KR101932992B1 - Gas boiler have ventilation duct prevention water inflow - Google Patents

Abstract

The present invention relates to a gas boiler with a water inflow preventing ventilation duct. According to the present invention, a combustion chamber, a heat exchange inflow fan, and a water supply device are installed in a boiler housing having an air inlet and an air outlet formed therein, and a ventilation duct having a water trap part formed around the inside of the air outlet of the boiler housing, such that water flowing through a gap between the air outlet and a discharge pipe coupled to an insertion hole through the air outlet is dropped in the water trap part formed around the circumference of the insertion hole. Accordingly, the water is trapped in the water trap part, such that the water is prevented from dropping to the gas boiler. Moreover, the water flowing into the gas boiler through the gap between the air outlet and the discharge pipe coupled to the insertion hole through the air outlet, or through a gap between coupling members fixing a flange is dropped in the water trap part, such that the water is prevented from coming in contact with important parts and other parts of the gas boiler, thereby providing advantages of improving durability of the parts and extending a service life thereof. In particular, electric damage to the important part is not generated, such that abnormal operation does not occur in the gas boiler, thereby providing an effect of stably using a product.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a gas boiler having an exhaust duct for preventing inflow of water,

The present invention relates to a gas boiler, and more particularly, to a gas boiler, and more particularly, to a gas boiler, and more particularly, to a gas boiler which is provided with an exhaust duct having a water collecting part formed along the periphery of an inlet port in the inside of an exhaust port of a boiler housing, To the water collecting portion of the exhaust duct to prevent the water from falling into the components in the boiler housing.

Generally, a gas boiler uses gas as a fuel, heats water using combustion heat generated when the gas is burned, and uses a circulation pump for forcibly circulating the heated and heated water, To heat the room, and to supply heated water to hot water in bathrooms and kitchens.

Patent Document 1 discloses a conventional gas boiler. Referring to this, there is disclosed a gas boiler comprising a gas boiler in which a pair of supply mechanisms opposed to each other is formed on an upper surface thereof and an exhaust port is formed between the supply mechanisms, An exhaust pipe connecting the combustion chamber and the exhaust port to guide the combustion gas and air in the combustion chamber to the exhaust port; a heat exchanger installed inside the combustion chamber; And a water tank accommodated therein.

Here, when air is supplied into the gas boiler through the pair of air supply mechanisms, the air is supplied into the combustion chamber. At this time, air and gas are mixed in the combustion chamber to generate a mixed gas.

Then, a flame is generated while the mixed gas is burned in the combustion chamber, and the heat exchanger is heated by the flame.

Then, when the water stored in the water tank is circulated through the heat exchanger, the water is heated by the heat exchanger in the heat exchanger, and then circulated to the heating pipe to heat the room. Alternatively, .

In addition, the combustion gas and air burnt in the combustion chamber pass through the exhaust pipe of the gas boiler and are discharged to the outside.

However, in the above-described Patent Document 1, water is readily introduced into the gas boiler through the air supply mechanism or the exhaust port so that the air supply mechanism and the exhaust port are directly exposed to the outside of the gas boiler, The water is contacted with the water to damage the parts, the durability of the parts is damaged and the maintenance is frequently performed. Particularly, electrical defects are generated in the control part controlling the gas boiler among the main parts, The gas boiler malfunctions, which causes a great inconvenience to the user, thereby deteriorating the reliability of the product.

KR 1998-047529 U

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a combustion chamber, a heat exchanger intake fan, and a water supply device in a boiler housing having a feed mechanism and an exhaust port, The water flowing into the gap between the exhaust pipe and the exhaust port coupled to the insertion port through the exhaust port falls into the water trapping portion formed at the edge of the insertion port, so that water is trapped in the water trapping portion, And to provide a gas boiler provided with an exhaust duct for preventing inflow of water to prevent water from dropping into the boiler.

