KR20180058246A - Gas boiler exhaust block equipment - Google Patents

Abstract

The present invention relates to an exhaust gas shutoff apparatus for a gas boiler. According to the present invention, a housing having a support plate in a lower inside portion is provided, a first wall annularly formed and having a water level blocking film in the inner peripheral surface thereof and a second wall portion coupled with the upper surface of the support plate and surrounding and covering the first wall portion are formed in the housing, an upper cap finishing between the housing and the first wall portion and a lower cap finishing the lower end of the housing are coupled to an upper end of the housing, and a sealing ball is formed in the upper portion of the first wall portion so that the water level blocking film is blocked by the weight of the sealing ball, in which the sealing ball is lifted and lowered by the buoyancy of the condensed water flowing into the first wall portion, and the condensed water is dropped downward through the water level shielding film to remain in the condensed water movement flow path so that inward leakage of exhaust gas is prevented by the sealing ball or the condensed water. According to the present invention, when the gas boiler is driven, there is no risk of the exhaust gas leaking into the room through the water level shielding film and the condensate water flow channel since the water level blocking film is blocked by the weight of the sealing ball. When the condensed water is collected at a predetermined amount above the first wall portion, the sealing ball is lifted by buoyancy of the condensed water to automatically blocking the blocking film, In particular, the condensed water dropped downward through the water level shielding film is left in the condensed water flow passage so as to block the flow of the exhaust gas, so that the flow of the exhaust gas is blocked regardless of whether the gas boiler is first driven or continuously operated. As a result, the reliability of the product can be improved.

Description

Gas boiler exhaust block equipment for gas boiler

The present invention relates to an exhaust gas shutoff apparatus, and more particularly, to an exhaust gas shutoff apparatus that includes a closed ball inside a housing to exhaust gas from a gas boiler to shut the exhaust gas by lifting the closed ball by buoyancy when the condensed water reaches a predetermined water level Quot;

Generally, the gas boiler is divided into a wall-mounted type and a floor-mounted type according to its installation type. Depending on the hot water supply method, the heat exchanger of the boiler body is stored in a hot water storage tank In addition, depending on the heating water circulation system, the heating circulation circuit in the boiler is shut off from the atmosphere, and the air is shut off and the air heating circuit in the boiler is opened.

Such a gas boiler is heated by a gas burner in a state in which the heating pipe and the pipe body are filled with water, and is supplied to the heating pipe and the hot water pipe by the circulation pump to heat the room or supply the hot water On the other hand, when the temperature of the heated water rises and the pressure inside the boiler rises, the increased water is supplied to the cistern tank through the expansion line, and the boiler's moving heat is stopped and the temperature of the water in the pipe and the heating pipe drops When the internal pressure of the heating chamber is lowered, the water in the cistern tank flows backward through the expansion line to the pipe body and the heating pipe by the pressure difference, so that the amount of deficient water is automatically returned and replenished.

Particularly, in the case of a condensing gas boiler, the exhaust gas, which is discharged into the atmosphere at a high temperature during combustion, is passed through the cold portion of the heat exchanger and is condensed to a temperature below the dew point, so that the heating efficiency can be improved by using the latent heat of condensation .

Patent Document 1 discloses an exhaust gas condensed water discharging device of a conventional gas boiler. Referring to FIG. 1, there is shown a conventional exhaust gas condensed water discharging device of a gas boiler, which comprises a housing having a hollow shape with an exhaust port formed on an upper surface thereof, an elbow connected to an exhaust port of the housing, A siphon tube that is coupled to an outer circumferential surface of the elbow end and has one end disposed in the housing and accommodates condensed water generated in the exhaust gas discharged to the exhaust pipe; .

At this time, the exhaust gas flows through the exhaust port and the elbow toward the exhaust pipe, and the condensed water generated from the exhaust gas passing through the blocking plate of the elbow moves along the siphon tube.

Then, the condensed water moved along the siphon tube is collected in the first bent portion, and the exhaust gas is prevented from flowing into the room through the siphon tube.

If more condensed water than the predetermined amount is collected in the siphon tube, the condensed water collected in the first bent part is discharged to the room through the second bent part and the outlet side end part.

However, in the above-described Patent Document 1, when the gas boiler is driven, the condensed water is not collected in the first bend portion of the siphon tube, so that the exhaust gas flows into the room through the siphon tube as it is and until the condensed water is collected in the first bent portion There is a problem that the reliability of the product is deteriorated due to the inconvenience of ventilating the room when the gas boiler is driven each time.

