KR100623921B1 - Drain trap for air handling unit - Google Patents

Abstract

The present invention smoothly discharges the water condensed by the dew point phenomenon generated during the heat exchange process with the surrounding air in the heat exchanger tube of the heat exchanger coil during the cooling operation or the dehumidification operation of the air conditioner, and at the same time, the drainage port is discharged to the outside. The present invention relates to a drain trap for an air conditioner that can block external air from flowing therein, wherein a heat exchange coil for exchanging a heat exchange medium is installed on a housing of an air conditioner, and the housing provided with the heat exchange coil is provided with a fresh water part. Condensed water and the heat exchanged water discharged from the heat exchange coil are collected in the fresh water part, and in the fresh water part of the housing, the drain trap is connected to the drain water pipe, and the inlet pipe of the boxed drain trap is connected to the drain pipe. The outlet pipe of the boxed drain trap is connected to the discharge pipe, and the boxed drain trap has a main body. After forming a first low water hammer plate and a second low water hammer plate on an inner upper surface thereof, the lower end thereof is spaced apart from the lower surface of the main body to form a first water seal point and a second water salvage point, and then the first low water hammer plate and the second low water hammer plate The invention can be achieved by forming a drain trap to form an overflow space connecting the first reservoir portion and the second reservoir portion while the upper end is spaced apart from the upper surface while forming a flooding plate integrated on the lower surface.

Air Conditioner, Heat Exchanger Coil, Drain Traps

Description

Drain trap for air handling unit

1 is a cross-sectional view showing a state of use of a conventional drain trap

Figure 2 is a perspective view showing a part of the use state of the drain trap according to the present invention

Figure 3 is a cross-sectional view of the use state showing the drain trap according to the present invention

Figure 4 is an enlarged longitudinal cross-sectional view of the drain trap according to the present invention

Explanation of symbols on the main parts of the drawings

100: air conditioner 110: housing

120: fresh water 130: bottom

140: bottom 200: heat exchange coil

300: drain trap 310: main body

320: top side 330: bottom side

340: acquisition pipe 350: first low water hammer

351: first point of storage 352: first reservoir

360: flooded plate 361: flooded space

370: second low water hammer plate 371: second bonsu point

372: second reservoir 380: water outlet

390: drain pipe 391: discharge pipe

The present invention relates to a drain trap for an air conditioner to discharge the water discharged from the heat exchange coil installed in the air conditioner to the outside,

In particular, during the cooling or dehumidification operation of the air conditioner, the water condensed by the dew point phenomenon generated during the heat exchange process with the surrounding air in the heat exchanger tube of the heat exchanger coil is discharged smoothly to the outside without backflow and at the same time through the external air. It relates to a drain trap for an air conditioner to block the inflow.

In general, during the cooling operation and the dehumidification operation of the air conditioner, the latent heat passing through the heat exchange tube is lost while circulating the heat exchange medium (coolant) through the heat exchange tube of the heat exchange coil. The dew point phenomenon liquefied on the outer circumferential surface of the heat exchange tube occurs, and the condensed water generated by the dew point phenomenon is collected at the bottom of the housing of the air conditioner and discharged through the drain hole.

However, the conventional air conditioner is also made by connecting a hose to the bottom of the housing or simply by connecting a pipe. However, this method has a risk of flowing water from the sewer back into the air purifier due to the positive pressure during operation of the air conditioner. In the case of low drainage or no drainage, various types of drain traps for air conditioners have been developed since the smell of the sewer may flow into the air purifier through the drain.

As a result of the development of the drain trap as described above, the most commonly used structure is a structure having one reservoir part and one flooded part between the drain part directly connected to the housing of the air conditioner and the discharge part extending to the sewer. have.

That is, as illustrated in FIG. 1, a heat exchange coil 20 for exchanging heat exchange medium is installed on the housing 11 of the air conditioner 10, and the fresh water part is provided in the housing 11 in which the heat exchange coil 20 is installed. (12) is provided and the condensed water and the heat-exchanged water discharged from the heat exchange coil 20 is collected in the fresh water portion 12 is composed of a structure that is discharged to the sewer through the drain 31 of the drain trap (30) there was.

However, the drain trap 30 installed in the conventional air conditioner 10 is constituted by a pipe, and the drain trap 30 composed of the pipe is directly connected to the fresh water part 12 of the housing 11. A portion 31, a reservoir portion 32 connected to the drain portion 31 and bent into a cup shape, a flood portion 33 connected to the reservoir portion 32 and bent in a shape in which the cup is placed up; It is comprised by the discharge part 34 connected to the overflow part 33 and extended to a sewer.

As described above, the drain trap 30 composed of a pipe having a circular cross section starts to discharge water in the fresh water part 12 through the drain part 31 connected to the fresh water part 12 of the housing 11. The water portion 32 is filled, and the water filling the water storage portion 32 is filled with the water storage portion 32 until the water is discharged from the fresh water portion 12 to be blocked.