In order to accomplish the above object, the present invention provides a gas boiler provided with an exhaust duct for preventing inflow of water according to the present invention, A boiler housing forming an exhaust port, a boiler housing fixed on the upper surface by a fastening member and forming a flange connected to communicate with the exhaust port; A combustion chamber installed at one side of the inside of the boiler housing and being ignited by mixing air and gas supplied through the air supply mechanism; A heat exchanger installed inside the combustion chamber and being heated in the combustion chamber; An intake fan installed at a front end of the combustion chamber and forcedly sucking air through the air supply mechanism to supply the air to the combustion chamber; And a water supply device connected to the heat exchanger to supply water to the heat exchanger, wherein an inner upper surface of the boiler housing is formed with an insertion hole communicating with the exhaust port in a hollow shape to allow entry of the exhaust pipe, An exhaust duct formed in an annular shape along the rim and having a water collecting portion for collecting water falling into the boiler housing through a gap between the exhaust port and the exhaust pipe or a coupling member for fixing the flange is further formed .

In the gas boiler provided with the exhaust duct for preventing inflow of water according to the present invention, the exhaust duct is provided between the inlet and the water collector, And an outer blocking wall is formed at the rim of the water collecting portion for blocking water falling to the water collecting portion from falling to the outside of the water collecting portion.

In the gas boiler provided with the exhaust duct for preventing inflow of water according to the present invention, the exhaust duct may further include a water outlet formed at one side of the outer blocking wall for discharging the water collected in the water collector to the outside of the water collector .

In the gas boiler provided with the exhaust duct for preventing inflow of water according to the present invention, the exhaust duct is formed in a pair in parallel with each other on both sides of the water outlet, and the water discharged from the water outlet through the water outlet And a water induction diaphragm for guiding the water to flow in one direction is further formed.

In the gas boiler provided with the exhaust duct for preventing inflow of water according to the present invention, the exhaust duct is connected to the water outlet at one end, and the other end is exposed to the outside of the boiler housing, And a water discharge hose for moving the water discharge hose to the outside of the housing.

In the gas boiler provided with the exhaust duct for preventing inflow of water according to the present invention, the water collecting part is formed to be inclined downward from one side to the other side to guide the water to flow down to the water outlet.

In the gas boiler provided with the exhaust duct for preventing inflow of water according to the present invention, the water collecting portion of the exhaust duct is formed to have a larger diameter than the diameter of the diameter connecting the center of the fastening member for fixing the flange, And collects water falling into the boiler housing through the clearance of the fastening member.

In the gas boiler provided with the exhaust duct for preventing inflow of water according to the present invention, the flange forms an inner pipe for guiding the entrance of the exhaust pipe, and a flange coupling portion which is tightly coupled to the upper surface of the boiler housing is formed on the outer surface of the inner pipe And the inner diameter of the flange coupling portion is formed to be larger than the inner diameter of the water collecting portion of the exhaust duct.

According to the present invention, the water introduced into the gas boiler through the clearance of the water introduced into the gas boiler or the fastening member fixing the flange through the gap between the exhaust pipe inserted into the inlet of the exhaust duct through the exhaust port, Water is prevented from coming into contact with the main parts of the gas boiler and water is prevented from coming into contact with the parts, thereby improving the durability of the parts and extending the service life of the parts. In particular, There is no abnormality in the operation of the gas boiler, so that the product can be used stably.

1 is a schematic view showing a gas boiler provided with an exhaust duct for preventing inflow of water according to the present invention.
2 is an exploded perspective view of a gas boiler provided with an exhaust duct for preventing inflow of water according to the present invention.
3 is a cross-sectional perspective view of a gas boiler having an exhaust duct for preventing inflow of water according to the present invention.
4 is a plan view showing a state where a flange is coupled to an exhaust duct of a gas boiler provided with an exhaust duct for preventing inflow of water according to the present invention.
5 is a perspective view showing an exhaust duct of a gas boiler provided with an exhaust duct for preventing inflow of water according to the present invention.
6 is a perspective view showing another exhaust duct of a gas boiler provided with an exhaust duct for preventing inflow of water according to the present invention.

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

The boiler housing 100 is hollow and has an air supply mechanism 101 for sucking outside air and an exhaust port 102 for exhausting the exhaust gas to the outside and is fixed to the upper surface by a fastening member B And a flange 103 connected to communicate with the exhaust port 102 is formed.