KR 20-2000-0013888 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 an air conditioner having a first wall portion formed in an annular shape in an inner lower portion of a housing, A second wall part coupled to an upper surface of the support plate to cover and enclose the first wall part, an upper cap for closing the housing and the first wall part at the upper end of the housing, and a lower cap for closing the lower end of the housing, The closed ball is formed on the upper portion of the closed ball so that the closed ball is shut off by the own weight of the closed ball, the closed ball is lifted and lowered by the buoyancy of the condensed water flowing into the first wall portion and the condensed water is dropped downward through the level- The exhaust gas is prevented from leaking into the room by the sealed ball or the condensed water, thereby providing an exhaust gas shutoff apparatus for a gas boiler .

In order to achieve the object of the present invention as described above, there is provided a vacuum cleaner comprising: a hollow housing having upper and lower openings; A receiving plate coupled to a lower portion inside the housing in a plate shape; A first wall portion formed in an annular shape along a periphery of a central portion of the housing, the lower wall of the annular wall being formed at a predetermined distance from the bottom of the housing, The first wall part is formed to be spaced a predetermined distance from the upper end of the housing so that the first wall part and the housing part are covered with the first wall part. A second wall portion for forming a condensate flow path between the inner peripheral surfaces; An upper cap coupled to an upper end of the housing to close between the housing and the first wall and having an inlet formed at a central portion thereof; A lower cap coupled to a lower end of the housing to close the lower end of the housing and having a discharge port formed at a central portion thereof; And a sealing ball which is inserted and coupled to the upper portion of the first wall portion and moved up and down with respect to the level blocking film.

In the exhaust gas shutoff apparatus for a gas boiler according to the present invention, the level shielding film of the first wall portion is formed to be inclined downward in a downwardly projecting light structure.

The exhaust gas blocking device for a gas boiler according to the present invention is characterized in that the first wall portion is formed at an annular spaced distance from the upper inner circumferential surface with reference to the level intercepting membrane so that the sealing ball is spaced from the inner circumferential surface of the first wall portion by a predetermined distance And a guide protrusion for separating the guide protrusion.

In the exhaust gas blocking device for a gas boiler according to the present invention, a space between the lower end of the first wall portion and the support plate is spaced a predetermined distance so as to communicate with the condensate flow passage.

According to the present invention, when the gas boiler is driven, the water level shielding film is blocked by the self weight of the closed ball, there is no possibility of the exhaust gas leaking into the room through the water level shielding film and the condensate water flow channel, The closed ball is occasionally lifted by the buoyant force of the condensed water to automatically open the water level blocking film. Particularly, the condensed water dropped downward through the water level blocking film remains in the condensate water flow passage to block the flow of the exhaust gas, The closed ball is kept floated by the buoyant force at the time of collecting at a height equal to or higher than the level of the water level, so that the condensed water can be easily moved to the condensed water flow passage. Thus, the flow of the exhaust gas is interrupted The reliability of the product is improved.

1 is a perspective view showing an exhaust gas shutoff apparatus for a gas boiler according to the present invention.
Fig. 2 is an exploded perspective view of Fig. 1; Fig.
3 is a cross-sectional view showing a state in which the closed ball of the exhaust gas shutoff device for a gas boiler according to the present invention closes the level shutoff film.
4 is a cross-sectional view showing a closed ball of an exhaust gas shutoff device for a gas boiler according to the present invention, lifted by condensed water.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The housing 100 has a hollow shape in which upper and lower portions are opened.

Preferably, the housing 100 is integrally coupled to the bottom surface of the duct of the gas boiler.

The upper end of the housing 100 is sealed by the upper cap 400, and the lower end of the housing 100 is closed by the lower cap 500.

The housing 100 includes at least two connecting portions 102 protruding from the inner peripheral surface of the first and second wall portions 200 and 300 and connected to the first and second wall portions 200 and 300, .

The connection portion 102 protrudes from the inner circumferential surface of the housing 100 and has a distal end integrally formed with the outer circumferential surface of the second wall portion 300.

The receiving plate 110 is coupled to the lower inside of the housing 100 in the form of a plate.

The diameter of the receiving plate member 101 is preferably smaller than the inner diameter of the housing 100.

The support plate 110 further includes at least two extension protrusions 111 that are closely attached to the upper surface of the lower cap 500 along the bottom edge of the support plate 110.

The support plate 110 guides the condensed water to the discharge port 501 of the lower cap 500 through a gap between the extended protrusions 111.

The first wall portion 200 is formed in an annular shape along the periphery of the central portion of the housing 100 and has a lower end spaced a predetermined distance from the bottom of the housing 100 and has an annular water level blocking film 201 are formed.

The first wall part 200 is divided into upper and lower spaces with respect to the level shielding film 201.

The water level shielding film 201 of the first wall part 200 is formed to have a downward sloping downward symmetry structure.

The level shielding film 201 guides the foreign matter introduced into the first wall part 200 to move in a downward inclined direction along the periphery thereof and deposits around the periphery thereof.