Therefore, the odor is prevented from flowing back from the sewer to the air conditioner, and the water from the sewer is prevented from flowing back to the fresh water part 12 due to the drop height from the drain 31 to the reservoir 32.

However, since the drain trap 30 by the conventional circular cross-section pipe as described above has a limited height at which the housing 11 of the air conditioner 10 is installed from the bottom surface 14, the drain portion 31 and the reservoir portion ( 32) The problem arises that there is a limit in increasing the height deviation, so that the vacuum suction force inside the air conditioner formed by the static pressure during operation of the large air conditioner sucks back the fresh water and the water of the sewer in the reservoir 32 There was this.

That is, the height between the bottom surface 13 of the housing 11 and the bottom surface 14 on which the air conditioner 10 is installed is usually maintained at about 10-15 cm.

Therefore, the height difference between the drain 31 and the reservoir 32 of the drain trap 30 directly connected to the fresh water part 12 of the housing 11 also cannot be out of the range of 10 to 15 cm.

In particular, the conventional drain trap 30 as described above is not only limited to the peak point of dropping point according to the height difference between the drain 31 and the reservoir 32, but also bottom of the bottom surface of the reservoir 32 Since the surface 14 cannot be brought into close contact with the surface 14, a substantial loss of the sealing point is also generated. When the air pressure acts as a vacuum suction force for the air conditioner to circulate the air, the water contained in the reservoir 32 and the water of the sewer are discharged. The problem of backflowing into the fresh water part 12 of the.

In addition, since the drain trap 30 is configured by combining a plurality of components, the installation and construction costs not only increase, but also workability is reduced.

Therefore, an object of the present invention is to connect the drain pipe to the housing of the air conditioner and the boxed drain trap to the drain pipe, and then to connect the discharge pipe to the drain trap to perform the cooling operation or dehumidification operation of the air conditioner Drainage for the air conditioner that allows the condensed water to be discharged smoothly by the dew point occurring during the heat exchange process with the ambient air in the heat exchanger coil of the heat exchange coil to the outside without backflow and to block the inflow of external air through the drain hole. In providing a trap.

An object of the present invention is a heat exchange coil for heat-exchanging the heat exchange medium is installed on the housing of the air conditioner, the housing provided with the heat exchange coil is provided with a fresh water portion to collect condensed water in the fresh water portion, the fresh water portion of the housing In connecting the drain trap through the drain pipe, the inlet pipe of the boxed drain trap is connected to the drain pipe, and the outlet pipe of the boxed drain trap is connected to the discharge pipe, the boxed drain trap is After forming a first low water hammer plate and a second low water hammer plate on an inner upper surface thereof, the lower end thereof is spaced apart from the lower surface of the main body to form a first water seal point and a second water salvage point, and then the first low water hammer plate and the second low water hammer plate The drain trap is formed so as to form an overflow plate which is integrally formed at the lower surface with the upper end spaced apart from the upper surface to form an overflow space connecting the first reservoir part and the second reservoir part. By construction.

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

A heat exchange coil 200 for exchanging heat exchange medium is installed on the housing 110 of the air conditioner 100, and a fresh water part 120 is provided in the housing 110 in which the heat exchange coil 200 is installed. Condensation water generated by heat exchange in the heat exchange coil 200 is collected at the 120, and the housing 110 of the air conditioner 100 has its bottom surface 130 spaced apart from the bottom surface 140 by a constant height. After installation, the drainage trap 300 is connected to the fresh water part 120 of the housing 110 through a drain pipe 390.

At this time, the drain trap 300 connected to the drain pipe 390 boxed the main body 310 so that the inlet pipe 340 and the outlet pipe 380 protrudes to both sides.

The boxed drain trap 300 allows the first storage plate 350 and the second storage plate 370 to protrude from the upper surface 320 of the main body 310, and the first storage plate 350 and the first storage plate 350. The second low water receiving plate 370 has an upper end integrated with the upper end surface 320 of the main body 310, and the lower end of the second low water receiving plate 370 is spaced at regular intervals from the lower end surface 330 of the main body 310 so that the space is spaced apart. The first sealing point 351 and the second sealing point 371 are to be made.

In addition, a flooding plate 360 is provided between the first low-spreading plate 350 and the second low-spreading plate 370, and the lower end of the flooding plate 360 is integral to the bottom surface 330 of the main body 310. The upper end is spaced apart from the upper end surface 320 of the main body 310 so that the space spaced apart to become the overflow space (361) and at the same time both sides of the overflow plate 360, respectively, the first reservoir 352 ) And the second reservoir 372.

On the other hand, the first sealing point 351 and the second sealing point 371 formed on the lower side of the first low water hammer plate 350 and the second low water hammer plate 370 have the same cross-sectional area as a circular cross-section pipe of a conventional drain trap. It is desirable to adjust the separation distance to have.

