KR20110137119A - A water-trap of a boiler - Google Patents

Abstract

PURPOSE: A water trap for a boiler is provided to prevent condensate from backward flowing from a compartment to a heat exchanger by forming a second inlet unit. CONSTITUTION: A water trap for a boiler comprises a main body(10), a cover(20), and a second inlet unit(30). The main body comprises a water containing unit(11), a filter unit(12), and a drainage unit(13). The water containing unit accepts condensate flowing from a heat exchanger of a gas boiler and neutralizes the condensate using a neutralizing agent. The filter unit filters impurities through filters(121) and vertically moves the condensate. The drainage unit discharges the condensate to the outside. The cover has a first inlet(21) for flowing the condensate from the heat exchanger to the main body. The backward flowing condensate re-flows into the main body through the second inlet.

Description

A water-trap of a boiler

The present invention relates to a boiler water trap, and more particularly, to a water trap for dewatering, purifying and draining condensate generated from a heat exchanger of a boiler.

Generally, various types of boilers are installed in the home as a means of receiving heating and hot water, and these boilers have a combustion unit for igniting and burning a large supply of fuel, and the amount of heat generated from the combustion unit. It is divided into a heat exchanger that transmits to a high temperature state, and a heating pipe that circulates and supplies heating water heat exchanged at high temperature for heating and hot water supply, and is divided into a gas boiler and an oil boiler according to the fuel used during combustion. It is done.

On the other hand, in recent years, condensing gas boilers having a heat exchanger composed of a sensible heat exchanger and a latent heat exchanger have been popularized so as to maximize thermal efficiency with minimal fuel consumption. Water vapor contained in the gas condenses below the dew point temperature and is discharged to the outside of the heat exchanger.

The acidity of the condensate is about pH 3 to pH 4, which is not only a problem of corrosion when it comes in contact with the components constituting the boiler, but also causes environmental pollution when drained as it is.

Accordingly, in order to prevent corrosion and environmental pollution of boiler components generated by acid condensate drainage, condensate discharged from the heat exchanger was drained through a device equipped with a separate neutralizer.

4 is a schematic main perspective view of a device with a conventional neutralizer.

Referring to FIG. 4, the prior art includes a plurality of partitions 16 into which condensed water is introduced into the body tank 10, wherein each of the partitions is formed lower than the height of the body tank 10. Each of the partition walls 16 includes a detachable filter 20 having a hole formed at one side thereof, and the filter 20 is provided such that holes are alternately positioned at an upper side and a lower side thereof. It is neutralized in the third by the neutralizer filled in the body tank 10 while moving the hole formed in the up and down.

However, the above-described prior art has a deterioration in neutralization performance after a certain period of time due to foreign matter such as combustion products or dust in the combustion exhaust gas accumulated in the condensate, and condensate flows back into the boiler due to a malfunction of the water trap due to blockage. There was a problem.

The present invention has been made to solve the above problems and the present invention is to provide a boiler water trap that prevents the back flow of condensate flowing into the heat exchanger and at the same time to allow the back flow of the condensed water back into the water trap. do.

In addition, an object of the present invention is to provide a boiler water trap in which the condensed water flowed back in sequence to extend the retention time of the condensed water.

In addition, an object of the present invention is to provide a boiler water trap that prevents foreign matter contained in the backflow condensate from flowing back.

It is also an object of the present invention to provide a boiler water trap that prevents backflow of condensate and provides smooth drainage.

The present invention accommodates condensate introduced from the heat exchanger of the gas boiler and the neutralizing agent is mounted therein to neutralize the condensate, and divides the freshwater into four compartments, and filters foreign substances by filters formed at the upper and lower ends thereof. A main body having a filter part for moving the condensate up and down and a drain part for draining the condensate to the outside;

A cover having a first inlet for introducing condensate from the heat exchanger;

It characterized in that it comprises a second inlet for introducing the condensed water back to the filter blocked by the foreign matter.

The second inlet of the present invention is characterized in that the stepped membrane is formed so that the condensed water is sequentially introduced.

