KR20090090223A - Smoke tube packaged boiler - Google Patents

Abstract

A smoke tube packaged boiler is provided to easily fix a gas circulation member to the inside of a smoke tube unit, thereby designing a small boiler. A boiler main body member comprises a smoke tube unit(11), a water tank(12) and an exhausting unit(13). The water tank is located in the outside of the smoke tube unit to store water. The exhausting unit exhausts combustion gas. One or more connecting members are inside the water tank. A burner member generates flame. The burner member is mounted in the smoke tube unit. The gas circulation member has a hollow flow path(41) through which the combustion gas passes. A narrow tube unit(42) is installed inside the hollow flow path. A support tube member surrounds the outside of the gas circulation member to fix a location of the gas circulation member.

Description

Smoke tube associated boiler {Smoke Tube Packaged Boiler}

The present invention relates to a furnace associated boiler, and more particularly, to a furnace associated boiler that can reduce the amount of NOx generated during combustion to minimize environmental pollution.

In general, the furnace associated boiler has a furnace through which combustion gas passes, and the heat exchange area is increased by increasing a heat exchange area through a plurality of tubes connected to the furnace through which the combustion gas passes.

The furnace-associated boiler is pressurized due to the closed structure of the furnace, which increases the evaporation rate per unit heat transfer area, which is advantageous for fuel saving.The heat exchange is carried out through the furnace, which provides high heat efficiency and high steam generation speed. It is used for various production plants and large apartment buildings that need it.

1 is a view illustrating such a conventional furnace associated boiler, the furnace associated boiler includes a furnace section 11 in which combustion gas flows from one side to the other side, and the outside of the furnace section 11. A boiler body member (10) having a water tank (12) in which water is stored and having an exhaust portion (13) for discharging combustion gas on one side thereof;

One or more associated members (20) provided in the tank chamber (12) and in communication with the furnace section (11) for moving the combustion gas of the furnace section (11) to the exhaust section (13);

The burner member 30 is mounted on one side of the furnace part 11 and generates a flame to heat the air.

The furnace tube associated boiler is configured to discharge water stored in the tank chamber 12 while the combustion gas heated by the flame of the burner member 30 passes through the furnace tube 11 and the tube member 20 and is discharged to the exhaust unit 13. The heated and heated hot water is circulated through the heat exchanger and the heating pipe.

In this furnace-associated boiler, the nitrogen component in the fuel and the nitrogen component in the air react with the surplus air in the combustion gas to generate nitrogen oxides (NOx) during the flame combustion of the burner member 30.

Nitrogen oxides (NOx) are environmental pollutants that cause acid rain, photochemical smog, snow and respiratory disturbances, and ozone production. To prevent environmental pollution, the amount of nitrogen oxides produced should be minimized.

However, in the conventional furnace associated boiler, a large amount of nitrogen oxide is generated by a high temperature flame, and the combustion gas containing the nitrogen oxide is discharged as it is to the exhaust unit through the furnace barrel 11 and the associated member 20, thereby preventing environmental pollution. There was a problem to increase.

The present invention has been made to solve the conventional problems as described above, an object of the present invention is to reduce the amount of nitrogen oxides (NOx) generated by recycling the combustion gas to the burner side by reducing the flame temperature during combustion of the furnace-associated boiler To provide.

The object of the present invention is a boiler body member having a combustion chamber in which combustion gas flows from one side to the other side, a water tank chamber in which water is stored outside the furnace portion, and an exhaust unit for discharging the combustion gas on one side;

At least one associated member provided in the tank chamber and communicating with the furnace tube to move combustion gas of the furnace portion to the exhaust unit;

A burner member mounted to one side of the furnace part to generate a flame;

A hollow flow path is formed in the furnace part at a predetermined distance from the burner member and a combustion flow passage is formed. A gas circulation member to make;

It is solved by providing a furnace-related boiler including a support tube member communicating with the tank chamber to circulate water in the tank chamber and surrounding the outside of the gas circulation member to fix the position of the gas circulation member.

The present invention has the effect of minimizing environmental pollution by reducing the amount of nitrogen oxide (NOx) generated during combustion by lowering the flame temperature by circulating the combustion gas.

In addition, the present invention can easily support and fix the gas circulation member for partially circulating the combustion gas to the burner side as a support tube member through which water circulates in the high-temperature furnace tube portion, so that a compact boiler design is possible.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

FIG. 2 is a cross-sectional view showing the structure of the present invention, and shows an embodiment in which a plurality of associated members are provided in a tank chamber formed outside the furnace part.

3 is an enlarged cross-sectional view of the main portion of the present invention, showing a state in which the combustion gas is partially circulated to the burner member with a gas circulation member mounted at an arbitrary distance from the burner member.

4A to 4B are perspective views showing the gas circulation member of the present invention, showing that the support tube member is wound around the outer circumferential surface of the gas circulation member.

5A to 5B are enlarged cross-sectional views of the main part of another embodiment of the present invention, and show an example in which a protrusion is fixed to the outer circumferential surface of the gas circulation member to catch the support tube member to fix the position of the gas circulation member.

