KR101383859B1 - Two drum type marine boiler - Google Patents

Abstract

The present invention relates to a two-drum type marine boiler to improve the heat exchange efficiency inside the boiler for steam generation.
To this end, the present invention and the body portion is a plurality of bank tubes are built-in; A water drum provided below the body part and storing water; A steam drum provided at an upper portion of the body part and into which steam generated from the water is introduced; And a burner part for supplying a flame to the inside of the body part, wherein the bank tube communicates with the steam drum by evaporating the water in the water drum by heat supplied by the flame of the burner part. It is to provide a two-drum type marine boiler characterized in that a plurality of heat dissipation fins are formed to protrude to increase the heat exchange area to increase the heat exchange performance.

Description

Two drum type marine boiler

The present invention relates to a marine boiler, and more particularly to a two-drum type marine boiler with increased heat exchange efficiency inside the boiler for the generation of steam.

In general, a boiler is a device that generates steam with high temperature and pressure by transferring the heat of combustion of fuel to water, etc. do.

There are many kinds of such boilers according to their structural type. Among them, marine boilers usually produce steam to drive turbines used in ships or preheat the oil tanks for driving turbines and boilers to save energy. It does what it does.

Conventional marine boilers include a closed body portion having a predetermined space therein and a burner portion provided on the side of the body portion, and the water is evaporated by the combustion gas of high heat generated by the flame provided by the burner portion. Steam is generated, where heat transfer between the combustion gas and the water is accomplished by heat exchange with the water filled outside the tube as the combustion gas passes through the tube.

However, the conventional marine boiler has a problem that the heat transfer efficiency is lowered by using a tube having a conventional structure when heat exchange of the combustion gas and water.

Therefore, the conventional marine boiler needs more tubes to increase the heat transfer efficiency during the heat exchange of the combustion gas and water, and also because the downcomer is installed inside the body portion, the volume of the boiler increases. The problem is that the installation cost is increased.

The present invention has been made to solve the above problems, by configuring the bank tube in the boiler to improve the heat exchange performance, by reducing the number of bank tubes installed in the body portion to reduce the volume and at the same time inside the boiler The purpose is to provide a two-drum type marine boiler with improved heat exchange performance.

In order to achieve the above object, the present invention provides a body portion in which a plurality of bank tubes are built, a water drum provided at a lower portion of the body portion and storing water, and a steam generated from the water provided at the upper portion of the body portion. And a burner part for supplying flame to the inside of the body part, and the bank tube communicates with the steam drum by evaporating the water in the water drum by the heat supplied by the flame of the burner part. Provided is a two-drum type marine boiler, characterized in that a plurality of heat dissipation fins are formed to protrude to increase the heat exchange area to increase the heat exchange performance.

In the present invention, the heat radiating fins are formed radially protruding along the outer surface of the bank tube, it is characterized in that the bent in the direction of the combustion gas.

In addition, the present invention, the precipitation pipe for recovering the water condensed in the steam drum to the water drum is arranged on the outside of the body portion, the steam drum and the water drum is characterized in that the structure having an elliptical cross-section do.

The 2-drum type marine boiler according to the present invention can reduce the volume by reducing the number of bank tubes in the body compared to the existing marine boiler and at the same time maintain or improve the heat exchange performance inside the boiler at the same level as the existing boiler. In addition, since the precipitation pipe is arranged outside the body portion, there is an effect of reducing the overall volume of the boiler.

1 is a view showing a two-drum type marine boiler according to an embodiment of the present invention.
2 is a cross-sectional view taken along AA of FIG. 1.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

As shown in FIG. 1, the two-drum type marine boiler according to an embodiment of the present invention has a body portion 1 having a space therein and a flame inside the body portion 1. It comprises a burner portion 2 for providing, and a steam drum 4 and a water drum 3, which are respectively formed on the upper and lower portions of the body portion 1, and the like.

The body portion 1 is a component having a space of a predetermined volume, and is divided into left and right sides by a division wall tube 7 crossing the body portion 1 up and down, respectively. And the combustion chamber 8 are formed.

The burner part 2 is provided in the outer wall surface of the body part 1 of the upper part of the combustion chamber 8, and the combustion chamber of high heat is formed by the oil fuel supplied from the burner part 2 in the combustion chamber 8 .

Since the evaporator 9 is adjacent to the combustion chamber 8 with the division wall tube 7 interposed therebetween, the evaporator 9 is heated by the high heat of the combustion gas introduced between the division wall tube 7.

A plurality of bank tubes 5 are installed in the evaporator 9 of the body 1, and the bank tubes 5 communicate the water drum 3 and the steam drum 4 with water. It serves to vaporize the water introduced from the drum (3).
The bank tube 5 is a tube extending linearly up and down as shown in Figure 1, by connecting the lower surface of the steam drum 4 and the upper surface of the water drum 3 to each other, the steam drum (4) is supported.

The bank tube 5 is heated by the high-temperature combustion gas generated in the combustion chamber 8 to vaporize the water in the water drum 3 contained therein, and the generated steam is pressured inside the bank tube 5. It is raised by the flow into the upper steam drum (4).

That is, the bank tube 5 heats and vaporizes the water in the water drum 3 by heat exchange between the water contained therein and the combustion gas which is an external heat source.

The water drum 3 is a component in which water for steam generation is stored, which is provided at the lower part of the body 1, and the steam drum 4 receives steam generated from the water of the water drum 3. It is provided on the upper portion of the body portion 1 as a component for.