The flange 103 is formed with an inner pipe 103a to guide the exhaust pipe P and a flange coupling portion 103b formed on the outer surface of the inner pipe 103a to be in tight contact with the upper surface of the boiler housing 100, .

The inner diameter of the flange coupling portion 103b is formed to be relatively larger than the inner diameter of the water trapping portion 602 of the exhaust duct 600.

The water falling through the clearance between the inner pipe 103a and the flange engagement portion 103b falls to the water collection portion 602. [

The exhaust port 102 allows the exhaust pipe P to be inserted into the exhaust port 102 and exhausts the exhaust gas in the boiler housing 100 to the outside of the boiler housing 100 through the exhaust pipe P.

The boiler housing 100 includes the combustion chamber 200, the heat exchanger 300, the intake fan 400, the water supply device 500, and the exhaust duct 600 therein.

The water flowing into the boiler housing 100 through the gap between the exhaust port 102 and the exhaust pipe P falls to the water collecting portion 602 of the exhaust duct 600.

The combustion chamber 200 is installed on one side of the inside of the boiler housing 100 and is operated by igniting the air supplied through the air supply mechanism 101 and the gas.

The heat exchanger 300 is installed inside the combustion chamber 200 and is heated in the combustion chamber 200.

The heat exchanger 300 is heated by the flame generated in the combustion chamber 200.

The heat exchanger 300 forms a pipe 300a connected to the water supply device 500 at its periphery and transfers the water delivered from the water supply device 500 through the pipe 300a to the heat exchanger (300), and the water is heated by a heat exchange function.

The intake fan 400 is installed at a front end of the combustion chamber 200 and forcibly sucks air through the air supply mechanism 101 and supplies the air to the combustion chamber 200.

The water supply device 500 is connected to the heat exchanger 300 to supply water to the heat exchanger 300.

The water supply device 500 supplies water to the pipe 300a formed around the heat exchanger 300 so that the water passes through the pipe 300a and the water passed through the pipe 300a is heat- And is then supplied to the hot water or circulated through the heating pipe to heat the room.

The exhaust duct 600 has a hollow shape and is formed in an annular shape along the rim of the insertion port 601 to communicate with the exhaust port 102 to form an insertion port 601 for allowing the exhaust pipe P to enter, And a water collecting portion 602 for collecting water falling into the boiler housing 100 through a gap between the exhaust pipe P and the coupling member B for fixing the flange 103, .

The exhaust duct 600 is installed to surround the exhaust port 102 on the inner upper surface of the boiler housing 100.

The insertion port 601 and the water collecting part 602 are preferably formed in a cylindrical shape on the outer circumferential surface thereof.

The water collecting portion 602 collects water falling through a gap between the inner pipe 103a and the flange coupling portion 103b.

The exhaust duct 600 is provided between the insertion port 601 and the water collecting part 602 and includes an inner blocking wall 603 for blocking water falling into the water collecting part 602 from entering the insertion port 601 And an outer blocking wall 604 is formed at the rim of the water collecting portion 602 to block the water falling into the water collecting portion 602 from falling out of the water collecting portion 602.

The water collecting portion 602 of the exhaust duct 600 is formed to have a diameter that is relatively larger than the diameter d connecting the center of the fastening member B that fixes the flange 103, And collects the water falling into the boiler housing 100 through the clearance of the member (B).

The inner blocking wall 603 is formed to have a diameter that is relatively smaller than the diameter d connecting the center of the fastening member B and is located in the inner portion of the diameter d.

The outer blocking wall 604 is formed to have a diameter that is relatively larger than a diameter connecting the center of the fastening member B and is located at an outer portion of the diameter d.

A water outlet 604a for discharging the water collected in the water collecting part 602 to the outside of the water collecting part 602 is further formed on one side of the outer blocking wall 604.

The exhaust ducts 600 are formed on both sides of the water outlet 604a in parallel to each other so that the water discharged from the water collector 602 through the water outlet 604a flows in one direction Thereby forming a water induction diaphragm 605 for inducing the water.

The water induction diaphragm 605 prevents the water discharged to the water outlet 604a from flowing down to the side of the exhaust duct 600 and guides the water to flow in one direction.

