KR101868592B1 - Zone dividing the heat balance heat recovery and dehumidification heat pipe device - Google Patents

Abstract

When the waste heat recovering and dehumidifying heat pipe is installed in the waste heat recovering and dehumidifying heat pipe device of the air conditioner without inclination, the waste heat recovering and dehumidifying heat pipe can be used as a waste heat recovering device for an air conditioner. When the pipe is installed in a state where there is a slope in the waste heat recovery and dehumidifying heat pipe device of the air conditioner, it can be used as a dehumidifying heat pipe in summer and can be used as a separate heat pipe unit for each heat recovery and dehumidifying heat pipe unit Heat balance and stable heat exchange can be performed.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a heat recovery apparatus,

The present invention can be installed in the air outlet of the air conditioner and the air supply device to uniformly recover the waste heat of the air exhausted or supplied during the winter season and the summer season while uniformly heating or cooling the waste heat recovered from the air supplied / And a zone heat divided equilibrium waste heat recovery and dehumidifying heat pipe device which is installed at the front and rear ends of the cooling coil to perform dehumidification while uniformly preheating and reheating the heat without cooling.

Generally, the cooling device of the air conditioner functions as a cooling function and a dehumidifying function. In order to dehumidify, since there is a lot of moisture in the summer and hot air is brought into the outside air inlet, overcooling for removing moisture from the cooling coil If the supercooled air is supplied to the room, condensation or the like is formed in the diffuser, and a precise control is required to place a heating device at the rear end of the cooling coil.

To this end, conventionally, a U-shaped heat pipe was used before and after the cooling coil.

At this time. The U-shaped heat pipe, which is a conventional single-assembly heat transfer device, is constructed such that the evaporator and the condenser are separated from each other, and the connection between the evaporator portion heat pipe and the condenser portion heat pipe is made by connecting the upper portion of the evaporator portion and the upper portion of the condenser portion with a pipe- The lower portion of the evaporator and the lower portion of the condenser are connected to a pipe-shaped liquid pipe.

Thus, when heat is applied to the evaporating portion heat pipe, the liquefied working fluid is vaporized, and the upper portion becomes superheated steam, which results in a region that does not absorb heat, and the superheated steam is connected to the upper portion of the condensing portion and the upper portion of the evaporating portion And is introduced into the condenser heat pipe through the gas pipe.

When the air cooled by the cooling coil passes through the condenser portion heat pipe provided at the rear end of the cooling coil, the superheated vapor of the working fluid is liquefied and the lower portion of the condenser is supercooled, This is due to the similar phenomenon that the inlet temperature and the outlet of the direct inflatable cooling coil have superheating degree, and the upper and lower portions of the condensation portion are not heat balanced.

Thus, the efficiency of the heat pipe as a whole is lowered. In the prior art, since the slope of the gas pipe and the liquid pipe is increased, the heat pipe is operated only in one direction, which is difficult to use in an energy recovery device of an air conditioner.

1 is a conceptual diagram of a single-piece heat pipe 1 of a U shape in the prior art, in which the single-piece heat pipe 1 includes a gas guide tube 1a and a liquid guide tube 1b, A portion 1c and a condensing portion 1d.

The evaporator 1c and the condenser 1d include a plurality of gas and liquid tubes 1c 'and 1d' having a plurality of fins formed on the outer surface thereof and a plurality of gas and liquid tubes 1c 'and 1d' (1c '') 1d '' for connecting the connecting band 1c ''.

The single-piece heat pipe 1 is installed in the air conditioner so that the cooling coil is positioned between the evaporator 1c and the condenser 1d.

Thus, the working fluid that has been vaporized in the evaporation portion 1c and absorbed heat becomes a superheated gas at the upper portion, fails to properly absorb heat, is transferred to the upper portion of the condensing portion 1d, The lower the temperature, the lower the heat is not able to emit properly. That is, there is a problem in the heat exchange function because the heat balance is not achieved in the upper and lower portions of the evaporator 1c and the condenser 1d.

Patent Document 1: Korean Registered Patent No. 10-0309937 (registered on September 12, 2001) Patent Document 2: Korean Registered Patent No. 10-1409813 (Registered on June 13, 2014)

Accordingly, the present invention is to provide an air conditioner that is installed in an exhaust port of an air conditioner and a supply mechanism to uniformly recover waste heat of air exhausted or supplied during the winter season and summer season while uniformly heating or cooling the waste heat recovered from air supplied or exhausted And it is an object of the present invention to provide a zone heat divided equilibrium waste heat recovery and dehumidifying heat pipe device which is installed at the front and rear ends of a cooling coil to perform dehumidification while uniformly preheating and reheating.

