KR101156287B1 - Water drain system of cistern with a one body sipon - Google Patents

Abstract

The present invention relates to a neutralizer integrated system, and in particular, the neutralizer and the system can be integrated to reduce the overall size and the number of parts, and to share the water channel, and the neutralizer can be heated without installing a separate draining device. The complex connection of condensate is invented to draw out the water inside the neutralization chamber with a simple operation.

The configuration of the present invention is provided with a heating return inlet 131 and the heating return outlet 132, the heating water tapping line 150 is penetrated and has a storage body having a storage space 101 to store the heating return therein With 100,

Located in the upper portion of the cistern body 100, it is blocked by the partition wall 210 is filled with a neutralizing agent, the passage 220 is opened in the upper portion of the partition wall 210 to communicate with the storage space 101. Chinese room 200 which becomes,

A condensate connector 300 installed through the neutralization chamber 200 in a hollow tube shape to induce condensate generated by the secondary heat exchanger to be moved into the neutralization chamber 200, and having holes 301 drilled in the lower portion thereof; ,

It is provided with an overflow outlet 500 for discharging the overflowed water in the storage space 101 and the neutralization chamber 200,

The connection protrusion 211 is erected on the bottom surface of the partition wall 210 of the neutralization chamber 200 so that the fitting portion 310 of the condensate connector 300 is fitted thereto, and the drainage hole 212 is interposed between the connection protrusions 211. ) Are pierced.

Cistern, China, Neutralizer, Drainage, Heating water, Condensate, Connector, Overflow, Draining,

Description

Heavy water integrated system {water drain system of Cistern with a one body sipon}

The present invention relates to a neutralizer integrated system, and in particular, the neutralizer and the system can be integrated to reduce the overall size and the number of parts, and to share the water channel, and the neutralizer can be heated without installing a separate draining device. The complex connection of condensate is invented to draw out the water inside the neutralization chamber with a simple operation.

In general, a boiler heats water by using combustion heat generated when burning fuel, and circulates the heating pipe installed in the room by a circulation pump for forcibly circulating the heated and regenerated water to heat the room. In addition, it is a device that supplies hot water to bathrooms and kitchens.

These boilers can be divided into various types according to the control method or the sealed state, and can be divided into condensing and non-condensing types according to the heat source for heating the heating water.

The condensing method refers to having a latent heat exchanger that maximizes thermal efficiency by absorbing the latent heat of condensation of the exhaust gas passing through the sensible heat exchanger together with the sensible heat exchanger that directly heats the heating water by using the heat burned by the gas burner.

The non-condensing method means having only a sensible heat exchanger.

Condensing gas boilers each equipped with a sensible heat exchanger and a latent heat exchanger can be classified into a downward combustion method in which gas moves downward to supply heat and an upward combustion gas boiler in which heat is supplied upward while supplying heat. .

1 is a view showing the internal structure of a conventional general upward combustion condensing gas boiler.

As shown in FIG. 1, a gas boiler using gas as a fuel in an upward combustion condensing boiler uses a gas introduced through a gas supply pipe 11 to generate heat in the combustion chamber 20. 10) and the sensible heat exchanger (30) that receives the heat of the gas burner (10) and heats the heating water moving to the sensible heat pipe (31), and the latent heat by using the heat used in the sensible heat exchanger (30). The latent heat exchanger 40 is provided to provide latent heat to the heating water moving through the pipe 41.

That is, the sensible heat exchanger 30 is disposed above the gas burner 10, and the latent heat exchanger 40 is disposed above the sensible heat exchanger 30.

In addition, a condensate receiving partition wall 50 is formed between the sensible heat exchanger 30 and the latent heat exchanger 40 to receive condensed water formed in the latent heat exchanger 40. The central portion of the (50) is formed with a passage (51) for moving the heat from the sensible heat exchanger (30) to the latent heat exchanger (40), the condensate collected in the side portion of the condensate receiving partition wall (50) The neutralizer 60 is installed to discharge the.

In addition, one side of the inside of the gas boiler is provided with the cisterns tank 70 having a predetermined space to maintain the volume of the heating water is expanded.