The water outlet 604a may be formed in the shape of an opened hole through which water passes according to a user's selection, or may be formed in a connection pipe shape.

One end of the exhaust duct 600 is connected to the water outlet 604a and the other end of the exhaust duct 600 is exposed to the outside of the boiler housing 100 so that water collected in the water collector 602 is discharged to the outside of the boiler housing 100 A water discharge hose 606 for moving water is further formed.

The other end of the water discharge hose 606 is connected to a water collecting device (not shown) provided outside the boiler housing 100.

The water collecting part 602 is formed to be inclined downward from the one side to the other side to guide the water to flow down to the water outlet 604a.

The gas boiler having the above-described exhaust duct for preventing water inflow according to the present invention is used as follows.

[First Embodiment]

In the following description, an exhaust duct according to the first embodiment will be described as an example.

The inlet duct 601 of the exhaust duct 600 and the outlet 102 of the boiler housing 100 communicate with each other by closely fixing the exhaust duct 600 to the upper inner surface of the boiler housing 100.

When the exhaust pipe P is introduced into the exhaust port 102, the exhaust pipe P enters the inlet port 601 of the exhaust duct 600 and the exhaust pipe 600 is connected to the exhaust duct 600. ) This connection is fixed.

At this time, when the exhaust pipe P enters the insertion port 601, a sealing packing (not shown) provided in the insertion port 601 is pressed between the inner circumferential surface of the insertion port 601 and the exhaust pipe P, So that the inflow of water into the insertion port 601 is blocked.

The water exhausting duct 600 is formed with a water collecting part 602 at the edge of the insertion port 601. The water collecting part 602 includes an inner blocking wall 603 formed outside the insertion port 601, And is disposed between the outer blocking wall 604 formed on the outer edge of the water collecting portion 602 to collect water flowing into the gap between the exhaust pipe P and the insertion port 601.

The water dropped into the boiler housing 100 through the space between the inner pipe 103a and the flange coupling portion 103b of the flange 103 is larger than the inner diameter of the flange coupling portion 103b of the flange 103 The inner diameter of the inner pipe 103a and the flange engaging portion 103b fall down to the water collecting portion 602 located below the seam between the inner pipe 103a and the flange engaging portion 103b and are collected in the water collecting portion 602.

A flange 103 covering the connection pipe 111 of the exhaust pipe P and the exhaust duct 110 is installed on the upper surface of the boiler housing 100 and the flange 103 is fastened to the upper surface of the flange 103 And the flange 103 is tightly fixed to the upper surface of the boiler housing 100 by fastening the member B. [

At this time, the diameter d connecting the center of the fastening member B is formed into an arc shape, and the diameter d of the arc shape is located at the center between the inner and outer blocking walls 603 and 604.

That is, the inner blocking wall 603 is formed to be relatively smaller than the diameter d and is located inside the diameter d, and the outer blocking wall 604 is formed to be relatively larger than the diameter d. And is located at the outer portion of the diameter d.

Then, the water introduced into the boiler housing 100 through the clearance of the fastening member (B) falls to the water collecting part (602).

When the gas boiler provided with the exhaust duct 600 is operated to operate the intake fan 400 provided in the boiler housing 100 as described above, the intake fan 400 is operated by the suction pressure of the intake fan 400, Outside air is forcibly sucked through the air supply mechanism (101).

The air introduced into the combustion chamber 200 through the intake fan 400 is mixed with the gas in the combustion chamber 200 to generate a mixed gas, and the mixed gas is combusted to generate a flame.

At this time, the mixed gas generated in the combustion chamber 200 is ignited in the combustion chamber 200 to generate a flame, and the flame heats the heat exchanger 300 provided in the combustion chamber 200, The heat exchanger 300 is heated.

The water supply device 500 supplies water to the pipe 300a formed around the heat exchanger 300. At this time, the water passing through the pipe 300a is heat-exchanged with the heat exchanger 300 And then the heated water is introduced into the heating pipe to raise the temperature of the room, or is discharged through piping such as a kitchen or a bathroom to provide hot water.