In order to achieve the above object, the present invention provides a waste heat recovering and dehumidifying heat pipe device installed in a ship, an air supply device, and a cooling coil of an air conditioner, comprising: a vaporizer connected to both the gas guide pipe and the liquid guide pipe; And a condensing part, and a working fluid is injected into the evaporating part. The evaporating part is long in the longitudinal direction, one side is inclined in the same direction, a plurality of fins are formed on the outer surface, and a pair of 'U' Shaped gas pipe and a first U-shaped band connecting one end of each of the evaporator gas pipes, and the condenser is elongated in the longitudinal direction in the same direction as each of the evaporator gas pipes, One side is inclined, and a plurality of pins are formed on the outer surface. A pair of condensed liquid pipes of a 'U' type having a predetermined distance equal to the distance between the gas pipes of the respective evaporator parts and facing each evaporator gas pipe at a distance longer than the distance between the gas pipes of the respective evaporator parts, And a second U-shaped band for connecting one end of the liquid pipe of the condensing part to each other. The gas induction pipe and the liquid induction pipe are connected to the other end of each evaporator gas pipe and the other end of each condenser liquid pipe, Wherein the gas guide tube, the liquid induction tube, and the inner surface of the evaporator and the condenser are formed with an inner groove type wick, and the gas guide tube and the liquid guide tube of the waste heat recovery and dehumidifying heat pipe And the other is a waste heat recovering and dehumidifying heat pipe having a gas induction pipe and a liquid induction pipe having a short length, and the gas induction pipe and the liquid induction pipe of the heat recovery and dehumidifying heat pipe, And the shaft portion is positioned above the gas induction pipe and the liquid induction pipe and the evaporation portion and the condensation portion of another waste heat recovery and dehumidifying heat pipe and another waste heat recovery and dehumidifying heat pipe is located inside the waste heat recovery and dehumidifying heat pipe The heat recovery and dehumidifying heat pipe unit including the waste heat recovering and dehumidifying heat pipe unit, and the evaporating unit and the condensing unit of the waste heat recovering and dehumidifying heat pipe unit are respectively installed in the first and second casings.

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The present invention relates to an air conditioner which is installed in an air outlet of an air conditioner and an air supply device to uniformly recover waste heat of air to be exhausted or supplied during the winter season and summer season while uniformly heating or cooling the waste heat recovered air, It is effective.

In addition, since there is no contamination among the heat exchanging process between the exhaust gas and the supply air, it is sanitary and the cleaning is easy by the general cleaning.

When the dehumidifying device is installed at the front and rear ends of the cooling coil, the dehumidifying effect is maximized by effectively reducing the load of the cooling coil by effectively precooling the outside air during summer in the evaporator, Since the outlet air of the coil is reheated and the relative humidity is lowered and supplied to the room, the room can be maintained at an appropriate humidity and the energy saving can be achieved.

That is, the conventional heat exchanger for recovering the domestic waste heat is a plate-shaped or annular heat exchanger which can not be cleaned, and becomes a hotbed of bacteria. In many cases, The efficiency was also low in necessity.

Thus, the use of the non-powered dehumidifying heat pipe to which the present invention is applied can prevent the propagation of bacteria, prevent corrosion by bacteria in various devices and buildings, and has an excellent effect in dehumidifiers and dryers.

1 is a perspective view of a conventional single heat pipe,
2 is a perspective view of a waste heat recovering and dehumidifying heat pipe according to an embodiment of the present invention,
3 is a front view of one waste heat recovery and dehumidifying heat pipe unit according to an embodiment of the present invention;
4 is a front view of a plurality of waste heat recovery and dehumidifying heat pipe units according to an embodiment of the present invention,
5 is a front view of a waste heat recovering and dehumidifying heat pipe apparatus provided with a plurality of waste heat recovering and dehumidifying heat pipe units according to the present invention,
6 is a front view of a waste heat recovering and dehumidifying heat pipe apparatus provided with a plurality of waste heat recovering and dehumidifying heat pipe units according to the present invention,
7 is a state view showing a state in which a waste heat recovery and dehumidifying heat pipe device is installed in a ship, a feeder, and a cooling coil of an air conditioner.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a configuration of a specific embodiment of the present invention will be described with reference to the accompanying drawings.

2, the waste heat recovery and dehumidifying heat pipe 10A according to the embodiment of the present invention includes a vaporizing portion 13 connected to both the gas induction pipe 11 and the liquid induction pipe 12, (14), and a working fluid is injected into the inside thereof and installed in the waste heat recovery and dehumidifying heat pipe device (20).

