KR100724601B1 - Condesing boiler - Google Patents

Abstract

A condensing boiler is provided to prevent clogging of a core by frequently checking the operation of a condensed water trap. A condensing boiler includes a burner(100); a heat exchange unit(200) for heat exchange between the combustion gas generated from the burner and heating water; an outer casing(260) for accommodating the burner and the heat exchange unit; and a condensed water trap unit(400) for collecting condensed water generated during heat exchange of the combustion gas. The condensed water trap unit includes a trap pipe(420) coupled to an outer surface of the outer casing and coupled to a duct(410) arranged beneath the heat exchange unit; and a condensed water trap(412) coupled to the trap pipe. The duct has a bottom with a tilt surface formed toward a portion to be coupled to the trap pipe. The condensed water trap unit includes a heat insulation member for preventing the condensed water contained in the condensed water trap from freezing.

Description

Condensate latent heat recovery boiler

1 is a schematic view showing a conventional latent condensation recovery boiler.

2 is a cross-sectional view showing an embodiment of a latent heat recovery condensate boiler according to the present invention.

3 is a partial cross-sectional view showing a condensate trap in the embodiment shown in FIG.

Figure 4 is a cross-sectional view showing another embodiment of the latent heat recovery condensate boiler according to the present invention.

<Description of main parts of drawing>

100: burner 110: intake and exhaust device

200: heat exchanger 210: association

220: hot water supply coil 230: heating sink chamber

240: reverse duct 250: reverse connection

260: jacket 400: condensate trap

410: duct 420: trap pipe

430: connection portion 440: switchgear

450: condensate confirmation window 500: water pump

The present invention relates to a latent heat recovery boiler for condensate, and more particularly, to a condensate latent heat recovery boiler in which a condensate trap for storing condensate is mounted on an outer surface of the outer shell and the condensate trap is detached.

In general, a boiler may be classified into a condensation latent heat recovery boiler (condensing) and a non-condensing type in which the exhaust gas temperature is lower than the dew point according to the temperature of the exhaust gas. The condensed latent heat recovery boiler was developed to prevent heat loss as much as possible by absorbing latent heat of steam components in the combustion gas in order to increase thermal efficiency.

Figure 1 is a schematic diagram schematically showing a conventional condensation latent heat recovery boiler.

As shown in Figure 1, the condensation latent heat recovery boiler is a blower fan 12 is coupled to the inner top of the main body to suck air from the outside.

A burner 13 is connected to the blowing fan 12. The burner 13 generates a flame 14 by burning air and fuel supplied from the blowing fan 12.

The heat exchanger 15 is mounted to the lower end of the burner 13. The water is provided inside the heat exchanger 15 to circulate and is converted into water from low temperature water to high temperature water by the flame 14 of the burner 13 to be used as ondol water or hot water.

In addition, since the heat exchanger 15 at the bottom which is not directly exposed to the flame 14 of the burner 13 is in contact with the hot combustion gas, heat exchange occurs. At this time, when the temperature of the combustion gas is lowered, condensed water is generated outside the heat exchanger 15 due to the combustion gas below the dew point. The combustion gas is discharged through the exhaust duct 17, and the condensate is stored through the condensate trap 18 connected to the exhaust duct 17. A certain amount of condensate is stored in the condensate trap 18, and the excess condensate is discharged out of the main body through the drain pipe 16.

However, the condensate latent heat recovery boiler is difficult to visually inspect the condensate trap from time to time because the condensate trap is mounted inside the main body, due to which there is a problem that can not be cleaned from time to time durability.

The present invention was created in order to solve the above problems, and provides a condensate latent heat recovery boiler that can be visually inspected from time to time by mounting a condensate trap of the latent heat recovery condensate boiler.

Condensate latent heat recovery boiler according to the present invention for realizing the above object, the burner; A heat exchanger configured to heat-exchange the combustion gas generated from the burner with heating water or hot water; An outer shell accommodating the burner and the heat exchanger; And a condensate trap unit configured to collect condensate generated when the combustion gas is heat-exchanged. Coupled trap pipes; And a condensate trap coupled to the trap pipe, wherein an inclined surface is formed on a bottom surface of the duct to engage with the trap pipe, and includes a heat insulating material to prevent the condensate inside the condensate trap from being frozen. . In the present specification, the heating water refers to a liquid for heating a predetermined space, and the hot water supply refers to hot water supplied through a water pipe, for example, bath water.

