KR100899405B1 - A water-trap of boiler - Google Patents

Abstract

A water trap for a boiler is disclosed. In the water trap provided in the boiler to drain the condensed water generated from the heat exchanger, the first partition is installed inside the body of the water trap to form a receiving portion for receiving the condensate and the drain portion is introduced into the water overflowed from the receiving portion And a neutralizer for neutralizing the condensed water in each of the receiving portion and the draining portion. The connector is formed to extend on the upper surface of the receiving portion side of the body of the water trap, and the condensate inlet is formed to extend to the lower side of the receiving portion of the body integrally with the connector so that the condensate flows into the receiving portion. The drain pipe extends from the bottom surface of the drain portion side of the body of the water trap to drain the water introduced into the drain portion. According to the water trap for the boiler according to the present invention, it is possible to neutralize the condensate water to neutral pH concentration and drain, and to insert a large amount of neutralizing agent to neutralize the condensate water, so that it can be used for a long time without replacing and adding neutralizing agent. By neutralizing the double, it is possible to neutralize the condensate with a high neutralization rate, it is easy to replace the neutralizing agent and cleaning the inside, it is possible to prevent the reverse flow caused by freezing and excessive inflow of rainwater.

Boiler, Water Trap, Condensate, Neutralizer, Backflow

Description

Water trap for boilers

The present invention relates to a water trap for a boiler, and more particularly, to a water trap for dewatering 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. The water vapor contained in the gas condenses below the dew point temperature and is discharged to the outside of the heat exchanger. The acidic condensate has an acidity of about PH3 to PH4. Not only did they have the problem that occurred, but if it was drained as it was, it caused environmental pollution.

9 is a front view illustrating main parts of a state in which a water trap is installed in a general condensing gas boiler.

Referring to FIG. 9, the existing water trap 100 is used to prevent corrosion and environmental pollution of boiler components generated by acidic condensate drainage. That is, the condensed water generated from the heat exchanger 110 is typically passed through the water trap 100, in which the water trap 100 is a fresh water to drain the condensate so that the combustion gas is not exhausted. The water trap 100 is a connection hose 112 of the connecting pipe 104 is formed from the upper portion of the body 102 to the inner lower side so that the condensed water can be introduced from the heat exchanger 110 of the condensing gas boiler 1. It is connected to the upper side, and the water overflows by the water tank 120 and the connection hose 122 is connected to the interior of the body 102 so that some part is introduced into the body 102 and some can be immediately discharged The connecting pipe 106 and the drain pipe 108 are configured to be integrally formed.

10 is a partially exploded perspective view schematically showing a conventional water trap for a boiler.

Referring to FIG. 10, the conventional water trap 200 for a boiler is formed in the body 210 to accommodate an accommodation space 220 for accommodating water, and the connector 240 is formed on an upper surface of the body 210. Is formed extending to perform the function of introducing the condensate generated from the soft exchanger 110 to the body 210, the condensate inlet 250 is integrally coupled with the connector 240 and formed to extend to the lower side of the body 210 It performs the function of introducing the condensed water into the receiving space 220. The auxiliary connector 260 is formed upward to be connected to the receiving space 220 on the upper side of the body 210 to perform the function of introducing the overflowed water from the water tank 120 into the body 210 and , The drain pipe 280 is formed integrally with the auxiliary connector 260 and the body 210 of the body 210 so that the water introduced through the auxiliary connector 260 and the water filled in the receiving space 220 can be drained The upper one side is extended downward.

The conventional water trap 200 for the boiler receives the condensate generated during the heat exchange process through the connector 240 and the condensate inlet 250 and gradually fills it in the receiving space 220 in the body 210. In addition, the existing water trap 200 for the boiler receives the overflowed water from the water tank through the auxiliary connecting pipe 260, and partly drains directly through the drain pipe 280, the rest to the receiving space 220 Inflow. The existing water trap 200 for the boiler drains the fresh water in the body 210 through the drain pipe 280.

In addition, the existing water trap 200 needs to be supplied with water separately to replenish the amount of fresh water in the body 210 from the outside into the body 210 as needed.

The technical problem to be achieved by the present invention is to neutralize and drain condensate to neutral PH concentration, and to insert a large amount of neutralizing agent to neutralize the condensate can be used for a long time without the replacement and addition of neutralizing agent to double the neutralization in the process of draining condensate The present invention provides a water trap for a boiler that neutralizes condensate with a high neutralization rate.

Another technical problem to be achieved by the present invention is to provide a water trap for a boiler that is easy to replace and neutralize the neutralizer to neutralize condensate.

