KR102501785B1 - Boiler with Water Discharge Function - Google Patents

Abstract

The present invention relates to a boiler having a rainwater discharge function that allows rainwater flowing into an exhaust pipe to be discharged to the outside, and since a discharge pipe is connected to the lower part of the air supply pipe, the rainwater flowing into the air supply pipe is guided toward the drain part. , there is an effect of easily discharging water from the air supply pipe to the outside.

Description

Boiler with rainwater discharge function {Boiler with Water Discharge Function}

The present invention relates to a boiler having a rainwater discharge function, and more particularly, to a boiler having a rainwater discharge function to discharge rainwater flowing into an air supply pipe to the outside.

In general, gas boilers are used for heating by using gas as fuel and water as heat medium, and in the case of hot water boilers, heating circulation water is circulated inside the boiler through a three-way valve, and hot water is also available by heating feed water in the form of indirect heat exchange. it is a burner Gas boilers are installed in various buildings such as homes, offices or factories and are configured to supply hot water or heating water. They can be divided into general boilers and condensing boilers depending on whether condensate is generated, and instantaneous boilers and It can be classified as a storage boiler.

Looking at the basic structure of such a gas boiler, a combustion device and a heat exchanger are provided inside the housing. The combustion device is a space in which the flame of fuel, that is, gas, is burned in the form of a free flame having an appropriate length. Afterwards, the combustion gas coming out of the combustion device exchanges heat with a heating medium in a heat exchanger and passes through a communication and supply/exhaust pipe to the outside. It is composed of a structure that is discharged into

1 is a view showing a supply and exhaust pipe connected to a conventional boiler. Referring to FIG. 1, a conventional air supply and exhaust pipe includes an air supply pipe 10 formed to have a relatively large diameter and an exhaust pipe 30 formed along the inside of the air supply pipe 10 and formed to have a relatively small diameter. do.

One end of the exhaust pipe 30 is connected to the communication pipe 40 of the boiler, and the other end of the exhaust pipe 30 is formed to protrude outward from the air supply pipe 10 . A plurality of exhaust holes 31 are formed at the outer periphery of the other end of the exhaust pipe 30, and the combustion gas exhausted through the communication 40 is discharged to the outside through the exhaust holes 31. One end of the air supply pipe 10 is connected to the air supply pipe 13 of the boiler, and the other end of the air supply pipe 10 is formed long along the exhaust pipe 30 and exposed to the outdoors. A plurality of air supply holes 11 are formed at the outer periphery of the other end of the air supply pipe 10, and external air is supplied to the air supply pipe 13 connected to the burner of the boiler through the air supply holes 11.

Meanwhile, since the other end of the air supply pipe 10 is exposed to the outdoors, when it rains, rainwater may flow into the air supply pipe 10 through the air supply hole 11 . Rainwater introduced into the air supply pipe 10 is introduced into a burner inside the boiler through the air supply pipe 10, causing various problems such as burner corrosion and heat exchange efficiency deterioration.

Korean Patent Publication No. 10-2013-0125427

An object of the present invention to solve the problems of the prior art as described above is to provide a boiler having a rainwater discharge function that allows rainwater introduced into the air supply pipe to be discharged to the outside.

In order to achieve the above object, the present invention provides a casing having an air supply unit and an exhaust unit on the upper side and a drain unit on the lower side, and is located inside the casing and combusts using air supplied from the air supply unit and fuel supplied from the outside. In a boiler having a combustion device and a heat exchanger for exchanging heat between combustion gas discharged from the combustion device and a heating medium, it is formed in a long shape along the longitudinal direction, one end is connected to the air supply part and the other end is formed with an air supply hole air supply; An exhaust pipe formed along the inside of the air supply pipe, one end of which passes through one end of the air supply pipe and is connected to the exhaust pipe, and the other end protrudes outward through the other end of the air supply pipe; And a discharge pipe formed in a tubular shape, one end of which is connected to the lower end of the air supply pipe in a penetrating state, and the other end includes a discharge pipe extending to the drain through the inside of the casing, and protrudes to the outside of the air supply pipe. An exhaust hole is formed at the other end of the exhaust pipe, and water flowing into the air supply pipe is discharged to the drain part through the discharge pipe.