The evaporating portion 13 of the waste heat recovering and dehumidifying heat pipe 10A is long in the longitudinal direction and one side is inclined in the same direction, a plurality of the pins 13a 'are formed on the outer surface, And a pair of U-shaped evaporator gas pipes 13a.

The evaporating portion 13 of the waste heat recovering and dehumidifying heat pipe 10A further includes a first U-shaped band 13b connecting one end of each of the evaporator gas pipes 13a.

That is, the evaporator 13 has a staggered shape by the evaporator gas pipe 13a and the first band 13b, and the distance between each of the evaporator gas pipes 13a is shorter than the conventional one .

The condensed portion 14 of the waste heat recovering and dehumidifying heat pipe 10A is long in the longitudinal direction same as each evaporator gas pipe 13a and one side is inclined in the same direction as the evaporator gas pipe 13a , And a plurality of pins (14a ') are formed on the outer surface. (U) having a predetermined distance equal to the distance between each evaporator gas pipe (13a) and the evaporator gas pipe (13a) at a distance farther than the distance between the respective evaporator gas pipes (13a) A pair of condensate liquid tubes 14a of the shape of ''.

The condensing section 14 of the waste heat recovering and dehumidifying heat pipe 10A further includes a second U-shaped band 14b connecting one end of each condensing section liquid pipe 14a.

That is, the condensing section 14 has a staggered shape by the condensing section liquid pipe 14a and the second band 14b, and the distance between each condensing section liquid pipe 14a is shorter than the conventional one .

The gas induction pipe 11 and the liquid induction pipe 12 of the waste heat recovering and dehumidifying heat pipe 10A are connected to the other end of each evaporating portion gas pipe 13a and the other end of each condensing portion liquid pipe 14a, .

Here, the distance between the gas induction pipe 11 and the liquid induction pipe 12 is shorter than that of the prior art by the zigzag evaporator 13 and the condenser 14.

A micro-inner-groove type wick 15 is formed on the inner surfaces of the gas induction pipe 11, the liquid induction pipe 12, the evaporator 13, and the condenser 14.

When the air flows into the waste heat recovering and dehumidifying heat pipe 10A, the working fluid absorbing the heat through the plurality of fins 13a 'flows along the evaporator gas pipe 13a and the first band 13b And the working fluid as a gas flows through the plurality of fins 14a 'at the condensing liquid pipe 14a located at the upper portion of the condensing portion 14 along the gas guiding pipe 11 It is diverged and condensed.

The working fluid which is condensed by heat is condensed in the zigzag manner from the upper portion to the lower portion along the condenser portion liquid pipe 14a and the second band portion 14b and flows along the liquid guide pipe 12 to the evaporator portion 13 ≪ / RTI >

At this time, the working fluid moves on the gas induction pipe 11 toward the condenser 14 in a gaseous state due to the difference between the vaporization pressure of the evaporator 13 and the condensation pressure of the condenser 14, The working fluid moves to the liquid induction pipe 12 and the evaporator 13 due to the gravity due to the specific gravity and the capillary phenomenon of the wick 15.

Therefore, since the distance between each vaporizing portion gas pipe 13a and each condensing portion liquid pipe 14a and between the gas guiding pipe 11 and the liquid guiding pipe 12 is shorter than the conventional case, And the temperature deviation between the liquid guide tube 12 and the evaporator 13 and the condenser 14 is not large.

That is, the waste heat recovery and dehumidifying heat pipe 10A is in a thermal equilibrium state, so that heat is uniformly absorbed from the flowing air, and heat is uniformly emitted to the air.

In other words, the air passing through the waste heat recovery and dehumidifying heat pipe 10A has a uniform temperature as a whole.

As a result, the waste heat recovery and dehumidifying heat pipe 10A achieves a heat balance and a stable heat exchange function at the same time.

The waste heat recovering and dehumidifying heat pipe device 20 provided in the air conditioner 30, the air supply devices 31 and 32 and the cooling coil 33 is connected to the waste heat recovery and dehumidifying heat pipe 10A , A gas induction pipe (11) of the waste heat recovering and dehumidifying heat pipe (10A) and a gas induction pipe (11) and a liquid induction pipe (12) having a length shorter than the liquid induction pipe (12) And a waste heat recovering and dehumidifying heat pipe unit 10C composed of a waste heat recovering unit 10B.