Wherein the condensate trap portion trap pipe coupled to the duct mounted on the heat exchanger lower; Condensed water trap coupled to the trap pipe; including, wherein the bottom surface of the duct preferably comprises a slope toward the portion coupled to the trap pipe.

In addition, the condensate trap is preferably characterized in that the condensate confirmation window is formed that can check the contents on one side. This condensate confirmation window allows visual confirmation of the condensate inside the condensate trap.

Alternatively, the condensate trap is preferably formed of a transparent member or a semi-transparent member that can check the contents on one side. The transparent member and the translucent member allow visual inspection of the condensate inside the condensate trap and the internal condition of the condensate trap.

In addition, the condensate trap is preferably characterized in that the trap pipe and the condensate trap is detachably coupled. This removable function allows for easy repair of the condensate trap.

In addition, the condensate trap is preferably characterized in that it comprises a switchgear detachable to one side. This switch allows the insertion of a brush to clean the inside of the condensate trap.

In addition, it is preferable to include a heater for preventing the condensed water inside the condensate trap is frozen.

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Here, the burner is preferably characterized in that it comprises a downward combustion type mounted on the inner upper end of the shell.

Here, the heat exchanger is preferably characterized in that it comprises a low-temperature heat exchanger.

Figure 2 is a cross-sectional view showing an embodiment of the condensate latent heat recovery boiler according to the present invention, Figure 3 is a partial cross-sectional view showing a condensate trap in the embodiment shown in Figure 2, Figure 4 is a latent heat recovery of condensate in accordance with the present invention Sectional view showing another embodiment of a boiler.

2 or 3 in parallel, a preferred embodiment of the condensate latent heat recovery boiler according to the present invention is a burner 100 for generating heat, and to transfer the heat of combustion of the burner 100 to heating water or hot water It includes a heat exchanger 200, an outer shell 260 for accommodating the burner 100 and the heat exchanger 200, and a condensate trap unit 400 coupled to the outside of the outer shell 260.

The burner 100 may be mounted on an upper end of the outer shell 260 and configured as a downward combustion type that emits combustion gas downward.

The heat exchanger 200 is mounted at the lower end of the burner 100. The heat exchange part 200 is a heating chamber 230 formed between the association 210, the association 210, and the hot water supply coil 220 disposed in a form surrounding the association (210) Include.

The association 210 is located at the bottom of the burner 100. The tube 210 is a pipe through which combustion gas combusted in the burner 100 moves, and when the combustion gas moves to the tube 210, the tube 210 is formed between the shell 260 and the tube 210. The high temperature heat is transferred to the heating chamber 230. Therefore, the water circulating in the heating chamber 230 is changed from the low temperature water to the high temperature water. That is, the water introduced into the first pipe 510 by the water pump 500 is introduced into the heating water chamber 230 again, and at this time, the water is changed from the low temperature water to the high temperature water to replace the second pipe 520. Through the room. The combustion gas is discharged to the outside through the exhaust duct 470 coupled to the duct 410.

성분이 포함되는데, 배기가스가 노점이하로 되는 응축잠열 회수보일러 특징상

성분은 액체 상태의 응축수가 되고, 이때의 응축수는 도2에 도시된 화살표의 방향에 따라 이동된다. On the other hand, the combustion gas generated by the combustion of hydrocarbon material

Component, which is characterized by the latent heat recovery boiler

The component becomes condensate in the liquid state, at which time the condensate is moved in the direction of the arrow shown in FIG.

 The hot water supply coil 220 is connected to the third pipe 530, and the water introduced by the third pipe 530 transfers heat from the pipe 210 and the heating sink 230. Therefore, the water of the hot water supply coil 220 is changed from the low temperature water to the high temperature water and flows back into the fourth pipe 540. As such, the method of heating the hot water supply water through the heating water without directly exchanging the hot water with the hot water supply water is called a low temperature heat exchange method.

The condensate trap unit 400 is mounted to the outside of the shell 260. The condensate trap unit 400 includes a trap pipe 420 coupled to the duct 410 mounted under the heat exchange unit 200, and a condensate trap 412 coupled to the trap pipe 420.