In addition, the drain part is formed in the form of a column, and the upper end is installed at the lower end of the heat exchanger and the lower end extends downward, an outer tube, a lid for closing the lower end of the outer tube, and the inside of the outer tube. The upper end is connected to the upper end of the outer tube, the lower end extends downward of the outer tube, and the inner tube is positioned to be spaced apart from the top of the lid, and one end is located on one side between the upper end and the lower end of the inner tube. An internal connection pipe exposed to the outside of the outer pipe through one side of the outer pipe in a state in which it is communicated and the other end is inclined upward, and one end communicates with the other side between the upper end and the lower end of the outer pipe and is connected to the other end. An external connection tube having an end inclined upward and exposed to the outside of the external tube, and an exposure tube having one end connected to the other end of the external connection tube and the other end extending downward to be exposed to the lower portion of the casing. Including, the upper end of the inner pipe is connected to the lower end of the heat exchanger, the other end of the discharge pipe is connected to the inner pipe, condensate supplied from the heat exchanger to the inner pipe and the inner pipe The water supplied to the inner tube provides a boiler having a rainwater discharge function, characterized in that discharged to the exposure tube after being moved to the external connection tube through a gap between the inner tube and the cover.

In addition, the lower end of the internal connection pipe provides a boiler having a rainwater discharge function, characterized in that located lower than the lower end of the external connection pipe.

In addition, it provides a boiler having a rainwater discharge function, characterized in that it further comprises a discharge guide pipe connected to the external connection pipe, and a blower for discharging air to the discharge guide pipe.

In addition, the heat exchanger: a housing having a space portion formed therein and having an independent fire chamber above the space portion; a plurality of links, one side of which is connected to the lower surface of the firebox and the other side of which extends downward in the space; and an exhaust accommodating part provided at a lower part of the housing and connected to the fire pipe, and the combustion gas injected from the combustion device into the firebox moves along the inside of the fire pipe, heats the fire pipe, and then moves to the exhaust accommodating part. And, the lower part of the exhaust receiving portion is configured to communicate with the inner pipe, and provides a boiler having a rainwater discharge function, characterized in that the condensed water generated in the exhaust receiving portion is discharged to the inner pipe.

In addition, the exhaust hole is formed on the outer periphery of the other end of the exhaust pipe, and based on one end of the exhaust pipe, a closing portion for closing the open outlet of the other end of the exhaust pipe positioned farther than the exhaust hole And, the closing portion includes a central portion located at the center of the outlet and protruding in a conical shape toward one end of the exhaust pipe, and a rim portion interconnecting the outer periphery of the central portion and the inner periphery of the outlet, wherein the rim A plurality of auxiliary holes are formed in the portion, a part of the combustion gas moving along the exhaust pipe is exhausted through the exhaust hole, and another part of the combustion gas moving along the exhaust pipe is slid along the central part to be inclined. It provides a boiler having a rainwater discharge function, characterized in that discharged obliquely to the auxiliary hole.

Since the present invention is configured such that the discharge pipe is connected to the lower part of the air supply pipe, there is an effect of easily discharging water from the air supply pipe to the outside by guiding the water flowing into the air supply pipe toward the drain part.

In addition, since the drain part includes an inner tube and an outer tube, when the water level supplied to the inner tube and the outer tube rises to the exposure tube, the water filled in the inner tube and the outer tube flows downward along the exposure tube according to the siphon principle. It has the effect of being discharged quickly.

In addition, since the lower portion of the inner tube is normally filled with water, there is an effect of blocking gas or the like flowing backward through the exposure tube from being transmitted in the direction of the discharge tube.

In addition, since the lower end of the internal connection pipe is located lower than the lower end of the external connection pipe, the internal connection pipe is normally blocked by water, and accordingly, the air supplied through the air supply pipe cannot be moved in the direction of the inner pipe. , there is an effect that the air supplied through the air supply pipe is easily supplied to the combustion device.

In addition, since the combustion gas moving along the exhaust pipe is exhausted through the auxiliary hole as well as the exhaust hole, the combustion gas moving along the exhaust pipe can be rapidly exhausted to the outside through the exhaust hole and the auxiliary hole.

