KR200176948Y1 - A shutoff apparatus for exhaust gas of a condensate pipe - Google Patents

Abstract

The present invention relates to an exhaust gas blocking device of a condensate receiver for a gas boiler, even when the condensate of the exhaust gas that is condensed by heat exchange during initial operation or operation of the boiler does not remain in the condensate receiver 10 of the siphon structure. In order to double the stability of the boiler by structurally blocking a part of the exhaust gas flowing into the room through the condensate receiver, the condensate passage hole 16b is bent downwardly in the middle part where the discharge flow of the condensate is switched. The water level reference membrane 16a is formed, and the condensate water sealing ball 18 having excellent buoyancy is installed above the condensate water passing hole 16b of the water level reference membrane 16a, and the condensate is centered on the reference residual water level L. Passing hole (16b) is characterized in that it is configured to be space-sealed by the condensate and the condensate sealing ball (18).

Description

A shutoff apparatus for exhaust gas of a condensate pipe}

The present invention relates to an exhaust gas blocking device of a condensate receiver for a gas boiler that prevents a part of the exhaust gas from entering the room through the condensate receiver. More specifically, the exhaust gas is condensed by heat exchange during the initial operation of the boiler or during operation. Of the exhaust gas blocking device of the condensate receiver for the gas boiler that can structurally block the inflow of a part of the exhaust gas into the room through the condensate receiver even when the condensate in the siphon structure does not remain at a certain level. will be.

In general, the gas boiler is divided into a wall-mounted type and a floor-mounted type according to its installation type, and according to the hot water supply method, the heat exchanger of the boiler body supplies hot water by a hot water heat exchanger and stores it in a separate hot water storage tank. When the hot water is supplied, the heating water circulation system is divided into the air circulation circuit in the boiler is blocked from the atmosphere is divided into a closed air-blocking method and an air opening method of the heating circuit in the boiler is open.

The gas boiler is heated by a gas burner in a state in which the heating pipe and the tube are filled with water, and are supplied to the heating pipe and the hot water supply pipe by a circulating pump to heat the room or supply the hot water like a normal hot water boiler. On the other hand, when the temperature of the heated water rises and the pressure inside the boiler rises, an increasing amount of water is supplied to the tank tank through the expansion line, and the heating of the boiler is stopped to decrease the temperature of the water in the pipe and the heating pipe. When the internal pressure of the heating chamber is lowered, water in the cisterns tank flows back into the pipe and the heating pipe through the expansion line due to the pressure difference, thereby forming a circulation structure in which the insufficient water is automatically replenished.

Particularly, in the case of condensing gas boiler, the exhaust gas discharged into the atmosphere at high temperature during combustion passes through the cold part of the heat exchanger to condense below the dew point temperature, thereby improving heating efficiency by using the latent condensation heat generated at this time. .

On the other hand, since the gas boiler is installed near the living room and the living room, the necessity of ventilation is further emphasized according to the characteristics of the fuel and the presence of the room, and in fact, most of the boiler related accidents are generated when the exhaust gas is introduced into the room. Accidental poisoning due to carbon monoxide (CO) in the exhaust gas has become a major problem.

In particular, in the case of condensing gas boilers, most of the exhaust gas generated by combustion is discharged through the exhaust port when the boiler is commissioned in a state in which there is no residual water level condensate in the condensate receiver. While the condensate of the gas is maintained at a constant level in the condensate tray there is a structural problem that a part of the exhaust gas is introduced into the room through the condensate tray.

Therefore, the present invention was devised to solve the general problem that a part of exhaust gas flows into the room when the conventional condensing gas boiler is initially commissioned, and the condensed water of the exhaust gas condensed by heat exchange during initial operation or during operation of the boiler is siphoned. To provide an exhaust gas blocking device for the condensate receiver for a gas boiler that can structurally shut off a part of the exhaust gas flowing into the room through the condensate receiver even when a certain level is not remaining in the condensate receiver of the structure. There is this.

1 is a gas boiler internal structure of the exhaust gas blocking device is installed in the condensate receiver of the present invention.

Figure 2 is a detailed structure of the exhaust gas blocking device of the condensate receiver according to the present invention.

Explanation of symbols on the main parts of the drawings

10: condensate receiving 12: overflow pipe

14: condensate outlet 16a: water level reference membrane

16b: condensate through hole 18: condensate sealing ball

20: exhaust 22: exhaust duct

24 exhaust port 26 main heat exchanger

In order to achieve the above object, the present invention can increase the heating efficiency of the boiler by the latent heat of condensation generated by condensing below the dew point temperature by passing the exhaust gas lost to the air at high temperature during combustion to the cold part of the main heat exchanger. In the gas boiler of the condensing function configured to be, the intermediate portion where the discharge flow of the condensate is switched to prevent a part of the exhaust gas discharged while being heat exchanged through the main heat exchanger to enter the room through the condensate receiver of the siphon structure The water level reference membrane is formed to be centrally through the condensate through-holes while the condensate sealing ball is installed above the condensate through-hole of the water level reference membrane. Characterized in that configured to be space sealed by do.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention in detail as follows.