 The trap pipe 420 is equipped with a condensate trap (412). The condensate trap 412 is connected to the trap pipe 420 is mounted to the outside of the shell 300. Here, the condensate trap 412 is formed of a transparent member or a translucent member to visually identify the inside. In addition, a condensate check window 450 may be formed at the center of the condensate trap 412 to check the condensate level. And the upper and lower ends of the condensate trap 412 is formed with a connection portion 430 that can be attached and detached the condensate trap 412, respectively. By providing the connection portion 430 as described above, the condensate trap 412 can be visually inspected and detachable for cleaning or maintenance. In addition, the opening and closing device 440 is mounted on one side of the condensate trap 412 to form a lid or stopper for cleaning. The opening and closing device 440 can be opened and closed at any time to finish the visual inspection by the condensate check window 450 or the transparent member, and after opening and closing the opening and closing device 440 to insert a brush into the inlet to the condensate trap ( 412 is formed to clean the interior. Since the condensate trap 412 is mounted on the outer side of the outer shell 300 to prevent freezing of the condensate in winter, the condensate trap 412 surrounds the insulation 470 on the outside of the condensate trap 412 to maintain a constant temperature. The condensate is prevented from freezing inside the trap 412. In addition, a heater 460 may be provided at one side of the condensate trap 412 as a method for preventing freezing of the condensate trap.

Referring to Figure 4, another preferred embodiment of the latent heat recovery condensate boiler according to the present invention is an intake and exhaust device 110 is mounted on the bottom of the inner shell 260 and the burner coupled to the top of the intake and exhaust device (110) ( A trap pipe 420 coupled with a heat exchanger 200 positioned at an upper end of the burner 100, a duct 410 mounted at a lower end of the heat exchanger 200, and the trap pipe 420. Condensate trap 412 is coupled to include).

The burner 100 is mounted on the upper end of the intake and exhaust device 110. The burner 100 may be mounted to the bottom of the shell 260 and may be configured as an upward combustion type for releasing combustion gas to the upper end by burning the intake air and the fuel of the intake and exhaust device 110.

The heat exchanger 200 is positioned above the burner 100. The heat exchange part 200 is a heating sink chamber 230 formed between the association 210 and the association 210, the reverse duct 240 formed on the heating sink chamber 230, And an inverted tube 250 connected to the inverting duct 240 and a hot water supply coil 230 disposed to surround the inlet 210.

The association 210 is located at the top of the burner 100. The associator 210 moves the combustion gas generated from the lower end to the upper portion of the pipe through which the combustion gas generated from the burner 100 moves. And the combustion gas is dispersed by the inverting duct 240 formed on the upper end of the association 210, the dispersed combustion gas is downward through the inversion tube (250). The combustion gas is collected in the duct 410 and discharged to the intake and exhaust device 110. In addition, a certain amount of condensate is stored in the condensate trap 412.

Parts not described below are the same as described in the above embodiment, and detailed descriptions are omitted since they are known products.

The condensate latent heat recovery boiler according to the present invention has been described above. It will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will be belong to the claims of the present invention.

The condensate latent heat recovery boiler according to the present invention, which is operated and configured as described above, has a condensate trap attached to the outside so that visual inspection of the condensate trap can be performed at any time, thereby preventing the core from clogging through cleaning and repairing. .

Claims (10)

delete burner; A heat exchanger configured to heat-exchange the combustion gas generated from the burner with heating water or hot water; An outer shell accommodating the burner and the heat exchanger; In the latent heat recovery boiler comprising: a condensate trap unit for collecting condensate generated when the combustion gas heat exchange; The condensate trap unit, the trap pipe is coupled to the outside of the outer shell, and coupled to the duct mounted on the lower portion of the heat exchanger; And a condensate trap coupled to the trap pipe, the bottom surface of the duct having an inclined surface toward the portion coupled to the trap pipe, Condensate latent heat recovery boiler, characterized in that it comprises a heat insulating material to prevent the condensate inside the condensate trap is frozen. The method of claim 2, In the condensate trap, Condensate latent heat recovery boiler, characterized in that the condensate confirmation window formed on one side to check the contents. The method of claim 2, The condensate trap is, Condensate latent heat recovery boiler, characterized in that formed on one side of the transparent member or semi-transparent member that can check the contents. The method of claim 2, Condensate latent heat recovery boiler, characterized in that the trap pipe and the condensate trap is detachably coupled. The method of claim 2, The condensate trap is, Condensate latent heat recovery boiler, characterized in that it comprises a switchgear detachable on one side. delete The method of claim 2, Condensate latent heat recovery boiler, characterized in that it comprises a heater to prevent the condensate inside the condensate trap freezing. The method of claim 2, The burner is, Condensate latent heat recovery boiler, characterized in that the down combustion burner mounted on the inner upper end of the shell. The method of claim 2, The heat exchanger, Condensate latent heat recovery boiler, characterized in that the low-heat type heat exchanger.

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