The cisterne tank 70 is molded into a hollow tank shape with a synthetic resin material, and a predetermined amount of heating water is always stored therein.

When the condensing gas boiler having such a configuration is operated, the air is supplied to the upper portion through the air inlet 21 by the blowing fan (not shown), and the gas is supplied through the gas supply pipe 11 to the combustion chamber 20. The gas burner 10 installed in the lower portion of the ignition is to generate a flame.

Accordingly, the heat of combustion of the gas burner 10 is directly transmitted to the sensible heat exchanger 30 to heat the heating water flowing through the inner duct, and the latent heat exchanger 40 installed on the flow path of the exhaust duct is provided. The latent heat in the exhaust gas is recovered to heat the heating water.

In addition, the exhaust gas passing through the latent heat exchanger 40 is discharged to the outside through the exhaust port 80.

At this time, the condensate is generated in the process of recovering the latent heat of condensation from the latent heat exchanger (40). The condensate naturally falls to the lower side and is discharged to the outside through the pipe while being received by the condensate receiving partition wall (50). The neutralizer 60 is gathered.

On the other hand, the heating water received by the heat from the sensible heat exchanger 30 is finished heating the room while passing through the heating pipe 90, the heating water thus completed the heating through the water return and return pipe (91) The pressure is relieved by entering the turn tank 70 to generate a change in volume, and then supplied to the latent heat exchanger 40 through the water supply pipe 92 by the operation of the circulation pump (not shown), and then the sensible heat exchanger. Heated again while passing through (30) is moved back to the heating pipe 90 through the heating water transfer pipe (93).

By repeating this process, the heating water is circulated to perform the heating operation.

On the other hand, in the case of the conventional upward combustion condensing gas boiler, the neutralizer 60-sipon is configured and arranged separately from the cisterns tank 70.

Therefore, after the channel portion of the overflow tank and the drainage of the neutralizer 60 in the cisterns 70 is also configured separately, it must be piped separately by the connection system.

In addition, since the water draining portion of the neutralizer 60 is also configured separately, the utilization space in the product increases and manufacturing cost increases.

In addition, there may be a case in which a separate collection pipe and a discharge pipe for collecting the condensed water should be placed separately.

Therefore, this increases the area occupied by each component, and thus increases the size of the gas boiler product, and increases manufacturing costs, as well as increasing the number of assembly labor, since separate parts must be manufactured and assembled.

Accordingly, an object of the present invention is to provide a neutralizer integrated caster to reduce the number of parts and the total volume of the boiler by integrating the neutralizer and the tank in order to solve the conventional inconveniences and problems as described above. .

Another object of the present invention is to provide a neutralizer integrated system that can simplify the product by forming a simple channel in the cistern body without using the waterway unit and adding the draining structure of the neutralizer separately.

The present invention for achieving this purpose, the heating return inlet 131 and the heating return outlet 132 is provided, the heating water tapping line 150 is penetrated through the storage space 101 to store the heating return therein Cushion body having a 100 and,
Located in the upper portion of the cistern body 100, it is blocked by the partition wall 210 is filled with a neutralizing agent, the passage 220 is opened in the upper portion of the partition wall 210 to communicate with the storage space 101. Chinese room 200 which becomes,
A condensate connector 300 installed through the neutralization chamber 200 in a hollow tube shape to induce condensate generated by the secondary heat exchanger to be moved into the neutralization chamber 200, and having holes 301 drilled in the lower portion thereof; ,
It is provided with an overflow outlet 500 for discharging the overflowed water in the storage space 101 and the neutralization chamber 200,
The connection protrusion 211 is erected on the bottom surface of the partition wall 210 of the neutralization chamber 200 so that the fitting portion 310 of the condensate connector 300 is fitted thereto, and the drainage hole 212 is interposed between the connection protrusions 211. ) Is achieved by drilling.

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Here, the drain inlet 400 for connecting the interior of the neutralization chamber 200 and the secondary heat exchanger is provided.

The condensate connector 300 may be provided with an O-ring 311 to the position of the fitting portion 310 accommodated in the connection projection 211.

Here, the cistern body 100 is divided into an upper body 110, an intermediate body 120 and a lower body 130 to seal the boundary by heat bonding.