Another technical problem to be achieved by the present invention is to provide a water trap for a boiler for preventing a backflow caused by freezing, excessive inflow of rain water.

In order to achieve the above technical problem, a water trap for a boiler according to the present invention includes a water trap provided in a boiler to drain condensate generated from a heat exchanger, wherein a first partition is installed therein to accommodate the condensate. A body having a receiving portion and a drain portion into which water overflowed from the receiving portion is introduced, and a neutralizing agent neutralizing the condensed water is attached to each of the receiving portion and the drain portion; A connector extending from the upper surface of the receiving portion side of the body; A condensate inlet formed integrally with the connector to extend below the receiving portion of the body to allow the condensate to flow into the receiving portion; And a drain pipe extending from the bottom surface of the drain portion side of the body to drain water introduced into the drain portion.

Preferably the water trap for the boiler according to the invention further comprises a lid formed detachably coupled to the upper surface of the body.

Preferably, the water trap for the boiler according to the present invention further includes a filter provided inside the drainage unit to prevent discharge of the neutralizing agent and to transmit water.

Preferably, a second partition having a filter that prevents the discharge of the neutralizing agent and penetrates the water at an upper side thereof is installed downward from an upper surface of the drain side of the body, and the drain is located between the first and second partitions. The neutralization drainage portion is divided into a high speed drainage portion located between the side surfaces of the second bulkhead and the body, and the neutralization drainage portion is mounted on the neutralization drainage portion.

Preferably, the water trap for the boiler according to the present invention surrounds the outer periphery of the condensate inlet and is formed to be able to block or introduce water into the receiving portion, and when the lower surface is blocked, the condensate introduced from the condensate inlet is filled. And a temporary accommodating part configured to flow into the accommodating part when the filled condensed water overflows.

According to the water trap for the boiler according to the present invention, it is possible to neutralize the condensate water to neutral pH concentration and drain, and to insert a large amount of neutralizing agent to neutralize the condensate water, so that it can be used for a long time without replacing and adding neutralizing agent. By neutralizing the double, it is possible to neutralize the condensate with a high neutralization rate, it is easy to replace the neutralizing agent and cleaning the inside, it is possible to prevent the reverse flow caused by freezing and excessive inflow of rainwater.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the water trap for the boiler according to the present invention.

1 is a perspective view schematically showing a preferred embodiment of the water trap for the boiler according to the present invention, Figures 2a and 2b schematically shows a preferred embodiment for the water trap for the boiler according to the present invention, respectively One main side cross-sectional view and a main flat cross-sectional view, FIGS. 3A and 3B show a main side cross-sectional view and a main flat cross-sectional view, respectively, schematically showing another preferred embodiment of a water trap for a boiler according to the present invention.

1 to 3b, the water trap 300 for the boiler according to the present invention is provided in the boiler to dehydrate a certain amount of condensate generated from the heat exchanger and to drain the fresh condensate to the outside of the boiler. To this end, the water trap 300 for the boiler according to the present invention includes a body 310, a first partition 320, a receiving part 330, a draining part 340, a connector 350, a condensate inlet 360, and a drain pipe. 370 and a lid 380.

When the body 310 has a shape that can be easily connected to the connection tube of the heat exchanger while having a minimum occupied area at the time of installation, for example, the body 310 may be in the form of a square, a memory box, a needle-shaped box, the body ( The first partition 320 is provided inside the 310, and the interior of the body 310 is bisected into the receiving part 330 and the drainage part 340 by the first partition wall 320.

The first bulkhead 320 is installed upward from the bottom surface of the body 310 so that a gap having a predetermined size is formed between the first bulkhead 320 and the lid 380. Through the water flows between the receiving portion 330 and the drain 340.

Receiving unit 330 is filled with the condensed water introduced from the condensate inlet 360. In addition, the receiving unit 330 is equipped with a neutralizing agent 532 to neutralize the condensate to neutralize the filled condensate. When the condensate flowing from the condensate inlet 360 continues to be filled in the receiving part 330, and the level of the condensate reaches the height of the first partition 310, the condensate overflows and flows into the drain 340. . Therefore, the receiving unit 330 may neutralize the condensate with the neutralizer 532 for a long time until the condensate overflows and flows into the drain 340.