3, the waste heat recovering and dehumidifying heat pipe unit 10C includes a gas induction pipe 11, a liquid induction pipe 12, and a vaporizing unit 13 of the waste heat recovery and dehumidifying heat pipe 10A, The condensation section 14 is located above the gas induction pipe 11 and the liquid induction pipe 12 and the evaporation section 13 and the condensation section 14 of the waste heat recovery and dehumidification heat pipe 10B, The recovery and dehumidification heat pipe 10B is located inside the waste heat recovery and dehumidification heat pipe 10A.

The upper portion of the evaporating portion 13 of the waste heat recovering and dehumidifying heat pipe 10B is located in the middle of the evaporating portion 13 of the waste heat recovering and dehumidifying heat pipe 10A and the waste heat recovering and dehumidifying heat pipe The condensation portion 14 of the waste heat recovery and dehumidifying heat pipe 10B is located close to the middle of the condensation portion 14 of the heat recovery pipe 10A.

The gas induction pipe 11 and the liquid induction pipe 12 of the waste heat recovery and dehumidification heat pipe 10A and the gas induction pipe 11 and the liquid induction pipe 12 of the waste heat recovery and dehumidification heat pipe 10B 12 are positioned close to each other.

In addition, in the liquid induction pipe 12 of the waste heat recovery and dehumidification heat pipe 10A, the middle portion of the condensation portion 14 and the evaporation portion 13 of the waste heat recovery and dehumidification heat pipe 10B are positioned close to each other.

That is, the waste heat recovering and dehumidifying heat pipe 10A and the waste heat recovering and dehumidifying heat pipe 10B are overlapped with each other.

When the air flows into the waste heat recovery and dehumidifying heat pipe unit 10C, the gas induction pipe 11, the liquid induction pipe 12, and the evaporator 13 are connected to the waste heat recovery and dehumidifying heat pipe 10A in Fig. And the condensation section 14 is not further increased.

That is, the waste heat recovering and dehumidifying heat pipe unit 10C is in a thermal equilibrium state, so that it uniformly absorbs heat evenly in the flowing air, and more heat is uniformly discharged to the air.

In other words, the air passing through the waste heat recovery and dehumidifying heat pipe unit 10C has a more uniform temperature as a whole.

As a result, the waste heat recovering and dehumidifying heat pipe unit 10C is formed as one zone in which heat balance is performed and a stable heat exchange function is performed.

The waste heat recovering and dehumidifying heat pipe unit 10C as one unit is constructed such that the evaporator 13 and the condenser 14 are connected to the first and second casings 21 and 22 of the waste heat recovery and dehumidifying heat pipe apparatus 20, Respectively.

As shown in FIG. 4, the waste heat recovery and dehumidifying heat pipe unit 10C may include a plurality of zones at predetermined intervals, and may be formed of a plurality of zones for thermal balance and stable heat exchange.

5, of the waste heat recovery and dehumidifying heat pipe device 20 provided in the ship, the air supply devices 31 and 32 and the cooling coil 33 of the air conditioner 30, The evaporator 13 and the condenser 14 of each waste heat recovery and dehumidifying heat pipe unit 10C are connected to the first and second casings 21 and 22, ) 22 at predetermined intervals along the longitudinal direction.

6 shows the case where the waste heat recovering and dehumidifying heat pipe device 20 is used as a dehumidifying device. When the dehumidifying heat pipe device 20 is constructed with a slope in the inlet direction of the air, the specific gravity of the working fluid becomes large and flows only in one direction, Can not flow.

The waste heat recovering and dehumidifying heat pipe device 20 has an air inlet side serving as an evaporator 13 and an air outlet side serving as a condenser 14 and an evaporator 13 and a condenser 14 And a cooling coil is inserted and used for auxiliary dehumidification in summer.

7 shows the case where the waste heat recovery and dehumidifying heat pipe device 20 is installed and used in the ship, the air supply devices 31 and 32 and the cooling coil 33 of the air conditioner 30, The air circulated through the evaporator 13 of the waste heat recovery and dehumidifying heat pipe device 20 is discharged to the exhaust damper 31a provided in the exhaust port 31 via the evaporator 13. At this time, ) To absorb heat.

The working fluid evaporates in the evaporator 13 and is conveyed to the condenser 14. The cool air passes through the condenser 14 through the air supply damper 32a provided in the air supply device 32, The working fluid releases heat and is condensed to return to the evaporation portion 13.

On the other hand, in the summer, when the hot air introduced from the air supply damper 32a passes through the condensing portion 14, the condensing portion 14 is formed as the evaporating portion 13 so that the working fluid evaporates, The evaporator 13 is formed as the condenser 14 so that the working fluid is heat-exchanged with the fresh air and the condensed air is condensed And the heat-exchanged air is discharged to the exhaust damper 31a.