1 illustrates a schematic internal structure of a gas boiler in which an exhaust gas blocking device is installed in a condensate receiver 10 of the present invention, and FIG. 2 shows a condensate watertight ball 18 according to the residual water level of the condensate according to the present invention. The exhaust gas blocking device of the condensate receiver in which the water level reference membrane 16a is formed to be space-sealed while buoyancy is moved in detail.

As shown in the figure, the condensed water of the exhaust gas that is heat-exchanged through the main heat exchanger 26 of the exhaust unit 20 to be condensed below the dew point temperature is discharged outside through the condensation outlet 14 and at the same time, the exhaust unit 20 The condensate receiver 10 is formed in a siphon structure so that a predetermined level of water remains in the condensate receiver 10 connected between the bottom exhaust duct 22 and the condensate outlet 14.

In addition, the water level reference membrane 16a through which the condensate passage hole 16b penetrates in the center while the condensate is remaining downward by a certain level and is bent downwardly in the middle of the condensate receiver 10 which is bent by 180 °. This is formed, and the condensed water sealing ball 18 excellent in buoyancy is installed above the condensed water passing hole 16b of the water level reference membrane 16a so that buoyancy can be moved according to the residual water level of the condensed water.

That is, during the initial operation of the boiler or during operation, the condensed water that passes through the cold portion of the main heat exchanger 26 and condenses below the dew point temperature is condensed through the condensate passing hole 16b in the center of the water level reference membrane 16a. ) When the residual water level of the condensate water is increased while being filled into the inside and filled with the reference residual water level (L), the condensate water receiving bowl 10 can be buoyantly moved above the standard water level film 16a by buoyancy. The water level reference layer 16a is formed in the middle portion of the?

In addition, the condensed water that is condensed while being heat exchanged through the main heat exchanger 26 is introduced into the condensate receiver 10 having a siphon structure connected to the bottom of the exhaust duct 22 of the exhaust unit 20 to remain at a predetermined water level, thereby condensing water outlet 14. While the discharge flow of the condensate is made to be discharged through the outside, at the same time, the condensate excessively introduced into the condensate receiver 10 is configured to overflow through the overflow pipe (12).

As the condensate sealing ball 18 is buoyant to move according to the residual water level of the condensate as described above, the water level reference membrane 16a is formed to be space-closed so that a part of the exhaust gas flows into the room through the condensate receiver 10. The present invention, which is configured to be cut off without a control signal), first, condensed water of the exhaust gas condensed while being heat-exchanged by the main heat exchanger 26 during the initial operation or during the operation of the boiler to the condensate receiver 10 of the siphon structure. The condensate passing hole 16b of the level reference membrane 16a formed based on the level of the reference residual water level L through which the exhaust gas can pass even when the water level is not remaining may be sealed by the condensed water sealing ball 18. Therefore, space inflow of the exhaust gas can be blocked.

In addition, the condensed water from the exhaust unit 20 is continuously dropped and the water level rises above the reference residual water level (L) of the condensate receiver 10 through the condensate through hole 16b of the water level reference membrane 16a, and thus the condensate watertight ball ( 18) when the buoyancy is moved to open the condensate passage hole 16b of the water level reference membrane 16a, the reference residual water level L through which the exhaust gas can pass through is already filled by the condensate to be space-sealed. In this state, a part of the exhaust gas from the exhaust unit 20 can be cut off from flowing into the condensate receiver 10, and as a result, a part of the exhaust gas can be stopped without stopping the boiler due to the control signal of the main controller 30. Can be structurally prevented from entering the room through the condensate (10).

Unexplained reference numeral 24 denotes an exhaust port which is an outlet through which the exhaust gas burned is discharged to the outside through the exhaust unit 20.

As described above, according to the exhaust gas blocking device of the condensate receiver for a gas boiler according to the present invention, the condensate receiver of the exhaust gas condensed while being heat-exchanged to be absorbed by the latent heat of condensation during the initial operation of the boiler or during operation is condensate receiver of the siphon structure. Even if the water level does not remain at the water level, the water level reference membrane is space-sealed by the condensed water sealing ball, so that part of the exhaust gas flows into the condensate tray without power. The effect is provided.

Claims (1)

Condensation latent heat generated by condensing below the dew point temperature by passing the exhaust gas lost to the air at high temperature during combustion to the cold part of the main heat exchanger (26) to increase the heating efficiency of the boiler. Thus, the heat exchanged through the main heat exchanger (26) downwards to the middle portion where the discharge flow of the condensate is switched so that a part of the exhaust gas discharged to the outside is prevented from entering the room through the condensate receiver 10 of the siphon structure. As the curved condensate through hole (16b) is formed through the central level of the water level membrane (16a), and the condensate water sealing ball (18) having excellent buoyancy above the condensate through hole (16b) of the water level reference membrane (16a) is installed The condensate passing hole (16b) around the reference residual water level (L) is characterized in that it is configured to be space-sealed by the condensate and the condensate water ball (18) Condensate exhaust gas shutoff device for gas boilers.