In addition, since the combustion gas discharged through the auxiliary hole is slanted along the central part and then discharged to the auxiliary hole obliquely, the combustion gas discharged through the auxiliary hole does not stay around the outlet of the exhaust pipe, so the combustion gas exhausted through the auxiliary hole is discharged to the exhaust pipe. It has the effect of not regurgitating again.

1 is a view showing a supply and exhaust pipe connected to a conventional boiler.
Figure 2 is a diagram schematically showing a boiler having a rainwater discharge function according to a preferred embodiment of the present invention.
Figure 3 is a view schematically showing a side cross-section of a boiler having a rainwater discharge function according to a preferred embodiment of the present invention.
FIG. 4 is a view illustrating a closing portion provided in a supply and exhaust member of a boiler having a rainwater discharge function according to a preferred embodiment of the present invention.
5 is a diagram illustrating a flow of combustion gas moving along the closure of a boiler having a rainwater discharge function according to a preferred embodiment of the present invention.
6 is a view for explaining a discharge pipe of a boiler having a rainwater discharge function according to a preferred embodiment of the present invention.
7 is a view showing a state in which the discharge pipe of the boiler having a rainwater discharge function according to a preferred embodiment of the present invention is coupled to the drain pipe.
8 is a diagram showing the flow of water moving in a drain pipe of a boiler having a rainwater discharge function according to a preferred embodiment of the present invention.

Hereinafter, a boiler having a rainwater discharge function according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

Figure 2 is a diagram schematically showing a boiler having a rainwater discharge function according to a preferred embodiment of the present invention, Figure 3 is a side cross-section schematically showing a boiler having a rainwater discharge function according to a preferred embodiment of the present invention it is a drawing

2 and 3, the boiler 1000 having a rainwater discharge function according to a preferred embodiment of the present invention includes a casing 100, a combustion device 200, a heat exchanger 300, a supply and exhaust member 400 and a discharge pipe 500.

The casing 100 has a space formed therein and is formed in a substantially hexahedral shape or the like. An air supply unit 110 and an exhaust unit 120 are formed on the upper side of the casing 100 , and a drain unit 130 is formed on the lower side of the casing 100 .

The combustion device 200 is located on the upper side of the inside of the casing 100, so that fuel such as gas and air introduced into the casing 100 through the air supply unit 110 are properly mixed and then burned to form a flame. It is a typical construction to generate. When the combustion device 200 generates a flame, high-temperature combustion gas due to the flame is generated in the combustion device 200 .

The heat exchanger 300 is configured to mutually exchange heat with the combustion gas generated by the combustion device 200 and a heat medium supplied from the outside. The heat exchanger 300 includes a housing 310, a pipe 320, and an exhaust receiving part 330.

The housing 310 is located in the center of the casing 100, has a space 310a formed therein, and has an independent fire chamber 312 above the space 310a. And the combustion device 200 supplies combustion gas to the fire chamber 312 .

Association 320 is formed in a pipe shape and consists of a plurality of pieces. One side of the pipe 320 is connected to the lower surface of the firebox 312 and the other side extends downward of the space 310a and is connected to the exhaust receiving portion 330 to be described later. The fire tube 320 is configured as a passage through which the combustion gas delivered to the fire chamber 312 is moved. Then, the heat medium supplied to the housing 310 comes into contact with the fire tube 320 and exchanges heat with hot water.

The exhaust receiving part 330 is provided at the lower part of the housing 310 and is connected to the pipe 320 . In addition, the combustion gas injected from the combustion device 200 into the fire chamber 312 moves along the inside of the fire tube 320 to heat the fire tube 320 and then moves to the exhaust receiving unit 330 . And the combustion gas that has completed heat exchange with the fire tube 320 is exhausted to the outside through the exhaust receiving unit 330 . To this end, an exhaust connection pipe 424 is mounted on the side of the exhaust accommodating part 330, and the exhaust connection pipe 424 interconnects the exhaust part 120 with the side of the exhaust accommodating part 330. An exhaust pipe 420 to be described below is connected to the exhaust unit 120, and combustion gas accommodated in the exhaust receiving unit 330 is exhausted to the outside through the exhaust connection pipe 424 and the exhaust pipe 420.

