KR101301366B1 - Flow-through boiler - Google Patents

Abstract

The present invention relates to a once-through boiler, and more particularly, to a once-through boiler arranged in a multi-tubular manner to maximize the heat exchange efficiency of the heat exchange tube through which the combustion gas passes.
That is, the present invention is installed in the boiler body to burn the flame of the burner, the upper and lower chambers are installed at regular intervals in the upper and lower, and the upper and lower chambers vertically connected to the plurality of pipes Is composed of a heat exchanger tube arranged in an annular shape, the heat exchanger tube is provided as an internal and external heat exchanger tube, and then a watering unit is formed between the internal and external heat exchanger tube to communicate with upper and lower chambers and the combustion gas passage of the internal heat exchanger tube. A spiral guide plate is provided to allow the combustion gas to be transported in turn, and the flue gas is discharged through a combustion gas return chamber formed above the upper chamber and a heat exchange chamber formed between the upper and lower chambers in the upper chamber. Characterized in a once-through boiler consisting of.

Description

Flow-through boilers

The present invention relates to a once-through boiler, and more particularly, to a once-through boiler arranged in a multi-tubular manner to maximize the heat exchange efficiency of the heat exchange tube through which the combustion gas passes.

In general, a perfusion boiler forms a flue on one side of the casing, and installs upper and lower chambers at upper and lower intervals at regular intervals, and annularly heat-exchange tubes having a plurality of tubular bodies perpendicular to the upper and lower chambers. Each of them is arranged so that the combustion gas of the combustion chamber passes through the combustion gas passage of the heat exchanger tube and then is discharged to the flue of one side of the casing via the upper flow chamber.

However, in the case of a plurality of perfusion boilers including Patent No. 10-1042564 disclosed in the prior art, a plurality of tubular heat exchange tubes are used to heat a large amount of water at once, so that the combustion gas passage of the heat exchange tube is used. As the heat exchange efficiency decreases due to the contact of the combustion gas passing through, and the water boiling time takes longer to warm up, it costs a lot of fuel costs, and it also takes a lot of time to raise the temperature of the water and adds to the economic burden. There was a problem.

The present invention has been made in order to solve this problem, the upper and lower chambers are installed at regular intervals inside the boiler body, and each of the heat exchange tubes made of a plurality of pipes perpendicular to the upper and lower chambers annularly The heat exchanger tube is disposed as an inner and an outer heat exchanger tube to form a watering part between the inner and outer heat exchanger tubes, and the water of the irrigation part contacts the inner wall surface of the inner heat exchanger tube and the outer wall surface of the outer heat exchanger tube. The present invention provides a perfusion boiler to increase the heat transfer area and to maximize the heat exchange efficiency by installing a spiral guide plate in the combustion gas passage of the internal heat exchanger tube to increase the contact efficiency of the combustion gas by the spiral guide plate.

The present invention is installed in the boiler body and the combustion chamber to burn the flame of the burner, and the upper and lower chambers and the upper and lower chambers installed at regular intervals in the upper and lower, and vertically connected to the upper and lower chambers, a plurality of pipes annular It consists of a heat exchanger tube disposed in the heat exchanger tube is provided as an internal, external heat exchanger tube, and then formed a water pipe between the internal and external heat exchanger tube to communicate with the upper and lower chambers, and combustion in the combustion gas passage of the internal heat exchanger tube The spiral guide plate is installed to allow the gas to be transported by turns, and the flue gas is composed of a flue gas discharge chamber formed in an upper side of the upper chamber and a flue gas discharged through a heat exchange chamber formed between the upper and lower chambers. It features a once-through boiler.

The outer end portion of the pivoting portion of the spiral guide plate is characterized in that the heat conduction is made in contact with the inner wall surface of the inner heat exchange tube.

A plurality of irregularities are formed on the surface of the spiral guide plate installed in the combustion gas passage of the internal heat exchange tube.

Characterized in that by installing a spiral guide plate in the interior of the flue exhaust gas from the heat exchange chamber to the outside.