In addition, the bank tube 5 has a plurality of heat dissipation fins 6 protrudingly formed on the outer surface of the bank tube 5 to extend the heat exchange area. It will increase performance.

The heat dissipation fins 6 may improve the heat exchange performance of the bank tube 5 by releasing low heat of water introduced into the bank tube 5 and absorbing the high heat of the combustion gas delivered from the combustion chamber 8.

In addition, the heat dissipation fins 6 may protrude radially along the outer surface of the bank tube 5, and flow into the division wall tubes 7 disposed between the evaporator 9 and the combustion chamber 8. It may be provided to maximize the thermal contact area by bending in the traveling direction of the combustion gas.

The steam drum 4 may condense steam as the vapor evaporated from the bank tube 5 continues to flow, and thus the water condensed in the steam drum 4 flows back to the water drum 3. Precipitation pipe 10 for recovering is configured to be disposed outside the body portion (1).
In the present embodiment, the steam drum 4 and the water drum 3 are long containers extending along the first central axis C1. The steam drum 4 and the water drum 3 have a long axis along the first central axis C1 to withstand high pressure. Is formed to have an elliptical planar structure, and are disposed on the upper and lower portions of the body portion 1 in a state facing each other.
In the present embodiment, the body portion 1 is formed to have a rectangular planar structure extending long along the second central axis C2 perpendicularly intersecting the first central axis C1.
In the present embodiment, the division wall tube 7 is a tube extending vertically long and arranged along a plurality of third central axis (C3) parallel to the first central axis (C1), the body portion (1) is divided left and right by the division wall tube (7) and the evaporator (9) and the combustion chamber (8) are respectively formed therein.

The precipitation pipe 10 is installed in a structure in which the steam drum 4 and the water drum 3 communicate with each other, and the water condensed in the steam drum 4 is attached to the water drum 3 by flowing by its own weight. As shown in FIG. 1, the part connected to the steam drum 4 is composed of an obliquely inclined U-shaped pipe.
The precipitation pipe 10 is a tube extending vertically and long, and as shown in FIG. 2, a fourth center parallel to the first central axis C1 and disposed close to the first central axis C1. It is arranged outside the left short side of the said body part 1 along the axis C4.

In addition, the marine boiler according to the present invention distributes the load by configuring the steam drum 4 and the water drum 3 having the largest pressure load among the components constituting the same in an elliptical planar structure so that the pressure load is concentrated. By removing the part, the durability can be increased.
In the present embodiment, the steam drum 4 and the water drum 3 are disposed at the upper and lower portions of the evaporator 9 at the left end of the body 1 as shown in FIGS. 1 and 2. Each is arranged.

Referring to the series of operating processes for generating steam in the two-drum type marine boiler of the present invention configured as described above are as follows.

First, the heat of combustion of the combustion gas of the combustion chamber 8 generated by the combustion of the oil fuel supplied from the burner unit 2 is transferred to the water inside the bank tube 5 to generate steam having a high temperature and pressure. The high temperature and high pressure steam enters the steam drum 4 by the pressure.

That is, the bank tube 5 vaporizes the water introduced from the water drum 3 by the heat of the combustion gas by the flame of the burner part 2 burned in the combustion chamber 8, and the steam thus generated is Ascends into the steam drum 4 and is supplied to the steam use place through the steam discharge pipe 12 installed on the steam drum 4.

The combustion gas is heated from the combustion chamber 8 via the evaporator 9 to heat the water in the bank tube 5, and then discharged to the outside through the exhaust duct 11 provided at the upper end of the body 1. .

1: Body 2: Burner
3: water drum 4: steam drum
5: bank tube 6: heat dissipation fin
7: division wall tube 8: combustion chamber
9: evaporation unit 10: precipitation pipe
11: exhaust duct 12: steam discharge tube

Claims (4)

delete delete The body portion 1 is provided with a plurality of bank tubes (5), the water drum (3) is provided in the lower portion of the body portion 1 and the water is stored, and the upper portion of the body portion (1) A steam drum 4 into which the steam generated from the water flows, and a burner part 2 for supplying a flame into the body part 1, and the bank tube 5 is supplied by the flame of the burner part. In the two-drum type marine boiler in which a path of evaporating water of the water drum (3) by hot air to the steam drum (4) and a plurality of banded heat dissipation fins (6) radially protruding from the outer surface thereof,
A downcomer 10 for recirculating the water condensed in the steam drum 4 to the water drum 3 is arranged outside the body 1;
The steam drum 4 and the water drum 3 are containers extending long along the first central axis C1. The steam drum 4 and the water drum 3 are elliptical planes having the first central axis C1 as long axes to withstand high pressure. Is formed to have a structure, and are disposed on the upper and lower portions of the body portion 1 in a state facing each other,
The body portion 1 is formed to have a rectangular planar structure extending along a second central axis C2 that intersects the first central axis C1, and the first central axis C1. A plurality of sidewalls are arranged along the third center axis (C3) side by side and divided by left and right by a division wall tube (7) extending up and down, the evaporator (9) and the combustion chamber (8) are formed therein, respectively.
The precipitation pipe 10 is a pipe extending vertically along the first central axis (C1) along the fourth central axis (C1) arranged in close proximity to the first central axis (C1) It is arranged outside the short side of the body portion 1,
The steam drum 4 and the water drum 3 are disposed above and below the evaporator 9, respectively.
The bank tube 5 is a tube extending vertically up and down to support the steam drum 4 by connecting the lower surface of the steam drum 4 and the upper surface of the water drum 3 to each other. A two-drum type marine boiler. delete

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