The drain 340 allows the condensate overflowed from the receiver 330 to flow into the drain 370. In addition, the drain 340 is equipped with a neutralizing agent 542 to neutralize the condensate neutralizes the condensate in the process of free-falling the condensate overflowed from the receiving portion 330. The drain 340 includes a filter 342 therein for preventing the discharge of the neutralizer 546 and permeating water to support the neutralizer 546. The filter 342 is formed in parallel with the bottom surface 312 of the body, for example, at the lower side of the drainage portion 340 and may be in close contact with the bottom surface 312 of the body or form a gap 344 having a predetermined height. Can be.

The connector 350 performs a function of being coupled with a connecting tube connecting between the heat exchanger and the body 310. In one embodiment for this purpose, the connector 350 is formed to extend on the upper surface of the receiving portion 330 side of the body 310, and has a structure that can be inserted into the coupling tube connecting between the heat exchanger and the body 310 inward. Can be. And the condensate inlet 360 is integrally coupled with the connector 350 and formed to extend below the receiving portion 330 of the body 310 to perform the function of introducing the condensate generated from the heat exchanger into the receiving space 330. do.

The drain pipe 370 drains the water introduced into the drain 340. In one embodiment for this purpose is formed extending to the lower surface of the drain portion 340 side of the body (310). That is, the condensed water introduced into the drain 340 freely falls into the drain pipe 370, and the condensed water introduced into the drain pipe 370 is neutralized by the neutralizer 546, passes through the filter 342, and drain pipe 370. To the outside of the boiler.

Figure 4 is an exploded perspective view schematically showing a preferred embodiment of the water trap for the boiler according to the present invention.

Referring to FIG. 4, the lid 680 is formed on the upper surface of the body 610 to be detachably coupled, and covers the upper surface of the body 610 to prevent any discharge of the neutralizing agent and the introduced condensate inside the body 610. And protect the interior of the body 610. In addition, the lid 680 may be formed with an insertion groove for inserting the connector 650 or may be integrally formed with the connector 650 and the condensate inlet 660. In addition, the lid 680 can be easily removed from the body 610 to replace the neutralizing agent neutralizing the condensed water mounted in the body 610 and collected on the bottom surface of the receiving part 660 and the draining part 640. Foreign matters can be smoothly removed and at the same time can be easily cleaned inside. Therefore, the boiler water trap 600 according to the present invention has an effect of easy replacement and neutralization of the neutralizer to neutralize the condensate.

Figure 5 is a front view showing the main portion showing an embodiment of a state in which the boiler water trap according to the present invention is installed in the condensing gas boiler.

Referring to FIG. 5, the water trap 700 for a boiler according to the present invention receives the condensed water generated during the heat exchange process of the heat exchanger 701 through the connector 750 and the condensed water inlet 360, and the body 710. The inner receiving portion 330 is gradually filled. At this time, since the condensate inlet 360 is located at the lower side of the accommodating part 330, the combustion gas exhausted like the condensate is not discharged, and only the condensate is filled in the accommodating part 330 and then drained. Water filled in the accommodating part 330 is fresh water in the accommodating part 330 and then flows into the drain part 340 when an overflow occurs. The condensed water introduced into the drain 340 eventually flows into the drain pipe 770 and is drained out of the boiler.

The water trap 300 for the boiler according to the present invention may be equipped with a neutralizing agent in the accommodating part 330 and the draining part 340 to neutralize and drain the condensed water to neutral PH concentration, and the accommodating part 330 and the draining water. Each of the portions 340 neutralizes the condensate, and thus the condensate may be neutralized at a high neutralization rate.

In addition, as a result of the experiment, the water trap 300 for the boiler according to the present invention decreases with time, so that the boiler water trap 300 according to the present invention can be used for more than 5 years without replacing and adding the neutralizer. Considering the amount of neutralizing agent decreases over time, sufficient neutralizing agent should be installed in the water trap 300 for the boiler according to the present invention. Furthermore, since the boiler water trap 300 according to the present invention should maintain the minimum amount of neutralizer required to maintain an appropriate neutralization function, it is necessary to install the neutralizer in consideration of this, and the boiler water trap 300 according to the present invention. ) Can maintain an adequate neutralization function for more than five years. Here, since the boiler water trap 300 according to the present invention may be equipped with a large amount of neutralizing agent of 800g or more in the receiving portion 330 and the drainage portion 340, the boiler water trap 300 according to the present invention is replaced with the neutralizer And long term use without addition.

Figures 6a and 6b is a side sectional view and a main part sectional view schematically showing another preferred embodiment of the water trap for the boiler according to the present invention, respectively.

6A and 6B, the boiler water trap 800 according to the present invention further includes a second partition 890, a neutral drainage part 842, and a high speed drainage part 848.
Since the connector 850, the condensate inlet 860, and the lid 880 have the same configuration as the connector 350, the condensate inlet 360, and the lid 380 illustrated in FIG. 2A, detailed descriptions thereof will be omitted.