In the flow-through boiler of the present invention, when combustion generated by the flame of the combustion chamber is transferred to the flow chamber through the combustion gas passage of the internal heat exchanger tube, the water of the irrigation unit is primarily heated by the means for heating the inner wall surface of the internal heat exchanger tube. As the combustion gas flows from the return chamber to the heat exchange chamber, it is a means of heating the outer wall surface of the external heat exchanger tube located in the heat exchange chamber and installed between the upper and lower water chambers. In addition, the contact force of the combustion heat of the combustion gas to heat the inner wall surface of the internal heat exchanger tube, while greatly extending the time of staying in the combustion gas passageway when it is turned to the circulating chamber while turning by the spiral guide plate installed in the combustion gas passage of the internal heat exchanger tube. By greatly improving the efficiency of heat exchange can be maximized and has a very economic effect.

1 is a longitudinal sectional view showing an entire configuration embodiment of a once-through boiler according to the present invention.
Figure 2 is an enlarged partial cross-sectional view showing the configuration of the heat exchange tube portion in the perfusion boiler according to the present invention.
Figure 3 is an exemplary cross-sectional view showing the configuration of the once-through boiler according to the present invention.
Figure 4 is a longitudinal cross-sectional view showing the whole configuration embodiment in the perfusion boiler according to the present invention.
Figure 5 is a partially cut perspective view showing a heat exchange tube portion in a perfusion boiler according to the present invention.
Figure 6 is a perspective view of the spiral guide plate in the perfusion boiler according to the present invention.
7 is a perspective view showing a spiral guide plate of another embodiment in a perfusion boiler according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The perfusion boiler according to the present invention is to heat the water flowing through the inlet 11 by the combustion gas generated by the flame of the burner 22 to supply hot water or steam through the outlet 12. The heat exchanger tube 40 through which the combustion gas passes in the boiler body 10 is arranged in a multi-pipe type to maximize the heat exchange efficiency.

In the perfusion boiler, the combustion chamber 20 installed in the boiler body 10 to burn the flames of the burner, and the upper and lower water chambers 30 and 30 'installed at regular intervals in the upper and lower portions, and The heat exchanger tube 40 is vertically connected to the upper and lower water chambers 30 and 30 'and has a plurality of pipes arranged in an annular shape, but the heat exchanger tube 40 is an internal or external heat exchanger tube 40a or 40b. Next, the water supply unit 42 is formed between the inner and outer heat exchanger tubes 40a and 40b so as to communicate with the upper and lower water chambers 30 and 30 'and the combustion gas of the inner heat exchanger tube 40a. The spiral guide plate 50 is installed in the passage 44 so that the combustion gas is pivoted and transported, and the combustion gas return chamber 60 formed above the upper water chamber 30 and in the return chamber 60. It consists of flue 80 through which the combustion gas is discharged through a heat exchange chamber 70 formed between upper and lower water chambers 30 and 30 '.

In the present invention, when the combustion gas generated by the flame of the combustion chamber 20 is transferred to the flow chamber 60 through the combustion gas passage 44 of the internal heat exchange tube 40a, the inner wall surface of the internal heat exchange tube 40a. Primary water is heated in the water supply part 42 by means of heating the combustion gas from the circulating chamber 60 to the heat exchange chamber 70 while being located in the heat exchange chamber 70 and the upper and lower water chambers 30. As a means for heating the outer wall surface of the external heat exchanger tube 40b provided between the 30 ', the heat exchanger efficiency is increased by the secondary heating of the water in the irrigation unit 42.

The combustion gas generated by the flame of the combustion chamber 20 is rotated by the spiral guide plate 50 installed in the combustion gas passage 44 of the internal heat exchanger tube 40a, and then is burned when the combustion gas is transferred to the flow chamber 60. In addition to greatly extending the time of staying in the gas passage 44, the heat of combustion of the combustion gas greatly improves the contact force for heating the inner wall surface of the internal heat exchange tube 40a, thereby enabling heat exchange.