When the evaporation portion 13 and the condensing portion 14 of the waste heat recovery and dehumidifying heat pipe device 20 shown in Fig. 6 inclined to the front and rear ends of the summer cooling coil 33 are provided, the cooling coil 33, The working fluid of the condenser 14 is condensed and discharged by the air passing through the evaporator 13. The working fluid is transferred to the evaporator 13 to cool the outside air while evaporating, The dehumidifying effect is maximized in the cooling coil 33, and the reheating effect is exhibited in the condensing portion 14, so that the relative humidity is lowered.

Then, the air is supplied to the air supply flange 35a through the blower 35.

Thus, when the waste heat recovery and dehumidifying heat pipe device 20 is installed in the air conditioner 30 such as a hospital, a museum, and a museum, the preheating and the reheating can be performed at the same time,

When the outside air is introduced into the air without the heat exchange in the season of change, the air damper 31a is closed and the bypass damper 36 is opened to perform heat exchange.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the embodiments set forth herein. Various changes and modifications may be made by those skilled in the art.

10: waste heat recovery and dehumidification heat pipe 11: gas induction pipe
12: liquid induction pipe 13:
13a: Evaporator gas pipe 13b: First band
14: condensing part 14a: condensing part liquid pipe
14b: second band 15: wick
20: waste heat recovery and dehumidifying heat pipe device 21: first casing
22: second casing 30: air conditioner
31: exhaust port 32:
33: Cooling coil

Claims (3)

delete In the waste heat recovery and dehumidifying heat pipe device provided in the air conditioner (30), the air supply devices (31, 32) and the cooling coil (33)
And a condensing section (14) connected to both the gas induction pipe (11) and the liquid induction pipe (12). The working fluid is injected into the evaporation section (13)
The evaporator 13 includes a pair of 'U' shaped evaporator gas pipes 13a 'having a predetermined length and having one end inclined in the longitudinal direction and one side inclined, a plurality of pins 13a' )and,
And a first U-shaped band (13b) connecting one end of each of the evaporator gas pipes (13a) to each other,
The condenser 14 is long in the longitudinal direction same as each evaporator gas pipe 13a and one side is inclined in the same direction as each evaporator gas pipe 13a and a plurality of fins 14a ' . (U) having a predetermined distance equal to the distance between each evaporator gas pipe (13a) and the evaporator gas pipe (13a) at a distance farther than the distance between the respective evaporator gas pipes (13a) A pair of condensed liquid tubes 14a of the shape "
And a 'U' shaped second band (14b) connecting one end of each of the condenser part liquid pipes (14a)
The gas induction pipe 11 and the liquid induction pipe 12 are connected to the other end of each evaporating portion gas pipe 13a and the other end of each condensing portion liquid pipe 14a so as to face each other,
Characterized in that an inner groove type wick (15) is formed on the inner surfaces of the gas induction pipe (11), the liquid induction pipe (12), the evaporator (13) and the condenser (14) (10A)
A waste heat recovery and dehumidifying heat pipe having a gas induction pipe 11 of the waste heat recovery and dehumidification heat pipe 10A and a gas induction pipe 11 and a liquid induction pipe 12 having a length shorter than the liquid induction pipe 12 10B,
The gas induction pipe 11 and the liquid induction pipe 12 of the waste heat recovery and dehumidification heat pipe 10A and the evaporation portion 13 and the condensation portion 14 of the waste heat recovery and dehumidification heat pipe 10A are respectively connected to the gas Is located above the induction pipe (11), the liquid induction pipe (12) and the evaporator (13) and the condenser (14)
And a waste heat recovery and dehumidifying heat pipe unit (10C) in which the waste heat recovery and dehumidifying heat pipe (10B) is located inside the waste heat recovery and dehumidification heat pipe (10A)
Characterized in that the evaporating portion (13) and the condensing portion (14) of the waste heat recovering and dehumidifying heat pipe unit (10C) are provided in the first and second casings (21, 22), respectively. . 3. The method of claim 2,
The first and second casings 21 and 22 are elongated in the longitudinal direction,
The waste heat recovery and dehumidifying heat pipe unit (10C)
The evaporating portion 13 and the condensing portion 14 of each of the waste heat recovering and dehumidifying heat pipe units 10C are provided at predetermined intervals along the longitudinal direction of the first and second casings 21 and 22 Heat recovery and dehumidifying heat pipe device.

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