The second partition 890 is provided with a first filter 892 in the upper portion to prevent the discharge of the neutralizing agent and permeate water, and is installed downward from the upper surface of the drain 840 side of the body 810. When the water level of the drain portion 840 reaches the height of the first partition wall 820 due to freezing, excessive inflow of rainwater, etc., the water overflowed from the receiving portion 830 and flows into the drain portion 840 is first. It is introduced into the filter 892.

The neutralization drainage unit 842 is positioned between the first partition 820 and the second partition 890 and mounts a neutralizer. In addition, the neutralization drainage unit 842 may include a second second filter 844 for preventing the discharge of the neutralizing agent and permeating water therein to support the neutralizing agent. For example, the second filter 844 may be formed in parallel with the bottom surface 812 of the body 810 from the lower side of the second partition 890 to the first partition 820. A gap 846 is formed at the height of.

The high speed drainage part 848 is located between the side surfaces of the second partition 890 and the body 810, and the inside thereof is empty. Therefore, the water introduced into the high speed drainage unit 848 through the first filter 892 is freely dropped into the drain pipe 870 without interfering with other obstacles.

Usually, the water I ₁ overflowed from the receiving portion 830 flows into the neutralization drainage portion 842 and is neutralized by the neutralizing agent, and passes through the second filter 844 to the drain pipe 870. Water I ₁ introduced into the drain pipe 870 is discharged to the outside of the boiler through the drain pipe 870. However, when a situation in which reverse flow may occur due to freezing, excessive inflow of rainwater, etc. occurs, the overflowed water I ₂ from the receiving portion 830 passes through the first filter 892 to the high speed drainage portion 848. It is introduced and flows quickly into the drain pipe 870 through the high speed drain 848. Therefore, the water trap 800 for the boiler according to the present invention can prevent the reverse flow caused by freezing, excessive inflow of rain water.

Figures 7a and 7b is a side sectional view and a main sectional view schematically showing another preferred embodiment of the water trap for the boiler according to the present invention, respectively.

7A and 7B, the boiler water trap 900 according to the present invention further includes a temporary receiving part 932.

The temporary receiving part 932 surrounds the outside of the condensate inlet 960 and the lower surface 934 of the temporary receiving part 932 is formed to allow water to enter or block the receiving part 930, and the temporary receiving part 932 The top surface 936 of) is open. When the lower surface 934 of the temporary receiving part 932 is blocked, the condensed water introduced from the condensate inlet 960 is filled, and when the lower surface 934 of the temporary receiving part 932 is opened, the condensate inlet 960 is opened. It is introduced into the condensate receiving portion 930 introduced from. In addition, when the water level of the condensed water filled with the condensate is continuously filled in the temporary receiving part 932 and reaches the lower surface 934 of the temporary receiving part 932, an overflow occurs and the overflowed water I ₃ is Flow into the receiving portion (930).

The lower surface 934 of the temporary receiving part 932 is blocked in case of excessive inflow of freezing and rainwater, and condensate filled in the receiving part 930 flows into the condensate inlet 960 and is discharged to the connector 950. To prevent. That is, when a situation in which reverse flow may occur due to freezing or excessive inflow of rainwater occurs, the water (I ₃ ) flowing into the condensate inlet 960 is filled in the temporary receiving unit 932, and the level of the filled water is increased. When the overflow occurs, the overflowed water flows into the receiving portion 930, and the water I ₃ introduced into the receiving portion 930 moves upwards without passing through the neutralizer and flows into the drainage portion 940. . Therefore, the water trap 900 for the boiler according to the present invention can prevent the reverse flow caused by freezing, excessive inflow of rain water.

Figures 8a and 8b is a side sectional view and a main part sectional view schematically showing another preferred embodiment of the water trap for the boiler according to the present invention, respectively.

8A and 8B, the water trap 1000 for the boiler according to the present invention further includes a temporary receiving part 1032, a second partition 890, a neutralizing draining part 842, and a high speed draining part 848. do. Temporary accommodation portion 1032, second bulkhead 890, neutralization drainage portion 842 and high speed drainage portion 848, respectively, the temporary accommodation portion 932 and the present invention of the boiler water trap 900 according to the present invention The second bulkhead 890, the neutralization drainage part 842, and the high speed drainage part 848 of the boiler water trap 800 according to the same or the same components as detailed description thereof will be omitted.