Meanwhile, in the present invention, after the combustion gas is accommodated in the exhaust accommodating unit 330, it is moved to the exhaust connection pipe 424, and at this time, condensed water is generated in the exhaust accommodating unit 330. A drain unit 130 is provided below the exhaust receiving unit 330 to discharge the condensed water to the outside. The drain unit 130 will be described later.

The air supply and exhaust member 400 includes an air supply pipe 410 , an exhaust pipe 420 and a closing part 430 . The air supply pipe 410 is formed in a long shape along the longitudinal direction, and one end is connected to the air supply unit 110 and the other end has an air supply hole 412 formed therein. An air supply connection pipe 414 is connected to one end of the air supply pipe 410, and one end of the air supply pipe 410 is connected to the air supply unit 110. And, as the combustion device 200 operates, external air is supplied to the air supply pipe 410 through the air supply hole 412 . The exhaust pipe 420 is formed in a tubular shape along the inside of the air supply pipe 410, and one end passes through one end of the air supply pipe 410 and is connected to the exhaust part 120, and the other end is connected to the other end of the air supply pipe 410. passes through and protrudes outward. In addition, an exhaust hole 422 is formed at the other end of the exhaust pipe 420 protruding out of the air supply pipe 410, and the combustion gas moving to the exhaust part 120 is moved along the exhaust pipe 420, and then the exhaust hole 422 is formed. It is exhausted to (422). The closing part 430 closes the open other end of the exhaust pipe 420 so that the combustion gas exhausted through the exhaust hole 422 does not flow back to the exhaust pipe 420 .

The discharge pipe 500 will be described later.

Figure 4 is a view for explaining the closing portion provided in the supply and exhaust member of the boiler having a rainwater discharge function according to a preferred embodiment of the present invention, Figure 5 is a rainwater discharge function according to a preferred embodiment of the present invention It is a diagram shown to explain the flow of combustion gas moving along the closure of the boiler.

3 to 5, the exhaust hole 422 is formed on the outer periphery of the other end of the exhaust pipe 420. Further, the closing part 430 closes the open outlet of the other end of the exhaust pipe 420 located farther than the exhaust hole 422 based on one end of the exhaust pipe 420 . In more detail, the closing portion 430 is located at the center of the outlet and protrudes in a conical shape toward one end of the exhaust pipe 420, and the outer periphery of the central portion 432 and the inner periphery of the outlet are mutually connected. It includes an edge portion 434 for connecting. A plurality of auxiliary holes 436 are formed in the rim portion 434 . In addition, a part of the combustion gas moving along the exhaust pipe 420 is exhausted through the exhaust hole 422, and the other part of the combustion gas moving along the exhaust pipe 420 is slanted along the central portion 432 and then assisted. It is discharged obliquely into the hole 436.

As described above, since the combustion gas moving along the exhaust pipe 420 is exhausted through the auxiliary hole 436 as well as the exhaust hole 422, the combustion gas moving along the exhaust pipe 420 passes through the exhaust hole 422 and auxiliary hole 436. There is an effect that can be quickly exhausted to the outside through the hole 436.

In addition, since the combustion gas discharged to the auxiliary hole 436 is slanted along the central portion 432 and then discharged to the auxiliary hole 436 obliquely, the combustion gas discharged to the auxiliary hole 436 is of the exhaust pipe 420. It does not stay around the outlet, so there is an effect that the combustion gas exhausted through the auxiliary hole 436 does not flow back to the exhaust pipe 420.

6 is a view illustrating a discharge pipe of a boiler having a rainwater discharge function according to a preferred embodiment of the present invention, and FIG. 7 is a drain pipe of a boiler having a rainwater discharge function according to a preferred embodiment of the present invention. Figure 8 is a view showing the flow of water moving in the drain pipe of the boiler having a rainwater discharge function according to a preferred embodiment of the present invention.

6 to 8, the discharge pipe 500 is formed in a flexible tubular shape, and one end in the longitudinal direction is connected to the lower end of the air supply pipe 410 in a penetrating state, and the other end in the longitudinal direction is passed through. The end passes through the inside of the casing 100 and extends to the drain part 130 . And the water located in the air supply pipe 410 is discharged to the drain unit 130 through the discharge pipe 500. Accordingly, the water generated in the air supply pipe 410 by rainwater flowing into the air supply pipe 410 rides the discharge pipe 500 connected to the air supply pipe 410 and moves toward the drain part 130, and then the drain part ( 130) is discharged to the outside.