The second inlet of the present invention is characterized in that a filter is formed on the surface corresponding to each compartment.

The drain portion of the present invention is characterized in that the discharge hole for preventing the back flow of condensate formed.

The present invention employs a second inlet to prevent condensate flowing back from each compartment from entering the heat exchanger, and at the same time, the reversed condensate flows back into each compartment, purifies and drains the condensate backflow. It is effective to prevent damage to other parts by the environmental pollution caused by the drainage of condensate.

In addition, the present invention has the effect of further increasing the retention time of the condensate by further increasing the retention time of the condensate by adopting a second inlet portion is formed with a stepped membrane to sequentially enter the condensate into the compartment.

In addition, the present invention has an effect of further preventing environmental pollution by installing a filter in each of the compartments as well as the second inlet to drain foreign matter.

In addition, when the internal pressure of each compartment is increased by the exhaust gas pressure when the neutralizing agent is filled in each of the deletions, the present invention exhausts the air through the discharge hole to prevent backflow and smooth drainage.

Alternatively, even when the condensate is not drained smoothly through the drainage due to rain or a large amount of condensate, the condensate that has flowed back is drained to the outside through the discharge hole to prevent backflow of condensate contained in the compartment and to smoothly drain the condensate. It is effective.

1 is an exploded perspective view of a preferred embodiment of the present invention.
2 is a partially perspective view of the embodiment of FIG.
3 is a partial perspective view of the embodiment of FIG.
4 shows a prior art.

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

1 shows an exploded perspective view of a preferred embodiment of the present invention, FIG. 2 shows a partial perspective view of the embodiment of FIG. 1, and FIG. 3 shows a partial perspective view of the embodiment of FIG. 2.

The present invention partitions the fresh water part 11 and the fresh water part 11 into four compartments 111, 112, 113, and 114 to accommodate condensate introduced from the heat exchanger of the gas boiler and to neutralize the condensate with a neutralizer 40 mounted therein. The main body 10 having a filter part 12 alternately filtering the foreign matter with the filter 121 formed at the upper and lower ends, and a drain part 13 through which the condensate is drained to the outside,

A cover 20 having a first inlet 21 for introducing condensate from the heat exchanger;

The filter 121 is blocked by the foreign matter, characterized in that it comprises a second inlet 30 for flowing back the condensate.

The fresh water part 11 is partitioned into four compartments 111, 112, 113, and 114 by the filter part 12 as a place for fresh water condensed water introduced from the first inlet part 21. The fresh water part includes a first compartment 111 connected to the first inlet 21 and a second compartment 112 through which condensed water flows from the first compartment 111, and condensed water from the second compartment 112. The third compartment 113 and the third compartment 113 is introduced into the condensed water is introduced and the fourth compartment 114 is connected to the drainage portion 12.

In addition, the filter unit 12 may be configured to partition the first filter unit 12a and the second compartment 112 and the third compartment 113 that partition the first compartment 111 and the second compartment 112. The second filter part 12b, and the 3rd filter part 12c which divides the 3rd compartment 113 and the 4th compartment 114 are included.

The filter part 12 is detachable by slidingly coupled with the partition wall 16 and the main body 10 formed in the center of the main body 10, and because each filter part 12 is manufactured in the same shape, the manufacturing cost is high. There is a saving effect.

The partition 16 is formed with an assembly groove 161 to which the first filter part 12a, the second filter part 12b, and the third filter part 12c are coupled, and the first compartment 111 and The fourth compartment 114 is partitioned.

An assembly groove 15 is formed on an inner side surface of the main body 10 to correspond to the assembly groove 161 of the partition 16.

Therefore, the respective filter units 12 are coupled to and separated from each other by sliding on both sides of the assembly grooves 161 and 15.

The filter 121 is installed at the lower end of the first filter part 12a and the third filter part 12c and the upper end of the second filter part 12b. The filter 121 is a means for removing foreign matter present in the condensate.