In the combustion chamber 200, exhaust gas is generated due to the mixed gas combustion, and the exhaust gas is transferred to the inlet port 111 of the exhaust duct 110 by being moved above the combustion chamber 200.

Then, the exhaust gas flowing into the insertion port 601 is discharged to the outside of the boiler housing 100 through the exhaust pipe (P).

Water flowing downward through the outer surface of the exhaust pipe P flows into the gap between the exhaust pipe P and the insertion port 601 through the flange 103. The water introduced into the gap passes through the inner blocking Is moved in the direction of the outer rim of the insertion port (601) on the wall (603), and is collected in the water trapping section (602).

The water dropped onto the upper surface of the boiler housing 100 flows into the boiler housing 100 through the clearance of the fastening member B which fixes the flange 103 and flows into the boiler housing 100 The introduced water is directly dropped and collected in the water collecting unit 602.

At this time, the water collected in the water collecting part 602 is blocked by the inner blocking wall 603 and prevented from flowing in the direction of the insertion port 601, and is blocked by the outer blocking wall 604, So that it is prevented from falling outwardly of the water collecting portion 602.

The water collected in the water collecting part 602 flows downward in a downward inclined direction and then discharged to the outside of the water collecting part 602 through the water outlet 604a of the opened shape.

The water discharged into the water outlet 604a is blocked by the water induction diaphragm 605 and is prevented from falling to the side of the exhaust duct 600. At the same time, the water is guided by the water induction diaphragm 605, Thereby discharging the water in the water collecting part 602. [

[Second Embodiment]

In the following description, an exhaust duct according to the second embodiment will be described as an example.

The inlet duct 601 of the exhaust duct 600 and the outlet 102 of the boiler housing 100 communicate with each other by closely fixing the exhaust duct 600 to the upper inner surface of the boiler housing 100.

When the exhaust pipe P is introduced into the exhaust port 102, the exhaust pipe P enters the inlet port 601 of the exhaust duct 600 and the exhaust pipe 600 is connected to the exhaust duct 600. ) This connection is fixed.

At this time, when the exhaust pipe P enters the insertion port 601, a sealing packing (not shown) provided in the insertion port 601 is pressed between the inner circumferential surface of the insertion port 601 and the exhaust pipe P, So that the inflow of water into the insertion port 601 is blocked.

The water exhausting duct 600 is formed with a water collecting part 602 at the edge of the insertion port 601. The water collecting part 602 includes an inner blocking wall 603 formed outside the insertion port 601, And is disposed between the outer blocking wall 604 formed on the outer edge of the water collecting portion 602 to collect water flowing into the gap between the exhaust pipe P and the insertion port 601.

A flange 103 covering the connection pipe 111 of the exhaust pipe P and the exhaust duct 110 is installed on the upper surface of the boiler housing 100 and the flange 103 is fastened to the upper surface of the flange 103 And the flange 103 is tightly fixed to the upper surface of the boiler housing 100 by fastening the member B. [

At this time, the diameter d connecting the center of the fastening member B is formed into an arc shape, and the diameter d of the arc shape is located at the center between the inner and outer blocking walls 603 and 604.

That is, the inner blocking wall 603 is formed to be relatively smaller than the diameter d and is located inside the diameter d, and the outer blocking wall 604 is formed to be relatively larger than the diameter d. And is located at the outer portion of the diameter d.

Then, the water introduced into the boiler housing 100 through the clearance of the fastening member (B) falls to the water collecting part (602).

When the gas boiler provided with the exhaust duct 600 is operated to operate the intake fan 400 provided in the boiler housing 100 as described above, the intake fan 400 is operated by the suction pressure of the intake fan 400, Outside air is forcibly sucked through the air supply mechanism (101).

The air introduced into the combustion chamber 200 through the intake fan 400 is mixed with the gas in the combustion chamber 200 to generate a mixed gas, and the mixed gas is combusted to generate a flame.

At this time, the mixed gas generated in the combustion chamber 200 is ignited in the combustion chamber 200 to generate a flame, and the flame heats the heat exchanger 300 provided in the combustion chamber 200, The heat exchanger 300 is heated.