As such, since the present invention is configured such that the discharge pipe 500 is connected to the lower part of the air supply pipe 410, the water flowing into the air supply pipe 410 is guided toward the drain part 130, so that the water in the air supply pipe 410 is removed. It has the effect of being easily discharged to the outside.

The drain unit 130 is installed at the lower end of the heat exchanger 300 to drain condensed water generated in the heat exchanger 300 to the outside and to drain water flowing into the discharge pipe 500 to the outside. The drain part 130 includes an outer tube 132, a lid part 136, an inner tube 134, an inner connection tube 134a, an outer connection tube 132a, and an exposure tube 138.

The outer tube 132 is formed in a columnar shape, and the upper end is installed at the lower end of the exhaust receiving portion 330, and the lower end extends downward to pass through the lower portion of the casing 100. The lid portion 136 closes the open lower end of the outer tube 132 . The inner tube 134 is formed in a tubular shape along the inside of the outer tube 132, and the upper end is connected to the upper end of the outer tube 132, and the lower end extends downward of the outer tube 132. The upper end of the inner tube 134 is connected to communicate with the lower side of the exhaust receiving portion 330, and the lower end of the inner tube 134 is positioned to be spaced apart from the top of the cover 136. In detail, the drain connection part 332 protrudes from the lower end of the exhaust accommodating part 330, and the connection guide part 131 is coupled to the drain connection part 332. And the outer periphery of the upper end of the outer tube 132 is coupled to the connection guide 131, and the upper end of the inner tube 134 is coupled to the inner periphery of the upper end of the outer tube 132.

The inner connecting pipe 134a has one end communicating with one side between the upper end and the lower end of the inner tube 134 in the longitudinal direction and the other end extending to penetrate one side of the outer tube 132 in an upwardly inclined state, , The other end of the inner connection pipe (134a) is positioned so as to be exposed to the outside of the outer pipe (132). One end of the external connection pipe 132a communicates with the other side between the upper end and the lower end in the longitudinal direction of the outer pipe 132 and the other end is positioned to be exposed to the outside of the outer pipe 132 with an upward inclination. At this time, the lower end of the inner connection pipe 134a connected to one side of the inner tube 134 is located lower than the lower end of the outer connection tube 132a connected to the other side of the outer tube 132. That is, the inner connection pipe 134a and the outer connection pipe 132a are positioned so that the heights connected to the inner pipe 134 and the outer pipe 132 are different from each other. The exposure tube 138 has one end connected to the other end of the external connection tube 132a and the other end extending downward to be exposed to the lower portion of the casing 100 . And, the upper end of the inner pipe 134 is connected to the lower end of the heat exchanger 300, and the other end of the discharge pipe 500 is connected to the inner connection pipe 134a.

The condensed water generated at the bottom of the heat exchanger 300 is moved to the inner tube 134. In addition, the water guided toward the drain unit 130 along the discharge pipe 500 passes through the internal connection pipe 134a and moves to the inner pipe 134. At this time, the water moved to the inner pipe 134 is moved to the external connection pipe 132a through the gap between the inner pipe 134 and the cover part 136. The water level of the inner pipe 134 and the outer pipe 132 gradually rises due to the water such as condensed water or rainwater moving into the inner pipe 134, and the water level of the inner pipe 134 and the outer pipe 132 rises. When it is filled up to the exposure tube 138, there is an effect that the water filled in the inner tube 134 and the outer tube 132 is quickly discharged downward along the exposure tube 138 according to the principle of the siphon. In addition, the lower part of the inner tube 134 is normally filled with water, such as, for example, the siphon tube of a toilet seat, so that gas flowing backward through the exposure tube 138 is blocked from being transmitted to the direction of the discharge tube 500. there is

In addition, since the lower end of the internal connection pipe 134a is located lower than the lower end of the external connection pipe 132a, the internal connection pipe 134a is normally blocked by water, and accordingly, through the air supply pipe 410 Since the supplied air cannot be moved in the direction of the inner tube 134 , the air supplied through the air supply pipe 410 is easily supplied to the combustion device 200 .