The water level sensor assembly holes 135 are drilled in the lower body 130, respectively.

The intermediate body 120 is connected to the heating water tapping line 150 is a temperature sensor assembly hole 151 for detecting the tapping temperature is drilled.

The upper body 110 is drilled with a water level electrode assembly hole 111 for detecting the water level inside the neutralization chamber 200.

In addition, the upper body 110 is formed with an injection port 230 for supplying a neutralizer into the neutralization chamber 200, it is sealed with a stopper 231.

On the other hand, the heating return inlet 131 formed in the lower body 130 is provided with a bubble separation wall 140, bubbles contained in the heating return hit the bubble separation wall 140 relatively bubbles that are dissolved in the heating return. Split it small so that it rises to the top.

The present invention made of such a structure is provided with a neutralization chamber 200 for accommodating the neutralizing agent into the interior of the body 100, it is possible to reduce the number of parts and the total volume of the boiler.

In addition, it is possible to simplify the product by forming a simple channel in the cistern body without adding a water channel structure and adding the drainage structure of the neutralizer.

Looking at the configuration and operation and effects of the present invention for achieving the above object with reference to the accompanying drawings as follows.

1 is a device diagram showing a circuit of a conventional gas boiler.

Figure 2 is a device diagram showing the interior of the boiler applied to the neutralization chamber 200 of the present invention body 100 of the present invention.

3 is an apparatus diagram showing an entire circuit of the present invention.

4 is an exploded perspective view showing a configuration in which the body 100 of the present invention is divided into an upper body 110, an intermediate body 120, and a lower body 130 and bonded to each other.

Figure 5 is an enlarged cross-sectional view of the neutralization chamber 200 is installed on the upper body 100 of the present invention.

6A and 6B are enlarged cross-sectional views illustrating main parts of draining from the neutralization chamber 200 by operating the condensate connector 300.

7A and 7B are enlarged cross-sectional views of main parts illustrating another embodiment of draining from the neutralization chamber 200 by operating the condensate connector 300.

The condensing boiler to which the present invention is applied is a gas burner that generates heat in the combustion chamber 20 by burning the gas as a gas boiler mainly using gas as a fuel among the upward combustion condensing boilers as shown in FIG. 3. 10) and the sensible heat exchanger 30 that receives the heat of the gas burner 10 to heat the heating water, and the latent heat to the heating water that moves through the pipe by using the heat used in the sensible heat exchanger 30. It is equipped with a latent heat exchanger 40 to provide.

In addition, a condensate receiving partition wall 50 is formed between the sensible heat exchanger 30 and the latent heat exchanger 40 to receive condensed water formed in the latent heat exchanger 40. Condensate collected in the side portion of the) is introduced into the neutralization chamber 200 through the condensate connector (300).

In addition, one side of the inside of the gas boiler is provided with a cistern body 100 having a constant storage space 101 to maintain the volume of the heating water is expanded, in the present invention to the upper side of the cistern body 100 The neutralization chamber 200 is integrally formed.

The cistern body 100 is divided into three stages and formed into an upper body 110 and a lower body 130, and an intermediate body 120 positioned therebetween. The intermediate body 120 and the lower body 130 are formed. Heating water tapping line 150 for passing the heating water in the bonded state is molded to penetrate.

In addition, the lower body 130 is provided with a heating return inlet 131 and a heating return outlet 132, respectively. Molding the turn body 100.

The partition wall 210 is formed at a distance from the substantially lower surface of the intermediate body 120 of the caster body 100 at a distance from the side wall (the left side wall of FIG. 5) to the space between the outer walls of the caster body 100. The neutralization chamber 200 in which the neutralizing agent is filled is formed.

At this time, the passage 220 is opened in the upper part of the partition 210 to communicate the storage space 101 and the neutralization chamber 200, and when the heating water overflows in the storage space 101, the neutralization chamber ( 200).

One side of the neutralization chamber 200 is provided with a condensed water connector 300 having a hollow tubular shape through the assembly hole 201.

The condensate connector 300 guides the condensate generated from the secondary heat exchanger using a hose and then falls down through the hollow interior to be collected into the neutralization chamber 200 through the hole 301.