The first wall portion 200 is spaced apart from the upper inner circumferential surface by a predetermined distance in an annular shape with respect to the level shielding film 201 so that the sealing ball 500 is separated from the inner circumferential surface of the first wall portion 200 by a predetermined distance The projecting portion 202 is further formed.

The guide protrusion 202 blocks the outer surface of the closed ball 500 from being in close contact with the inner circumferential surface of the first wall portion 200.

The lower end of the first wall portion 200 and the support plate 110 are spaced apart from each other by a predetermined distance to communicate with the condensate flow passage 301.

The second wall part 300 has a hollow shape having an open top and a bottom and is coupled to an upper surface of the receiving plate 110 of the housing 100 to cover the first wall part 200, 100 so as to form a condensed water flow path 301 between the first wall portion 200 and the inner peripheral surface of the housing 100.

The bottom surface of the second wall part 300 is inserted along the rim of the receiving plate 110 and positioned at a predetermined distance from the bottom surface of the housing 100.

It is preferable that the condensate flow passage 301 is formed in a shape of "∩".

The upper cap 400 is coupled to the upper end of the housing 100 to close the space between the housing 100 and the first wall 200 and form an inlet 401 at the center.

The upper cap 400 passes condensate through the inlet 401 and guides the condensate into the first wall 200.

The upper cap 400 fixes the upper end of the first wall part 200 on the bottom surface and keeps the first wall part 200 floating in the air in the housing 100.

The upper cap 400 is preferably fastened to the outer circumferential surface of the upper portion of the housing 100 in a spiral manner

The lower cap 500 is coupled to the lower end of the housing 100 to close the lower end of the housing 100, and a discharge port 501 is formed at the center of the lower cap 500.

The lower cap 500 discharges condensed water through its central portion.

The lower cap 500 is preferably fastened to the outer peripheral surface of the lower end of the housing 100 in a spiral manner.

The closed ball 500 is inserted and coupled to the upper portion of the water level shielding film 201 of the first wall portion 200 to move up and down.

The closed ball 500 is moved downward by its own weight in the first wall part 200 to close the level-shielding film 201.

The closed ball 500 is lifted by the condensed water collected in the upper space with reference to the level shielding film 201 of the first wall part 200 and is released from the level shielding film 201.

The closed ball 500 is preferably formed in a hollow shape so as to be lifted or lowered by a floating water buoyancy force.

The exhaust gas shutoff apparatus for a gas boiler according to the present invention constructed as above is used as follows.

The support plate 110 is inserted through the lower portion of the housing 100 and the lower cap 500 is coupled to the lower cap 500 to receive the extension protrusion 111 of the support plate 110 I support it.

At this time, the receiving plate 110 is disposed at a predetermined distance upward from the lower end of the housing 100.

The second wall portion 300 is inserted into the housing 100 so that the bottom surface of the second wall portion 300 is coupled to the upper surface of the support plate 110, The first wall portion 200 is inserted into the second wall portion 300 so that the first wall portion 200 is surrounded by the second wall portion 300.

Then, the sealing ball 600 is inserted into the inside of the first wall 200 through the top of the first wall 200 so that the sealing ball 600 seals the sealing layer 201 by its own weight.

The upper cap 400 is coupled to the upper end of the housing 100 so that the first wall part 200 is fitted and fixed to the lower surface of the upper cap 400. The lower cap 400 500) to seal the lower end of the housing (100).

Then, the first wall portion 200 is coupled to the upper cap 400, so that the central peripheral portion of the housing 100 is covered by the first wall portion 200.

The lower end of the first wall part 200 is spaced a predetermined distance from the receiving plate 110 and the upper end of the second wall part 300 is formed to be spaced a predetermined distance from the upper end of the housing 100 A condensed water flow passage 301 having a zigzag structure is formed between the housing 100 and the first wall portion 200.

The exhaust gas shutoff device for a gas boiler having the above configuration is integrally coupled to the bottom surface of the duct of the gas boiler.

That is, the exhaust gas heat-exchanged in the latent heat exchanger of the gas boiler generates condensed water. At this time, the exhaust gas is discharged to the outside through the gas boiler, and the condensed water falls downward.

Here, the exhaust gas is not discharged to the outside through the gas boiler, and the exhaust gas remaining in the gas boiler moves downward along the condensed water and flows into the inlet 401 of the upper cap 400.

The exhaust gas flowing into the upper space of the first wall portion 200 through the inlet 401 is blocked by the closed ball 500 sealing the level shielding film 201, And remains on the upper space of the first wall portion 200 without passing through the first wall portion 200.

The condensed water flowing into the upper space of the first wall part 200 through the inlet 401 is blocked by the sealing ball 600 sealing the water level shielding film 201, And is left on the rim of the level shielding film 201. [

Particularly, the foreign matter contained in the condensed water flowing into the upper space of the first wall part 200 remains on the rim of the level shielding film 201, and the sealing of the central part of the level shielding film 201 is blocked by the foreign substance.