The water supply device 500 supplies water to the pipe 300a formed around the heat exchanger 300. At this time, the water passing through the pipe 300a is heat-exchanged with the heat exchanger 300 And then the heated water is introduced into the heating pipe to raise the temperature of the room, or is discharged through piping such as a kitchen or a bathroom to provide hot water.

In the combustion chamber 200, exhaust gas is generated due to the mixed gas combustion, and the exhaust gas is transferred to the inlet port 111 of the exhaust duct 110 by being moved above the combustion chamber 200.

Then, the exhaust gas flowing into the insertion port 601 is discharged to the outside of the boiler housing 100 through the exhaust pipe (P).

Water flowing downward through the outer surface of the exhaust pipe P flows into the gap between the exhaust pipe P and the insertion port 601 through the flange 103. The water introduced into the gap passes through the inner blocking Is moved in the direction of the outer rim of the insertion port (601) on the wall (603), and is collected in the water trapping section (602).

The water dropped onto the upper surface of the boiler housing 100 flows into the boiler housing 100 through the clearance of the fastening member B which fixes the flange 103 and flows into the boiler housing 100 The introduced water is directly dropped and collected in the water collecting unit 602.

At this time, the water collected in the water collecting part 602 is blocked by the inner blocking wall 603 and prevented from flowing in the direction of the insertion port 601, and is blocked by the outer blocking wall 604, So that it is prevented from falling outwardly of the water collecting portion 602.

The water collected in the water collecting part 602 flows downward in a downward inclined direction and then discharged to the outside of the water collecting part 602 through the water outlet 604a of the connecting pipe shape.

The water discharge hose 606 is connected to the water discharge port 604a and the other end of the water discharge hose 606 is provided outside the boiler housing 100 or inside the boiler housing 100 (Not shown).

Then, the water discharged to the water discharge port 604a is guided by the water discharge hose 606 and is moved to a water collecting device (not shown), thereby discharging the water in the water collecting part 602. [

The water that flows into the gap between the exhaust pipe P and the insertion port 601 or flows into the gap of the fastening member B is collected in the water collecting portion 602 of the exhaust duct 600, The structure for preventing falling into the housing 100 is a structure for preventing inflow into the gas boiler through a gap between the exhaust pipe P and the exhaust port 101 inserted into the insertion port 601 of the exhaust duct 600 through the exhaust port 102 The water that has flowed into the gas boiler through the gap of the fastening member B that fixes the water or the flange 103 is dropped into the water collecting portion 602 to prevent water from contacting the main components of the gas boiler, Water is prevented from coming into contact with the parts, thereby improving the durability of the parts and extending the service life of the parts.

The present invention is not limited to the above-described embodiments, and various modifications and changes may be made without departing from the scope of the present invention as set forth in the following claims. For example, the present invention may be applied to a gas boiler provided with a gas- There is a technical spirit to the extent that anyone with ordinary knowledge in the field to which it belongs can make various changes.

100: boiler housing 101: feed mechanism
102: exhaust port 103: flange
200: combustion chamber 300: heat exchanger
300a: piping 400: suction fan
500: water supply device 600: exhaust duct
601: inserting port 602: water collecting part
603: inner blocking wall 604: outer blocking wall
604a: Water outlet 605: Water induction diaphragm
606: water discharge hose B: fastening member
d: diameter P: exhaust pipe

Claims (8)