Although the present invention has been described in detail in the above embodiments, it is obvious that the present invention is not limited thereto, and various changes and modifications are possible within the scope of the technical idea of the present invention. If it falls within the scope of the claims, the technical idea should also be regarded as belonging to the present invention.

1000: Boiler with rainwater discharge function
100: casing 110: air supply
120: exhaust unit 130: drain unit
131: connection guide unit 132: external pipe
132a: external connector 134: internal tube
134a: internal connector 136: lid
138: exposure pipe 200: combustion device
300: heat exchanger 310: housing
310a: Space 312: Japanese room
320: connection 330: exhaust receiving unit
332: drain connection 400: supply and exhaust member
410: air supply pipe 412: air supply hole
414: air supply connector 420: exhaust pipe
422: exhaust hole 424: exhaust connection pipe
430: closed portion 432: central portion
434: rim 436: auxiliary hole
500: discharge pipe

Claims (6)

A discharge pipe connected to an air supply pipe supplying air to the combustion device and discharging water in the air supply pipe;
An outer tube having an upper end installed at the lower end of the heat exchanger and extending downward at the lower end;
a lid for closing the lower end of the outer tube;
It is formed inside the outer tube, the upper end is connected to the lower end of the heat exchanger so that the condensed water in the heat exchanger flows, the lower end of the inner tube is spaced apart from the top of the lid;
an internal connection pipe having one end communicated with one side of the inner pipe and the other end passing through one side of the outer pipe and connected to the discharge pipe;
An external connection pipe having one end in communication with the other side of the outer pipe and the other end exposed to the outside of the outer pipe; and
An exposure tube connected to the external connection tube; including,
The condensed water flowing into the inner tube from the heat exchanger and the water flowing into the inner tube through the inner connection tube are moved to the outer tube through a gap between the inner tube and the cover, and the outer connection tube and the exposure tube Boiler having a rainwater discharge function, characterized in that discharged to the outside through.
According to claim 1,
The internal connection pipe and the external connection pipe are inclined upward from one end to the other end, and the exposure pipe extends downward from one end connected to the external connection pipe to the other end. boiler with.
According to claim 1 or 2,
A boiler having a rainwater discharge function, characterized in that the lower end of the internal connection pipe is located lower than the lower end of the external connection pipe.
According to claim 1,
The air supply pipe having one end connected to the combustion device and the air supply part and having an air supply hole formed at the other end; and
An exhaust pipe formed along the inside of the air supply pipe, one end of which is connected to the combustion device through an exhaust unit, and the other end having an exhaust hole protrudes to the outside past the other end of the air supply pipe; further comprising rainwater discharge Boiler with function.
According to claim 1,
The heat exchanger is:
A housing having a space portion formed therein and having an independent firebox above the space portion;
a plurality of links, one side of which is connected to the lower surface of the firebox and the other side of which extends downward in the space; and
An exhaust receiving portion provided at a lower portion of the housing and connected to the pipe,
Combustion gas injected from the combustion device into the firebox heats the fire pipe while moving along the inside of the fire pipe, and then moves to the exhaust receiving portion,
A boiler having a rainwater discharge function, characterized in that the lower portion of the exhaust accommodating portion is configured to communicate with the inner tube, and condensed water generated in the exhaust accommodating portion is discharged to the inner tube. According to claim 4,
The exhaust hole is formed on the outer periphery of the other end of the exhaust pipe,
Further comprising a closing portion for closing the open outlet of the other end of the exhaust pipe located farther than the exhaust hole based on one end of the exhaust pipe,
The closing portion includes a central portion located at the center of the outlet and protruding in a conical shape toward one end of the exhaust pipe, and a rim portion interconnecting the outer periphery of the central portion and the inner periphery of the outlet, A plurality of auxiliary holes are formed,
A part of the combustion gas moving along the exhaust pipe is exhausted through the exhaust hole,
The boiler having a rainwater discharge function, characterized in that another part of the combustion gas moving along the exhaust pipe is slanted along the central portion and then discharged obliquely into the auxiliary hole.

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