When condensed water is continuously introduced into the upper space of the first wall part 200 through the inlet port 401 and a predetermined amount of condensed water is collected in the upper space of the first wall part 200, 600 are floated upward by the condensed water. At this time, the level blocking film 201 is opened.

At this time, the condensed water collected in the upper space of the first wall part 200 through the level shielding film 201 falls into the lower space of the first wall part 200, The condensed water remains in the condensate water flow path 301 between the second wall portions 300 and the closed ball 600 is moved downward by its own weight to seal the water level shielding film 201.

Here, the closed ball 600 is guided by the guide protrusion 202 and is moved upward and downward while being separated from the inner circumferential surface of the first wall portion 200.

That is, the guide protrusion 202 blocks the sealing ball 600 from being in close contact with the inner circumferential surface of the first wall part 200.

Then, while repeating the inflow of the condensed water as described above, the condensed water collected in the upper space of the first wall part 200 is continuously dropped into the lower space of the first wall part 200, And the second wall portion 300. The condensed water flowing through the second wall portion 300 is condensed in the condensed water flowing path 301,

The exhaust gas that has passed through the level shielding film 201 is blocked by the condensed water remaining in the condensed water flow passage 301 between the first wall portion 200 and the housing 100, To prevent leakage to the room.

Condensate water is gradually collected in the condensate water flow passage 301 between the first wall portion 200 and the second wall portion 300 so that the condensed water flows between the second wall portion 300 and the housing 100 The condensed water of the condensed water flow passage 301 between the second wall portion 300 and the housing 100 flows between the extended protruding portions 111 supporting the receiving plate 110 And is discharged to the discharge port 501 of the lower cap 500.

The shutoff ball 201 is shut off by the own weight of the closed ball 500 and the closed ball 500 is moved up and down by the buoyancy of the condensed water to leave the condensed water in the condensate flow passage 301, And the condensed water flow passage 301 is such that when the gas boiler is driven, the water level shielding film 201 is blocked by the own weight of the sealed ball 500, and the water level shielding film 201 and / The closed ball 500 is lifted by the buoyancy of the condensed water when the condensed water is collected over a predetermined amount on the upper portion of the first wall portion 200 and is prevented from leaking through the condensation water flow passage 301, In particular, the condensed water dropped downward through the water level shielding film 201 remains in the condensed water flow passage 301 to block the flow of the exhaust gas.

The exhaust gas shutoff device for a gas boiler according to the present invention described above is not limited to the embodiments described above, and any person skilled in the art may apply the present invention to the exhaust gas shutoff device for gas boilers according to the present invention without departing from the gist of the present invention. There is a technical spirit to the extent that it can be carried out and changed.

100: housing 101:
110: Support plate member 111: Extension projection
200: first wall portion 201: level shielding film
202: guide protrusion 300: second wall portion
301: Condensate flow passage 400: Upper cap
401: inlet 500: bottom cap
501: Outlet 600: Closed ball

Claims (4)

A hollow housing 100 having upper and lower openings;
A support plate 110 coupled to a lower inner side of the housing 100 in a plate shape;
A lower end of the annular shaped level shielding film 201 is formed at a predetermined distance from the bottom of the housing 100 and is formed in an annular shape along the periphery of the central portion of the housing 100, A wall portion 200;
The upper and lower ends of the first and second wall parts 200 and 200 are connected to the upper surface of the receiving plate member 101 of the housing 100 to cover the first wall part 200, A second wall portion 300 spaced apart from the first wall portion 200 and forming a condensate flow passage 301 between the first wall portion 200 and the inner peripheral surface of the housing 100;
An upper cap 400 coupled to an upper end of the housing 100 to close the housing 100 and the first wall 200 and having an inlet 401 at a central portion thereof;
A lower cap 500 coupled to a lower end of the housing 100 to close the lower end of the housing 100 and having a discharge port 501 formed at the center thereof; And
A sealing ball 600 which is inserted into the upper portion of the first wall portion 200 and moved up and down with respect to the level blocking film 201;
And an exhaust gas shut-off device for the gas boiler. The method according to claim 1,
The water level blocking film 201 of the first wall portion 200 is formed by,
Wherein the exhaust gas blocking structure is formed so as to be inclined downwardly in a downward beam structure. The method according to claim 1,
The first wall part (200)
A guide protrusion 202 spaced a predetermined distance in an annular shape on the inner circumferential surface of the upper surface of the level shielding film 201 so as to separate the enclosed ball 600 from the inner circumferential surface of the first wall 200 by a predetermined distance Wherein the exhaust gas is supplied to the gas boiler. The method according to claim 1,
Wherein a distance between the lower end of the first wall portion (200) and the support plate member (110) is set to a predetermined distance so as to communicate with the condensate flow passage (301).

Images