Therefore, it can neutralize with the neutralizing agent which consists mainly of calcium carbonate filled in the neutralization chamber 200. As shown in FIG.

On the other hand, the neutralization chamber 200, the drain inlet 400 for connecting the secondary heat exchanger, the overflow to discharge the overflowed water from the storage space 101 and the neutralization chamber 200 of the cistern body 100 The outlet 500 is provided.

Therefore, water drained from the secondary heat exchanger may be induced into the neutralization chamber 200 through the drain inlet 400, and when the neutralized water or the heating water overflows inside the neutralization chamber 200, the overflow occurs. The circuit is formed to be discharged to the outside through the flow outlet (500).

Here, the inlet of the condensate connector 300 is disposed higher than the position of the overflow outlet 500 to prevent backflow to the heat exchanger.

Cushion body 100 according to the present invention is divided into the upper body 110, the intermediate body 120 and the lower body 130 by the difficulty of simultaneously molding integrally by the internal channel portion structure to open the boundary portion By adhering, it becomes possible to manufacture in the state in which a complicated channel, a channel | path, etc. were formed.

In the lower body 130 constituting the cistern body 100, the water level sensor assembly holes 135 for alarming the high water level and the low water level and the dangerous water level are drilled, respectively.

The intermediate body 120 is connected to the heating water tapping line 150, the assembly hole 151 of the temperature sensor for detecting the tapping temperature is drilled.

In addition, the assembly body 111 of the water level electrode for detecting the water level in the neutralization chamber 200 is drilled in the upper body 110.

The upper body 110 is formed with an injection port 230 for supplying a neutralizer into the neutralization chamber 200, and is sealed by a stopper 231.

On the other hand, the heating return inlet 131 formed in the lower body 130 is provided with a bubble separation wall 140, bubbles contained in the heating return hit the bubble separation wall 140 relatively bubbles that are dissolved in the heating return. Split it small so that it rises to the top.

That is, the bubble separation wall 140 is formed so that the upper side of the heating return inlet 131 side is blocked, so that the side is opened, bubbles contained in the heating return when the heating return flows into the system, the bubble separation wall It is to hit 140 and is separated into a relatively small bubble serves to prevent noise and rocking when the inlet of the heating return.

6A and 6B are enlarged cross-sectional views illustrating main parts of draining from the neutralization chamber 200 by operating the condensate connector 300.

That is, as shown in this figure, the connection protrusion 211 is erected on the partition wall 210 constituting the bottom surface of the neutralization chamber 200 so that the fitting portion 310 of the condensate connector 300 is fitted thereto. In the state where the lower end of the condensate connector 300 is connected to the connection protrusion 211 by drilling the drainage holes 212 between the drainage holes 211, the drainage holes 301 are blocked.

However, when the lower fitting portion 310 is artificially lifted by the condensate connector 300 and is removed from the connecting protrusion 211, the drainage hole 212 is opened to open the neutralization chamber 200 through the drainage hole 212. Water can be drained to the storage space 101 filled with heating return water.

At this time, the condensate connector 300 may be provided with an O-ring 311 to the position of the fitting portion 310 accommodated in the connection projection 211.

7A and 7B show another embodiment of the drain structure inside the neutralization chamber 200.

That is, the connection protrusion 211 connected to the lower end of the condensate connector 300 is connected to the drain pipe 230 connected to the outer side of the neutralization chamber 200, and the inside of the neutralization chamber 200 is operated by the operation of the condensate connector 300. May be drained to the outside.

1 is a device diagram showing a circuit of a conventional gas boiler.

Figure 2 is a device showing the interior of the boiler applied to the neutralizing chamber of the neutralization chamber of the present invention.

3 is an apparatus diagram showing an entire circuit of the present invention.

4 is an exploded perspective view showing a configuration in which the caster body of the present invention is divided and joined.

Figure 5 is an enlarged cross-sectional view of the neutralization chamber is installed on the upper body of the present invention.