Hereinafter, as shown in FIG. 2, the boiler body member 10 of the present invention associated furnace boiler includes a furnace part 11 in which combustion gas flows from one side to the other side, and the furnace part 11 and the boiler body member. Between the inner surface of the (10) is formed a water tank chamber 12 in which water is stored.

The boiler body member 10 is basically formed in a cylindrical shape and the furnace part 11 is formed in a cylindrical shape having a diameter smaller than the diameter of the boiler body member 10 to form a combustion chamber 11a therein. Is mounted to the inside of the boiler body member 10, the inner surface of the boiler body member 10 is mounted so as to have a predetermined interval between the tank chamber 12 and the inner surface of the boiler body member (10) To form.

In addition, the boiler body member 10 is connected to the associated member 20 to be described later on one side has an exhaust 13 for discharging the combustion gas.

In addition, it is preferable that the furnace part 11 is formed in a waveform in which the outer circumferential surface is a waveform in which mountains and valleys are repeated, thereby increasing the contact area with water in the tank chamber 12 to increase heat exchange efficiency.

An end portion of the furnace portion 11 is provided with a communication chamber 11a to which the end portion of the associated member 20 is coupled and communicated.

The associating member 20 is a tubular member having a pipeline through which combustion gas passes through, and is mounted in the water tank chamber 12 so that both ends thereof communicate with each other by being connected to the communication chamber 11a and the exhaust 13. The combustion gas generated in the combustion chamber 11a of the furnace part 11 flows into the exhaust part 13 and is discharged.

The associating member 20 is provided outside the furnace part 11, ie, inside the water tank chamber 12, with a plurality of spaces to increase the heat exchange area to increase heat exchange efficiency.

In addition, a burner member 30 for generating a flame and heating air in the combustion chamber 11a is mounted on one side of the furnace part 11.

The burner member 30 has a spray medium supplied to the center, and fuel is supplied to the outside of the spray medium. The burner member 30 has a spray mixing chamber (not shown) for mixing and spraying the fuel and the spray medium at the end to spray the fuel. It is ignited while generating a flame.

The burner member 30 is well known in the art, and a detailed description thereof will be omitted, and it is to be understood that the present invention includes any structure other than the above-described structure that generates a flame by ignition while discharging fuel.

On the other hand, the gas circulation member 40 is mounted inside the furnace part 11 at an arbitrary distance from the burner member 30.

As shown in FIG. 3, the gas circulation member 40 has a hollow flow passage 41 through which combustion gas passes, and the hollow flow passage 41 has a narrow tube portion having a narrow diameter in the flow passage. (42) is provided.

In the gas circulation member 40, when the combustion gas passes through the hollow flow passage 41, the flow rate increases in the buccal tube 42, thereby lowering the pressure of the fluid.

In addition, the combustion gas passes through the narrow pipe part 42 and is discharged to the outlet side of the gas circulation member 40 so as to expand, thereby slowing the flow rate and increasing the pressure of the fluid. At this time, some of the discharged combustion gas is the gas circulation member 40. It is sucked between the gap between the gas circulation member 40 and the burner member 30 along the outer wall of the.

The combustion gas reabsorbed between the gas circulation member 40 and the burner member 30 reduces the flame temperature of the burner member 30 to reduce the amount of nitrogen oxides (NOx) generated during combustion.

The hollow flow passage 41 of the gas circulation member 40 is formed such that the flow passage is gradually narrowed from the inlet side to the buccal tube portion 42 and gradually widens from the narrow pipe portion 42 side to the outlet side and passes through the flow passage. It is desirable to make the flow of the combustion gas smooth.

In addition, the hollow passage 41 of the gas circulation member 40 preferably has a length from the inlet to the buccal tube 42 shorter than the length from the buccal tube 42 to the outlet.

The flow rate of the combustion gas is rapidly increased from the inlet to the buccal tube part 42, and gradually expands after passing through the buccal tube part 42, and the flow rate is slowed down, thereby increasing the amount of suction between the gas circulation member 40 and the burner member 30. In addition, it is possible to further reduce the amount of nitrogen oxides (NOx) generated during combustion.

On the other hand, the inside of the side wall of the body member 10 provided with the burner member 30 is heated by the combustion gas and the combustion gas recycled along the outer wall of the gas circulation member 40 by passing through the buccal tube part 42 at a high temperature. Since the flue gas of the combustion gas is maintained at a high temperature due to the heat of the inner side wall of the body member 10, the water in the tank chamber 12 is connected to the inner side wall of the body member 10 so as to communicate with the water tank chamber 12. It is preferable to reduce the temperature of the recirculated combustion gas by installing the circulating water cooling tube member 52 and cooling the inner sidewall.

FIG. 6 is a schematic side view of the water cooling tube member along the line AA ′ of the embodiment of FIG. 2. As illustrated, the water cooling tube member 52 communicates with the water tank chamber 12 so that water is introduced and discharged. 53, 55, a communication tube 57 through which water supplied from the communication tube is circulated, and a cooling tube 59 communicating with the communication tube 57 and arranged radially, and communicating with the communication tube from the water tank chamber 12. The water obtained as 53) circulates through the cooling tube 59 through the contact tube 57 to cool the inner side surface of the main body member 10 so that the combustion gas recycled along the outer wall of the gas circulation member 4 is cooled. .