When a situation in which reverse flow may occur due to freezing, excessive inflow of rainwater, and the like, water (I ₄ ) flowing into the condensate inlet 860 is filled in the temporary receiving part 1032, and the level of the filled water is increased. When the flow occurs, the overflowed water (I ₄ ) is introduced into the receiving portion 830, the water (I ₄ ) introduced into the receiving portion 830 is moved to the upper portion without passing through the neutralizer to drain 840 Flows into. The water I ₄ introduced into the drain 840 passes through the first filter 892 and flows into the high speed drain 848 and quickly flows into the drain pipe 870 through the high speed drain 848. The water I ₄ introduced into the drain pipe 870 is drained out of the boiler through the drain pipe 870. Therefore, the water trap 1000 for the boiler according to the present invention can prevent the reverse flow caused by freezing, excessive inflow of rain water.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific preferred embodiments described above, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Various modifications can be made by those skilled in the art, and such changes are within the scope of the claims.

Water trap for the boiler according to the present invention can be manufactured in a form that can be provided in the boiler, it can be used to neutralize and drain the condensate generated in the heat exchanger of the boiler.

1 is a perspective view schematically illustrating a main part of a preferred embodiment of a water trap for a boiler according to the present invention;

Figure 2a is a side cross-sectional view schematically showing a preferred embodiment of the water trap for the boiler according to the present invention,

Figure 2b is a schematic top cross-sectional view showing another preferred embodiment of the water trap for the boiler according to the present invention,

Figure 3a is a side cross-sectional view schematically showing another preferred embodiment of the water trap for the boiler according to the present invention,

Figure 3b is a schematic top cross-sectional view showing another preferred embodiment of the water trap for the boiler according to the present invention,

4 is an exploded perspective view schematically showing a preferred embodiment of the water trap for the boiler according to the present invention;

Figure 5 is a front view showing the main part showing an embodiment of a state in which the boiler water trap according to the present invention installed in the condensing gas boiler,

Figure 6a is a side cross-sectional view schematically showing another preferred embodiment of the water trap for the boiler according to the present invention,

6b is a cross-sectional plan view schematically illustrating a main part of another preferred embodiment of a water trap for a boiler according to the present invention;

Figure 7a is a side cross-sectional view schematically showing the other preferred embodiment of the water trap for the boiler according to the present invention,

7b is a cross-sectional plan view schematically showing a main portion of another preferred embodiment of a water trap for a boiler according to the present invention;

8a is a side sectional view schematically showing a main part of another preferred embodiment of a water trap for a boiler according to the present invention;

8b is a cross-sectional plan view schematically showing a main portion of another preferred embodiment of a water trap for a boiler according to the present invention;

9 is a front view of a main part showing a state in which a water trap is installed in a general condensing gas boiler, and

10 is a partially exploded perspective view schematically showing a conventional water trap for a boiler.

Claims (5)

In the water trap provided in the boiler for draining the water generated from the heat exchanger, The first partition 820 is installed therein, and an accommodating part 830 in which the condensed water is accommodated and a draining part 840 into which the overflowed water flows from the accommodating part 830 are formed, and the accommodating part 830 is provided. And a body 810 to which neutralizers for neutralizing the condensate are mounted in each of the drains 840. A connector 850 extending on the upper surface of the receiving portion side of the body; A condensate inlet 860 integrally formed with the connector 850 so as to extend below the receiving portion of the body to allow the condensed water to flow into the receiving portion 830; And A drain pipe 870 extending on a lower surface of the drain 840 side of the body 810 to drain water introduced into the drain 840 to the outside; The drain 840, On the upper side and the lower side, a second partition 890 having a first filter 892 and a second filter 844 formed therein to prevent discharge of the neutralizing agent and penetrate water is installed therein, so that the first partition 820 and The neutralization drainage part 842 and the second partition wall disposed between the second partition wall 890 and neutralized with water and discharged through the second filter 844 after neutralizing the overflowed water from the accommodation part. Located between the 890 and the side of the body water trap for the boiler, characterized in that it is divided into a high speed drainage portion 848 for discharging the water flowing through the first filter (892) to the outside. The method of claim 1, Water trap for the boiler characterized in that it further comprises a lid 880 formed on the upper surface of the body 810 is detachably coupled. delete delete The method of claim 1, The lower surface of the condensate inlet 860 surrounds the outer surface of the condensate inlet 860 and is formed to be capable of inflowing or blocking the water. Water trap for the boiler further comprises; a temporary receiving portion (1032) to be introduced into the receiving portion (830) when the filled condensate overflows.

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