The condensed water introduced into the first inlet 21 is first neutralized by the neutralizing agent 40 filled in the first compartment 111 and moves to the second compartment 121 through the filter 121 installed at the lower end. .

The condensed water through the first filter part 12a is secondly neutralized by the neutralizer 40 filled in the second compartment 112 and moves to the third compartment 113 through the filter 121 installed at the upper end.

The condensed water through the second filter part 12b is neutralized by the neutralizer 40 filled in the third compartment 113 and moved to the fourth compartment 114 through the filter 121 installed at the bottom. It is drained to the outside through the drain 13.

The condensed water introduced into the water trap 1 of the present invention is moved up and down alternately through each filter unit 12 to be neutralized three times, so that the condensed water can be sufficiently neutralized.

The neutralizing agent 40 filled in the freshwater part 10 is for neutralizing acidic condensate, and is filled except for the fourth compartment 114. However, the neutralizer 40 may be filled in the fourth compartment 114. The filler 40 may be composed of an alkaline material or an amphoteric metal such as aluminum, zinc, and tin.

The main body 10 accommodates condensate flowing from the heat exchanger in each compartment formed therein, and discharges the neutralized condensate through the drainage portion 13 to the outside of the boiler, such as a quadrangular shape, a memory shape, a needle shape, and the like. It may be formed in a box shape.

The cover 20 is detachably coupled to the upper end of the main body to prevent random discharge of the neutralizer 40 and the condensed water in the main body 10, and to protect the inside of the main body 10. The first inlet 21 for introducing the is formed.

First, the coupling of the main body 10 and the cover 20 is a coupling protrusion 14 is formed at a predetermined interval on the upper side of the main body 10, the coupling protrusion 14 of the main body at the lower end of the cover 20 Coupling groove 22 is formed in the position corresponding to the coupling is coupled by the interference fit between the coupling projection 14 and the coupling groove 22, the first inlet 21 is It is formed larger than the main body so that the upper outer surface of the main body 10 can be tightly wrapped.

In an embodiment of the present invention, the first inlet 21 allows condensed water to flow into the compartment from the upper portion of the second inlet 30, but is not limited thereto. The lower portion of the main body passes through the second inlet 30. It can be formed to extend to.

In addition, the first inlet 21 is formed on the side opposite to the drain 13 so that the inflow of condensed water can be neutralized for a longer time.

The second inlet portion 30 is tightly coupled to surround the inner surface of the upper portion of the main body 10 from the lower portion of the cover 20, the inside is formed with a film 31 having a step so that condensed water is sequentially introduced The filter 32 is formed to correspond to each compartment. The filter 32 prevents foreign matter in the condensate that has flowed back into the other compartments 112, 113, and 114.

That is, the second inlet part 30 sequentially neutralizes the condensed water by introducing the condensed water into the second compartment 112 when the first compartment 111 is blocked by the foreign matter, and the second compartment 112 is blocked by the foreign matter. Condensed water is introduced into the third compartment 113 to be neutralized. When the third compartment 113 is blocked by foreign matter, the condensed water is introduced into the fourth compartment 114 to be drained through the drainage part 13.

According to an embodiment of the present invention, the third compartment 113 and the second compartment 112 and the third compartment 113 are not formed between the first compartment 111 and the second compartment 112 without forming a film 31. ) Is formed between the fourth compartment 114 and the fourth compartment 114 and the first compartment 111, but is not limited thereto, and the first compartment 111 and the second compartment 112 are not limited thereto. It is apparent that the film 31 can be formed even between the < RTI ID = 0.0 >

However, the height of the film 31 formed between the second compartment 112 and the third compartment 113 is between the third compartment 113 and the fourth compartment 114 and between the fourth compartment 114 and the first compartment ( Since the film 31 is formed to be lower than the height of the film 31 formed between the 111, the second compartment 112 and the third compartment when the film 31 is also formed between the first compartment 111 and the second compartment 112. It is preferable to form lower than the height of the film 31 formed between the (113).