The outer end portion of the pivoted portion of the spiral guide plate 50 installed in the combustion gas passage 44 of the internal heat exchanger tube 40a is in contact with the inner wall surface of the internal heat exchanger tube 40a and is integrally installed. As the combustion gas is rotated, the heating temperature of the spiral guide plate 50, which is heated by being in contact with the spiral guide plate 50, is preferably configured to allow thermal conductivity to occur on the inner wall surface of the internal heat exchange tube 40a.

This is because the combustion gas is naturally transported through the combustion gas passage 44 of the internal heat exchange tube 40a while the combustion gas is pivotally transferred by the spiral guide plate 50 installed in the combustion gas passage 44. Heating temperature of the spiral guide plate 50 which is heated in contact with the heat conduction to the internal heat exchange tube (40a) is a means for heat-exchanging the water of the irrigation portion 42 to further increase the heat exchange efficiency.

At this time, the outer end portion of the spiral guide plate 50 installed in the combustion gas passage 44 of the internal heat exchange tube 40a is bent to contact the inner wall surface of the internal heat exchange tube 40a. ) And the inner wall surface of the inner heat exchanger tube 40a to increase the contact force can be made easier.

In addition, a plurality of uneven parts 52 are formed on the surface of the spiral guide plate 50 for enlarging the heat exchange cross-sectional area by the spiral guide plate 50 installed in the combustion gas passage 44 of the internal heat exchange tube 40a. It is formed to increase the contact area of the combustion gas of the spiral guide plate 50 by the concave-convex portion 52 to increase the thermal efficiency of the heat conduction heat exchanged by the internal heat exchange tube (40a) in the spiral guide plate 50.

In the present invention, a spiral guide plate 50 'is also installed inside the flue 80 where the combustion gas is discharged from the heat exchange chamber 70 to the outside so that the combustion gas stays in the heat exchange chamber 70 as much as possible. In contact with the outer wall tube of the pipe 40b to heat exchange the water in the watering part 42 can maximize the heat exchange efficiency.

While the present invention has been described with reference to the exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: boiler body 11: inlet
12: outlet 20: combustion chamber
22: burner 30,30 ': sink
40: heat exchanger tube 40a, 40b: internal and external heat exchanger tube
42: watering part 44: combustion gas passage
50,50 ': spiral guide plate 52: uneven portion
60: flow chamber 70: heat exchange chamber
80: year

Claims (4)

The combustion chamber 20 installed in the boiler main body 10 to burn the flame of the burner 22, and the upper and lower water chambers 30 and 30 'installed at regular intervals in the upper and lower parts, and the upper and lower chambers. , It is made of a heat exchanger tube 40 vertically connected to the lower chambers 30, 30 'and a plurality of pipes are annularly arranged,
The heat exchanger tube 40 is provided with internal and external heat exchanger tubes 40a and 40b, and then a watering unit 42 is formed between the internal and external heat exchanger tubes 40a and 40b to allow the upper and lower water chambers 30 to be formed. To communicate with (30 '),
While installing the spiral guide plate 50 to the combustion gas passage 44 to the combustion gas passage 44 of the internal heat exchange tube (40a) to increase the heat exchange efficiency by extending the time the combustion gas stays,
The outer end portion of the spiral guide plate 50 that is pivoted is integrally installed in close contact with the inner wall surface of the internal heat exchanger tube 40a so that the temperature of the heated spiral guide plate 50 is increased. Heat conduction to the inner wall,
The surface of the spiral guide plate 50 is formed with a plurality of irregularities 52 to increase the contact area between the spiral guide plate 50 and the combustion gas, the temperature of the heated spiral guide plate 50 is a heat exchange tube Heat conduction at 40a,
Combustion gas via the combustion gas return chamber 60 formed above the upper water chamber 30 and the heat exchange chamber 70 formed between the upper and lower water chambers 30 and 30 'in the return chamber 60. Perfusion boiler, characterized in that by installing a spiral guide plate (50 ') inside the flue 80 is discharged.









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