In addition, the flood plate 360 is configured so that the height of the upper end is lower than the lower end of the inlet pipe 340, the outlet pipe 380 is preferably such that the upper end is located lower than the flood plate 360.

The present invention configured as described above generates a dew point phenomenon in which water in the air around the evaporator is liquefied while being heat-exchanged around the heat exchange coil 200 while the cooling operation and the dehumidification operation of the air conditioner 100 are generated. The condensed water is collected in the fresh water part 120 provided in the housing 110 of the air conditioner 100, and the collected condensed water is collected in the fresh water part 120 by a drain pipe 390 and a boxed drain trap 300. Drains through the sewer.

As described above, when the water collected in the fresh water part 120 of the housing 110 is drained to the sewer, the fresh water is provided through the drain pipe 390 connected to the fresh water part 120 and the water inlet pipe 340 connected to the drain pipe 390. Water from the unit 120 flows into the drain trap 300.

The water flowing into the drain trap 300 first fills the first reservoir 352 on both sides of the first reservoir plate 350, and then, on the sides of the second reservoir plate 370 beyond the flood plate 360. 2 filling the reservoir 372 is smoothly discharged through the water discharge pipe 380 and the discharge pipe 391.

At this time, the vacuum is formed by the static pressure during operation in the air conditioner 100, and even if a backflow phenomenon is attempted to suck water from the drain trap 300 into the freshwater part 120, the drain trap 300 of the present invention is sewer. It is possible to prevent the back flow of the fresh water portion 120.

That is, in the drain trap 300 of the present invention, the height from the bottom surface 140 on which the air conditioner 100 is installed to the bottom surface 130 of the housing 110 is the same from the inlet pipe 340. Resist the force from the air conditioner 100 by lowering the distance between the first and second points 351 and lowering the separation distance of the first and second points 351 and increasing the left and right lengths, thereby increasing the drop distance more than the existing drain trap. As the sealing efficiency increases, backflow is blocked first.

In addition, the drain trap 300 of the present invention is provided with a first trap plate 350 and the second reservoir plate 370 on both sides of the flooded partition 360, so that the structure of the double trap is made by the second reservoir plate 370 A water film and a pressure blocking the suction pressure are formed at both sides of the second reservoir part 372 to increase the free fall distance, thereby more effectively preventing backflow of sewage.

In particular, since the backflow phenomenon does not occur even in the vacuum suction input of the air conditioner as described above, the first trap part 352 and the second reservoir part 372 of both sides of the overflow plate 360 are not included. Since water is always in a standing state, it is possible to prevent the odor of the sewer from entering the air conditioner 100.

Meanwhile, the drain trap of the present invention, which prevents the backflow of sewage and prevents the introduction of odors, may further include a flood plate and a third reservoir plate between the second reservoir plate 370 and the discharge pipe 380. If the flood plate and the third low water partition plate are installed in this way, the third water reservoir formed on both sides of the third low water plate will act to block the suction pressure of the air conditioner, thereby increasing the drop distance. As a result, even if the static pressure of the air conditioner rises further, it is possible to prevent backflow of sewage.

As described above, the present invention connects the drain pipe to the housing of the air conditioner, connects the boxed drain trap to the drain pipe, and connects the discharge pipe to the drain trap to perform cooling or dehumidification operation of the air conditioner. When the heat exchanger tube of the heat exchange coil in the heat exchange process with the ambient air, the condensed water is discharged smoothly to the outside without backflow, and at the same time, the effect that can block the inflow of external air through the drain hole is provided. will be.

Claims (4)

A heat exchange coil is installed on the housing of the air conditioner to heat exchange the heat exchange medium, and the housing in which the heat exchange coil is installed is provided with a fresh water part to collect condensed water in the fresh water part of the housing. In connection, The inlet pipe of the boxed drain trap is connected to the drain pipe, and the outlet pipe of the boxed drain trap is connected to the discharge pipe, and the boxed drain trap is formed on the inner top surface of the main body. 2 forming a low water stop plate while the lower end thereof is spaced apart from the bottom surface of the main body to form a first water and a second water stop point, and then flooded integrally with the bottom surface between the first low water stop plate and the second low water stop plate. While forming a diaphragm, the upper end is spaced apart from the upper surface drain trap for the air conditioner, characterized in that configured to form a flooding space connecting the first reservoir and the second reservoir. The method of claim 1, The first water seal point and the second water seal point are drainage traps for an air conditioner, which are configured by separating the bottom surface of the main body and the lower surface of the first low water hammer plate and the second low water hammer plate so that the area thereof is the same as that of a pipe having a circular cross section. . The method of claim 1, The flooding plate is configured so that the height of the upper end is lower than the lower end of the water inlet pipe, the discharge pipe is an air conditioner drain trap, characterized in that configured to be positioned lower than the flooding plate. The method according to claim 1, 2 or 3, A drain trap for an air conditioner, characterized by further comprising a flooding plate and a third low water plate between the second low water plate and the discharge pipe of the drain trap.

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