6A and 6B are enlarged cross-sectional views of the main parts showing an embodiment of draining from the inside of the neutralization chamber by the operation of the condensate connector;

7A and 7B are enlarged cross-sectional views of main parts showing another embodiment of draining from the inside of the neutralization chamber by the operation of the condensate connector;

* Explanation of symbols used in the main part of the drawing *

10-burner 20-combustion chamber

30-sensible heat exchanger 40-latent heat exchanger

100-Cistern Body 110-Upper Body

120-Medium Body 130-Lower Body

140-Bubble separation wall 150-Heating water tapping line

200-China 210-Bulkhead

211-Splice 212-Drainage Hole

300-condensate connector 301-hole

310-fitting 400-drain inlet

500-overflow outlet

Claims (10)

A heating body inlet 131 and a heating return outlet 132 are provided, the heating body tapping line 150 penetrates the cistern body 100 having a storage space 101 to store the heating return therein, Located in the upper portion of the cistern body 100, it is blocked by the partition wall 210 is filled with a neutralizing agent, the passage 220 is opened in the upper portion of the partition wall 210 to communicate with the storage space 101. Chinese room 200 which becomes, A condensate connector 300 installed through the neutralization chamber 200 in a hollow tube shape to induce condensate generated by the secondary heat exchanger to be moved into the neutralization chamber 200, and having holes 301 drilled in the lower portion thereof; , It is provided with an overflow outlet 500 for discharging the overflowed water in the storage space 101 and the neutralization chamber 200, The connection protrusion 211 is erected on the bottom surface of the partition wall 210 of the neutralization chamber 200 so that the fitting portion 310 of the condensate connector 300 is fitted thereto, and the drainage hole 212 is interposed between the connection protrusions 211. ), A heavy fire integrated caster characterized in that the opening. A heating body inlet 131 and a heating return outlet 132 are provided, the heating body tapping line 150 penetrates the cistern body 100 having a storage space 101 to store the heating return therein, Located in the upper portion of the cistern body 100, it is blocked by the partition wall 210 is filled with a neutralizing agent, the passage 220 is opened in the upper portion of the partition wall 210 to communicate with the storage space 101. Chinese room 200 which becomes, A condensate connector 300 installed through the neutralization chamber 200 in a hollow tube shape to induce condensate generated by the secondary heat exchanger to be moved into the neutralization chamber 200, and having holes 301 drilled in the lower portion thereof; , It is provided with an overflow outlet 500 for discharging the overflowed water in the storage space 101 and the neutralization chamber 200, The connection protrusion 211 connected to the lower end of the condensate connector 300 is connected to the drain pipe 230 connected to the outer side of the neutralization chamber 200, and the condensate connector 300 operates in the neutralization chamber 200. A neutralizer integrated caster, characterized by draining water to the outside. The neutralizer integrated cistern according to any one of claims 1 to 3, wherein a drain inlet (400) for connecting the inside of the neutralization chamber (200) and the secondary heat exchanger is provided. The neutralizer integral type according to any one of claims 1 to 3, wherein the condensate connector 300 is provided with an O-ring 311 at a position of the fitting portion 310 accommodated in the connection protrusion 211. Cistern. The method of claim 1 or claim 2, wherein the cistern body 100 is divided into an upper body 110, the intermediate body 120 and the lower body 130 is configured to heat seal the boundary portion thereof The heavy weapon integrated cisterna which was characterized by the above-mentioned. The neutralizer integrated system of claim 5, wherein the water level sensor assembly holes (135) are respectively drilled in the lower body (130). The neutralizer integrated system of claim 5, wherein the intermediate body (120) communicates with the heating water tapping line (150) to drill a temperature sensor assembly hole (151) for assembling a tapping temperature detection temperature sensor. The neutralizer integrated system of claim 5, wherein a water level electrode assembly hole (111) through which the water level electrode for internal level detection of the neutralization chamber (200) is assembled is drilled in the upper body (110). The neutralizer integrated system of claim 5, wherein the upper body (110) is formed with an injection hole (230) for supplying a neutralizer into the neutralization chamber (200), and sealed with a stopper (231). The neutralizer integrated system of claim 5, wherein the heating return inlet 131 formed in the lower body 130 is provided with a bubble separation wall 140 in which bubbles included in the heating return hit.

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