A supply mechanism 101 for sucking outside air in an upper portion in a hollow shape and an exhaust port 102 for exhausting an exhaust gas to the outside are formed and fixed to the upper surface of the exhaust port 102 by a fastening member B, A boiler housing (100) formed with a flange (103) coupled to communicate;
A combustion chamber 200 installed at one side of the inside of the boiler housing 100 and ignited by mixing air and gas supplied through the air supply mechanism 101;
A heat exchanger 300 installed in the combustion chamber 200 and operated in the combustion chamber 200;
An intake fan 400 installed at a front end of the combustion chamber 200 for forcibly sucking air through the air supply mechanism 101 and supplying the air to the combustion chamber 200; And
A water supply device 500 connected to the heat exchanger 300 to supply water to the heat exchanger 300;
≪ / RTI >
The boiler housing 100 has an inner upper surface formed with an insertion hole 601 which communicates with the exhaust port 102 to allow the exhaust pipe P to enter and is formed in an annular shape along the rim of the insertion port 601 The water flowing into the gap between the exhaust port 102 and the exhaust pipe P or the water collecting water falling into the boiler housing 100 through the clearance of the fastening member B fixing the flange 103 An exhaust duct 600 having a collecting portion 602 is further formed,
The flange 103 is formed with an inner pipe 103a to guide the exhaust pipe P and a flange coupling portion 103b formed on the outer surface of the inner pipe 103a to be in tight contact with the upper surface of the boiler housing 100, And the inner diameter of the flange coupling portion 103b is formed to be larger than the inner diameter of the water trapping portion 602 of the exhaust duct 600. [ The method according to claim 1,
The exhaust duct (600)
An inner blocking wall 603 is provided between the insertion port 601 and the water trapping portion 602 to block water falling into the water trapping portion 602 from flowing into the insertion port 601,
And an outer blocking wall (604) for blocking water falling to the water collecting part (602) from dropping to the outside of the water collecting part (602) is formed in a rim of the water collecting part (602) Gas boiler with anti - ventilation duct. 3. The method of claim 2,
The exhaust duct (600)
And a water discharge port (604a) for discharging the water collected in the water collecting part (602) to the outside of the water collecting part (602) is formed at one side of the outer blocking wall (604) . The method of claim 3,
The exhaust duct (600)
A water induction diaphragm 605 protruding from both sides of the water discharge port 604a in parallel to each other and guiding the water discharged from the water collection port 602 through the water discharge port 604a to flow in one direction ) Is further formed on the outer circumferential surface of the outer circumferential surface of the outer circumferential surface of the outer circumferential surface of the gas duct. The method of claim 3,
The exhaust duct (600)
The water discharge hose 606 is connected to the water discharge port 604a and the other end is exposed to the outside of the boiler housing 100 to move the water collected in the water collecting part 602 to the outside of the boiler housing 100 ) Is further formed on the outer circumferential surface of the outer circumferential surface of the outer circumferential surface of the outer circumferential surface of the outer circumferential surface of the outer circumferential surface. 6. The method according to any one of claims 3 to 5,
The water collecting unit 602,
And the water outlet is formed to be sloped downward from one side to the other side so that water flows down to the water outlet (604a). The method according to claim 1,
The water collecting portion 602 of the exhaust duct 600 is connected to the water collecting portion 602,
The diameter of the connecting member B is larger than the diameter d connecting the center of the fastening member B for fixing the flange 103, Characterized in that water falling down into the inside of the duct is collected. A supply mechanism 101 for sucking outside air in an upper portion in a hollow shape and an exhaust port 102 for exhausting an exhaust gas to the outside are formed and fixed to the upper surface of the exhaust port 102 by a fastening member B, A boiler housing (100) formed with a flange (103) coupled to communicate;
A combustion chamber 200 installed at one side of the inside of the boiler housing 100 and ignited by mixing air and gas supplied through the air supply mechanism 101;
A heat exchanger 300 installed in the combustion chamber 200 and operated in the combustion chamber 200;
An intake fan 400 installed at a front end of the combustion chamber 200 for forcibly sucking air through the air supply mechanism 101 and supplying the air to the combustion chamber 200; And
A water supply device 500 connected to the heat exchanger 300 to supply water to the heat exchanger 300;
≪ / RTI >
On the inner upper surface of the boiler housing 100,
And an exhaust port 601 is formed in the shape of an annulus along the rim of the insertion port 601 to communicate with the exhaust port 102 and the exhaust pipe P, And a water collecting portion 602 for collecting water falling into the boiler housing 100 through a gap between the water flowing into the gap between the flange 103 and the coupling member B for fixing the flange 103, 600,
The water collecting portion 602 of the exhaust duct 600 is connected to the water collecting portion 602,
The diameter of the connecting member B is larger than the diameter d connecting the center of the fastening member B for fixing the flange 103, Characterized in that water falling down into the inside of the duct is collected.

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