By providing a step on the membrane 31, for example, the condensate flowing back from the first compartment 111 does not enter the third compartment 113 without passing through the second compartment 112.

The present invention employs a second inlet 30 to prevent backflow of condensed water into the heat exchanger, and at the same time to allow the backflowed condensate to be introduced into each of the compartments 112, 113, and 114 so as to be drained after purification. It is effective to prevent damage to other parts by the environmental pollution caused by the drainage of condensate.

The drainage portion 13 has a discharge hole 131 is formed to prevent the condensate flows back from the drainage portion 13 to flow into the compartments (112, 113, 114) when rain water, a large amount of condensate is generated,

The discharge hole 131 serves as an exhaust hole for exhausting air when the internal pressure of each compartment is increased by the exhaust gas pressure when the neutralizing agent is filled in each of the deletions, or the rainwater flows in due to the large amount of condensate or the drainage part 13. If the amount of condensate drained to) is large, it acts as a drainage hole for draining the condensate back to the outside.

The partition wall 132 formed in the drain portion 13 guides the discharged air or the backflow condensate to be discharged or drained to the discharge hole 131.

That is, during drainage, the condensate can be drained to the outside along the drainage path, and the discharged gas is discharged to the outside by the partition wall 132 and is not introduced into the compartment again. It is to prevent the backflow of condensate and to drain smoothly.

In addition, even in the case of backflow due to rainwater or a large amount of condensate, the condensate contained in the compartment flows back into the heat exchanger by being drained to the discharge hole 131 before being flowed back into the main body 10 by the partition 132. It is possible to drain a certain amount to the discharge hole 131 when a large amount is drained to prevent the drained water has an effect that can be smoothly drained.

On the other hand, the present invention is provided with a packing 50 that is pressed and coupled between the main body 10 and the cover 20 and the second inlet 30, the packing 50, the cover 20 and the first The packing groove 51 is coupled to the inlet portion 30 is formed.

The packing 50 is to increase the airtightness when the body 10 and the cover 20 and the second inlet 30 is coupled, the packing 50 is made of a material having elasticity, such as rubber.

Since the packing 50 prevents a gap between the coupling portion of the main body 10 and the cover 20 and the second inlet portion 30, the airtightness may be further improved.

Although the preferred embodiments of the present invention have been described above, the scope of the present invention is not limited to such specific embodiments, and those skilled in the art may appropriately change within the scope described in the claims of the present invention. This will be possible.

10: main body, 11: fresh water,
111: first compartment, 112: second compartment, 113: third compartment, 114: fourth compartment,
12: filter part, 121: filter,
12a: first filter portion, 12b: second filter portion, 12c: third filter portion,
13 drain, 131 discharge hole, 132 partition wall
14: engaging projection, 15: assembly groove,
16: bulkhead, 161: assembly groove,
20: cover 21: first inlet, 22: coupling groove,
30: second inlet, 31: membrane, 32: filter,
40: neutralizing agent, 50: packing, 51: packing groove

Claims (4)

The condensed water received from the heat exchanger of the gas boiler and a neutralizer 40 is mounted therein to divide the fresh water part 11 and the fresh water part 11 into four compartments 111, 112, 113, and 114, and neutralize the condensate. The main body 10 having a filter part 12 formed at the bottom thereof to filter foreign substances and a filter part 12 for moving the condensate up and down, and a drain part 13 for discharging the condensate to the outside;
A cover 20 having a first inlet 21 for introducing condensate from the heat exchanger;
Boiler water trap including a second inlet (30) for introducing the condensed water back to the filter 121 is blocked by foreign matters. The method according to claim 1,
The second inlet 30 is a boiler water trap, characterized in that the stepped film 31 is formed so that the condensed water is sequentially introduced. The method of claim 2,
The second inlet 30 is a boiler water trap, characterized in that the filter 32 is formed on the surface corresponding to each compartment. The method of claim 3,
The drain portion 13 is a boiler water trap, characterized in that the discharge hole 131 is formed to prevent the back flow of condensate.

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