On the other hand, the gas circulation member 40 is made of a known refractory that is maintained at a high temperature in the combustion chamber (11a) and does not deform, in the present invention using a castable mixed with a refractory aggregate and a binder (Castable) It is based on manufacturing.

As shown in FIGS. 4A to 4B, the gas circulation member 40 is connected to the tank chamber 12 so as to be wrapped and fixed by a support tube member 50 through which water in the tank chamber 12 is circulated and burner member ( It is mounted inside the furnace part 11, that is, in the combustion chamber 11a so that it may have an arbitrary distance from 30).

Since both ends of the support tube member 50 communicate with the tank chamber, the water in the tank chamber 12 is circulated so that the gas circulation member 40 is not deformed or damaged even in the high temperature of the combustion chamber 11a. It is to be mounted so as to have a random interval with the burner member (30).

The support tube member 50 may be wound around the outer circumferential surface of the gas circulation member 40 several times with a single tube to fix the gas circulation member 40. The support tube member 50 may be provided in plural to wind the outer circumferential surface of the circulation member 40, respectively. ) Can be fixed.

The support pipe member 50 is sucked between the gas circulation member 40 and the burner member 30 along the outside of the gas circulation member 40 to lower the temperature of the recirculated combustion gas, thereby reducing nitrogen oxides (NOx) generated during combustion. The amount of generation can be further reduced.

The outer circumferential surface of the gas circulation member 40 is provided with a mounting plate portion 43 joined to the support tube member 50, and the mounting plate portion 43 is wrapped with the support tube member 50 to be cooled and thus the combustion chamber 11a. It is to be fixed to the position of the gas circulation member 40 without being deformed even in the high temperature.

In addition, the outer circumferential surface of the gas circulation member 40 is provided with a protrusion 44 that is supported by the support tube member 50 as shown in Figure 5a to 5b can fix the position of the gas circulation member 40 It is.

The protrusion 44 may protrude on both end sides of the outer circumferential surface of the gas circulation member 40 as shown in FIG. 5A to support the support tube member 50, and as shown in FIG. 5B, a plurality of supports may be provided. Protruding between the tube members 50 may support the support tube member 50 by walking.

As described above, the gas circulation member 40 for recycling the combustion gas to the burner member 30 side is supported by the support tube member 50 through which the water in the tank chamber 12 is circulated. Since it is mounted inside the flame temperature of the burner member 30 it is possible to reduce the amount of nitrogen oxide (NOx) generated during combustion to prevent environmental pollution.

The present invention is not limited to the above-described embodiments, but can be modified and practiced in various ways within the scope not departing from the gist of the present invention, which is understood to be included in the configuration of the present invention.

1 is a cross-sectional view showing the structure of a conventional furnace-associated boiler

2 is a cross-sectional view showing the structure of the present invention.

3 is an enlarged cross-sectional view of the main part of the present invention;

4a to 4b are perspective views showing the gas circulation member of the present invention

5a to 5b is an enlarged cross-sectional view of the main portion showing another embodiment of the present invention

Figure 6 is a schematic side view of the water cooling tube member of the present invention along the line AA 'of Figure 2

* Description of the major symbols in the drawings *

10: boiler body member 11: the furnace part

12: water tank chamber 13: exhaust section

20: associated member 30: burner member

40: gas circulation member 41: hollow flow path

42: buccal tube portion 43: mounting plate portion

44: protrusion 50: support pipe member

52: water cooling tube member

Claims (5)

A boiler body member having a furnace part in which combustion gas flows from one side to the other side, a water tank chamber in which water is stored outside the furnace part, and an exhaust part configured to discharge the combustion gas on one side; At least one associated member provided in the tank chamber and communicating with the furnace tube to move combustion gas of the furnace portion to the exhaust unit; A burner member mounted to one side of the furnace part to generate a flame; A hollow flow path is formed in the furnace part at a predetermined distance from the burner member and a combustion flow passage is formed, and a narrow narrow pipe portion is formed in the flow path to circulate a part of the combustion gas passed to the burner member side. A gas circulation member to make; And a support tube member communicating with the tank chamber to circulate water in the tank chamber and surrounding the outside of the gas circulation member to fix the position of the gas circulation member. The method according to claim 1, The pain tube is associated with the boiler, characterized in that the outer circumferential surface is formed in a waveform that the mountain and the valley repeat. The method according to claim 1, The outer circumferential surface of the gas circulation member, the furnace tube associated boiler characterized in that the mounting plate is joined to the support tube member. The method according to claim 1, The outer circumferential surface of the gas circulation member is associated with the boiler, characterized in that the projection is supported by the support tube member. The method according to claim 1, And a water cooling tube member connected to the water tank chamber in a side wall of the main body member on which the burner member is mounted to circulate water in the water tank chamber.

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