 110 formed to surround a circumference of the first heat exchanger 100 and a first tube that is a heat exchange element supported by the first frame 110. 120).

A heat exchange fluid may pass through the first tube 120, and hot exhaust gas flowing into the first heat exchanger 100 may flow through the outside of the first tube 120. At this time, the heat exchange fluid flowing in the first tube 120 is lower than the exhaust gas so that the heat exchange fluid absorbs the heat of the exhaust gas. That is, the exhaust gas may be cooled by the first heat exchanger 100.

The first tube 120 may be arranged to have a large heat exchange area, consisting of a plurality of tubes side by side. The plurality of side-by-side tubes does not necessarily mean only a plurality of physically independent tubes, but may form a side-by-side arrangement in which one tube is bent 180 degrees at the edge of the first heat exchanger 100. In this case, since the first tube 120 is all connected to one tube, one inlet and one outlet of the heat exchange fluid formed in the first tube 120 may be provided.

The second heat exchanger 200 uses the heat of the exhaust gas absorbed by the first heat exchanger 100 to heat the low-temperature exhaust gas passed through the desulfurization facility 20 again. That is, the direction of heat exchange occurring in the second heat exchanger 200 is opposite to that of the first heat exchanger 100. That is, heat transfer may occur from the second heat exchanger 200 to the exhaust gas.

The dummy heat exchanger 300 may include a dummy frame 310 formed to surround the dummy heat exchanger 300, and a dummy tube 320 supported by the dummy frame 310.

The dummy heat exchanger 300 may be configured in a shape and size similar to that of the first heat exchanger 100. In particular, the exhaust gas flow direction area of the dummy heat exchanger 300 is preferably formed to match the exhaust gas flow direction area of the first heat exchanger 100.

A high temperature exhaust gas flows through the outside of the dummy tube 320 to allow the exhaust gas to contact the dummy tube 320. In this case, since the dummy heat exchanger 300 is provided upstream of the first heat exchanger 100 in the flow direction of the exhaust gas, the high temperature exhaust gas first contacts the dummy tube 320 and then the first heat exchanger. May be in contact with the tube 120.

Since the dummy tube 320 is provided for the purpose of protecting the first tube 120, the shape of the dummy tube 320 may be the same as that of the first tube 120. desirable. The dummy tube 320 may be formed to overlap the first tube 120 in the flow direction of the exhaust gas so that the respective tubes face each other.

In addition, the dummy tube 320 may be formed of a plurality of stages overlapped in the flow direction of the exhaust gas in order to more effectively protect the first tube 120. In this case, the dummy tube 320 formed of a plurality of stages may be supported by one dummy frame 310. The plurality of stages may consist of dummy tubes 320 all having the same arrangement.

The inside of the dummy tube 320 may be formed in a hollow, unlike the first tube 120 may be formed so that the heat exchange fluid does not pass through the hollow. Since the heat exchange fluid does not pass, both ends of the dummy tube 320 may be formed to be open.

The dummy heat exchanger 300 is easily damaged for the purpose of protecting the first tube 120, and in such a case, replacement is necessary. Therefore, the dummy heat exchanger 300 may be detachably formed on the first heat exchanger 100.

Specifically, as shown in Figure 3, the gas gas heater according to an embodiment of the present invention may be provided with a hook protrusion 312 protruding toward the first frame 110 in the dummy frame (310). have. In addition, a hook groove 112 protruding toward the dummy frame 310 may be provided in the first frame 110. The hook protrusion 312 may be inserted into the hook groove 112.

The hook protrusion 312 may be formed in a shape in which the end is bent in the direction of gravity. Therefore, the dummy heat exchanger 300 can be detachably attached to the first heat exchanger 100 without a separate coupling mechanism such as a screw.

The hook groove 112 may be formed in a shape in which the hook protrusion 312 may be inserted. Therefore, the dummy heat exchanger 300 may be stably attached to the first heat exchanger 100.

And, as shown in Figure 3, the dummy frame 310 is provided with a protruding lifting lug 314 may facilitate the transport, detachment, etc. of the dummy frame 310. The lifting lug 314 may be formed at an upper end of the dummy frame 310 to be easily gripped by, for example, an operator or a crane. Therefore, the dummy heat exchanger 300 may be detached from the first heat exchanger 100 by lifting or lowering the dummy heat exchanger 300.

In addition, the lifting lug 314 is composed of a hinge 316 coupling to be folded to the dummy frame 310 when the lifting lug 314 is folded to reduce the volume occupied by the lifting lug 314 Can be.

Hereinafter, the effect of the gas gas heater according to the present embodiment will be described.

That is, as shown in Figure 1, since the dummy heat exchanger 300 is located upstream of the exhaust gas flow direction of the first heat exchanger 100, the dummy heat exchanger 300 is the first heat exchanger Prior to 100, the exhaust gas may be first contacted.

At this time, the exhaust gas flowing from the boiler 10 includes a large amount of ash generated in the combustion process. The ash contained in the exhaust gas reduces the heat exchange efficiency by contacting the tube of the heat exchanger, and ultimately corrodes the tube and leads to breakage.

However, since the ash included in the exhaust gas is filtered by the dummy heat exchanger 300 due to the dummy heat exchanger 300, the ash contained in the exhaust gas flowing up to the first heat exchanger 100 is reduced. Therefore, the dummy heat exchanger 300 may prevent corrosion of the first tube 120 due to ash.

In addition, since the dummy tube 320 is formed to overlap the first tube 120 in the flow direction of the exhaust gas, the differential pressure increase of the exhaust gas is increased by reducing the flow resistance of the exhaust gas due to the dummy tube 320. Can be reduced.

In addition, since the dummy tube 320 does not exchange heat with the exhaust gas, the dummy tube 320 does not need to have a high thermal conductivity, and thus, the dummy tube 320 may be made of a low cost and lightweight material. Since the manufacturing cost of the dummy tube 320 is low when the material is made of low cost material, the burden of replacing the dummy heat exchanger 300 when the life of the dummy tube 320 expires is reduced. Therefore, the first heat exchanger 100 may be effectively protected by frequently replacing the dummy heat exchanger 300.

On the other hand, as the ash contained in the exhaust gas is reduced by the dummy tube 320, the desulfurization facility 20, the second heat exchanger 200 and the exhaust gas flows to the next step of the first heat exchanger 100 and Other facilities, such as stack 30, may also reduce the risk of damage to facility structures caused by ash contained in the exhaust gas.

In addition, since the dummy heat exchanger 300 is detachably formed, only the dummy heat exchanger can be easily replaced when the dummy heat exchanger 300 has reached the end of its life. Specifically, as the detachable part is formed of the hook protrusion 312 and the hook groove 112, a quick replacement operation may be performed without the need for a separate fastening mechanism.

In addition, since the lifting lug 314 is provided in the dummy frame 310, the dummy heat exchanger 300 may be easily transported when the dummy heat exchanger 300 is replaced.

On the other hand, since the lifting lug 314 is provided by the hinge 316 coupling, the lifting lug 314 can be folded in a state where the dummy heat exchanger 300 is mounted on the first heat exchanger 100. Folding of the lifting lug 314 may prevent the lifting lug 314 from interfering with the dummy frame 310 of another dummy heat exchanger 300.

In addition, since the lifting lug 314 is mounted in a folded state, there is a side that can reduce the flow resistance of the exhaust gas as compared with the case in which the lifting lug 314 protrudes without folding.

Meanwhile, in the present embodiment, the dummy tube 320 is formed of a plurality of stages overlapping in the flow direction of the exhaust gas. As shown in FIG. 5, in another embodiment, the dummy tube 320 is one row. It may be formed in one stage forming a.

The dummy tube 320 is to prevent corrosion of the first tube 120, but if formed in a plurality of stages, such a purpose can be effectively achieved, but there is a side that prevents the flow of exhaust gas.

Therefore, according to this other embodiment, the exhaust gas can flow smoothly. In addition, since only one dummy tube is formed, the manufacturing cost of the dummy heat exchanger 300 may be reduced. In addition, since the weight of the dummy heat exchanger 300 is reduced, the dummy heat exchanger 300 may be more easily replaced.

10: boiler 20: desulfurization equipment
30: stack 100: first heat exchanger
110: first frame 112: hook groove
120: first tube 200: second heat exchanger
300: pile heat exchanger 310: pile frame
312: hook turning 314: lifting lug
316: hinge 320: dummy tube

Claims (11)

A first heat exchanger for absorbing heat from exhaust gas flowing from the boiler to the desulfurization facility;
A second heat exchanger for heating the exhaust gas flowing from the desulfurization facility to the stack side by the heat absorbed by the first heat exchanger; And
And a dummy heat exchanger provided on an upstream side of the first heat exchanger in a flow direction of the exhaust gas. The method of claim 1,
The first heat exchanger,
A first frame forming an exterior of the first heat exchanger; And
And a first tube supported by the first frame, through which exhaust gas flows through the outside, and through which a heat exchange fluid passes.
The dummy heat exchanger,
A dummy frame forming an exterior of the dummy heat exchanger; And
And a dummy tube supported by the dummy frame and through which exhaust gas flows through the dummy frame. The method of claim 2,
The dummy tube is a gas gas heater formed to overlap the first tube in the flow direction of the exhaust gas. The method of claim 3,
The dummy tube is a gas gas heater formed of a plurality of stages in the flow direction of exhaust gas. The method of claim 2,
The inside of the dummy tube is formed hollow
Gas gas heater, characterized in that the heat exchange fluid does not pass through the hollow. The method of claim 2,
The dummy heat exchanger is a gas gas heater that is formed detachably to the first heat exchanger. The method of claim 6,
The dummy frame includes a hook protrusion,
The first frame is a gas gas heater including a hook groove into which the hook protrusion is inserted. The method of claim 7, wherein
The hook protrusion extends toward the first heat exchanger and is bent in a gravity direction,
The hook groove is a gas gas heater formed intaglio in the direction of gravity. The method of claim 8,
The hook protrusion is formed in plurality,
The hook groove is a gas gas heater is formed in the same number as the plurality of hook projections. The method of claim 7, wherein
The dummy frame further comprises a gripping lifting lug. The method of claim 10,
The lifting lug is superimposed on the dummy frame and hinged to the dummy frame to protrude from the dummy frame in a direction opposite to gravity when gripping.

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