KR20020061592A - Air conditioner - Google Patents

Abstract

An air conditioner having a humidifying unit, in which the amount of humidity can be maintained and the overall diameter of the lines can be designed to be minimized, by maintaining the temperature of humidified air from the humidifying unit to the indoor unit at an appropriate level. Refrigerant lines that that run between an outdoor refrigerant circuit and an indoor refrigerant circuit, and a humidified air line that runs between the humidifying unit and the indoor air conditioner, are formed inside and integral with a line member 161, and amongst the refrigerant lines, a high pressure/high temperature heating line 163 and a humidified air line 164 are disposed inside a high temperature maintenance space 165. <IMAGE>

Description

Air conditioner {AIR CONDITIONER}

In the separate type air conditioner, the outdoor heat exchanger disposed in the outdoor unit and the indoor heat exchanger disposed in the indoor unit are connected to the refrigerant pipe, and are configured to perform cooling operation or heating operation by controlling each heat exchanger to act as a condenser and an evaporator of the refrigerant. have.

In the outdoor unit, an outdoor fan for generating an air flow is disposed, and the outdoor fan introduces the outdoor air to exchange heat between the refrigerant and the air passing through the inside of the outdoor heat exchanger.

Similarly, an indoor fan is arranged in the indoor unit to generate an air flow inside the indoor unit casing, and the indoor fan sucks the indoor air to exchange heat between the refrigerant and the air passing through the interior of the indoor heat exchanger.

In general, in the heating operation of the air conditioner, since only the room temperature rises without supply of water, the relative humidity in the room often decreases significantly. For this reason, it is proposed to provide a humidification unit to an air conditioner and to supply humidification air to a room. The humidification unit comprises, for example, a disk-shaped rotor made of a porous hygroscopic material such as zeolite which releases the adsorbed moisture by adsorbing and heating the moisture in the air and heating the support. do. A moisture absorption fan is introduced to generate air flow through a part of the rotor by introducing outside air to adsorb moisture in the rotor, and humidified air containing moisture released from the rotor is conveyed to the indoor unit side. The humidification fan which produces | generates the airflow for this is provided. The airflow by the moisture absorption fan and the airflow by the humidification fan are respectively configured to pass through the rotor at different positions in the rotational direction of the rotor, and a heater that heats the rotor at a position where the airflow by the humidification fan passes. Is placed.

Moisture contained in the air flow by the moisture absorption fan is absorbed by the moisture absorption material of the rotor. The rotor is rotationally driven by the motor, and the adsorbed moisture is released from the heating position by the heater, thereby giving moisture in the air flow by the humidification fan.

The humidifying unit as described above is installed in the outdoor unit or installed in the vicinity of the outdoor unit, adsorbs the moisture in the air stored from the outside by the moisture absorbing fan to the rotor, and separates the absorbed moisture to the indoor unit side as the humidifying air. Return to

The humidified air from the humidifying unit is supplied to the indoor unit side using the humidifying air pipe. This humidifying air piping is normally comprised by heat insulating materials, such as foamed polyurethane.

In the case of the humidification operation by the humidification unit in Japan, it is mainly during the drying of the outdoor air in winter, and the piping from the humidification unit to the indoor unit is exposed to the low temperature outdoor air. For this reason, there exists a possibility that the air which passes through the inside of the piping for humidification air may cool, and moisture contained may condense and the appropriate amount of humidification may not be obtained.

In addition, the piping from the outdoor unit to the indoor unit is composed of two systems, a refrigerant pipe and a humidifying air pipe, which is complicated in handling of the pipe at the time of construction, and the diameter of the pipe is increased as a whole, so that it is easy to enter a duct for passing a conventional refrigerant pipe. There is a problem that can not go.

In the present invention, in the air conditioner provided with the humidifying unit, by appropriately maintaining the temperature of the humidifying air from the humidifying unit to the indoor unit side, it is possible to maintain the amount of humidification and to reduce the overall pipe diameter. do.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner capable of carrying out humidity adjustment of indoor air by conveying humidified air to the indoor unit side by a humidifying unit installed in an outdoor unit.

1 is a perspective view showing an external configuration of an air conditioner to which an embodiment of the present invention is adopted.

2 is an explanatory diagram of a refrigerant circuit.

3 is an exploded perspective view of the outdoor unit.

4 is an exploded perspective view of the indoor unit.

5 is a cross-sectional view of the piping member.

The air conditioner according to the present invention is configured to generate humidified air by adsorbing moisture from an outdoor air conditioning unit having an outdoor refrigerant circuit, an indoor air conditioning unit having an indoor refrigerant circuit connected to the outdoor refrigerant circuit, and outdoor air. An air conditioner having a humidifying unit for supplying humidified air to an indoor air conditioning unit, wherein a refrigerant pipe connecting an outdoor refrigerant circuit and an indoor refrigerant circuit, and a pipe for humidifying air connecting the humidifying unit and the indoor air conditioning unit are made of a heat insulating material. At the same time, the high-pressure high-temperature pipe is disposed in the same space as that of the humidifying air pipe during heating of the refrigerant pipe.

In this case, the air temperature in the piping for humidifying air can be kept at high temperature, and a lack of humidification amount can be prevented. Moreover, by arrange | positioning each pipe | tube integrally in a communication pipe | tube, it becomes possible to improve the work efficiency at the time of construction, and to make the whole pipe diameter small.

Here, the high pressure low temperature pipe during heating of the refrigerant pipe may be configured to be arranged in a different space from the space where the high pressure high temperature pipe and the humidifying air pipe are arranged during heating.

In this case, the humidifying air pipe is less affected by the refrigerant temperature passing through the high-pressure low-temperature pipe during heating, so that the air temperature in the humidifying air pipe can be maintained at a high temperature.

Moreover, it is possible to set it as the structure in which the communication wire which electrically connects an outdoor air conditioning unit and an indoor air conditioning unit is arrange | positioned in a communication piping.

In this case, it is possible to arrange the refrigerant pipe, the humidifying air pipe and the communication pipe integrally, thereby improving the work efficiency at the time of construction.

[Appearance of air conditioner]

The external appearance of the air conditioner which one embodiment of this invention is employ | adopted is shown in FIG.

This air conditioner 1 is equipped with the indoor unit 2 attached to the indoor wall surface, etc., and the outdoor unit 3 installed outdoors. The outdoor unit 3 is provided with the outdoor air conditioning unit 5 which accommodates an outdoor heat exchanger, an indoor fan, etc., and the humidification unit 4 which conveys humidified air to the indoor unit 2.

An indoor heat exchanger is housed in the indoor unit 2, an outdoor heat exchanger is housed in the outdoor unit 3, and each heat exchanger is connected by a refrigerant pipe to form a refrigerant circuit. Moreover, between the humidification unit 4 and the indoor unit 2, the humidification air piping for supplying the humidification air from the humidification unit 4 to the indoor unit 2 side is provided. The refrigerant pipe and the humidifying air pipe are arranged in the communication pipe 6 insulated from the outside by the heat insulating material.

[Schematic Configuration of Refrigerant Circuit]

An example of a refrigerant circuit used in the air conditioner 1 is shown in FIG. 2.

The indoor heat exchanger 11 is installed in the indoor unit 2. The indoor heat exchanger 11 is composed of a heat transfer tube that is folded back and forth at both ends in the longitudinal direction and a plurality of fans through which the heat transfer tube is inserted, and performs heat exchange between the contacting air.

The indoor unit 2 is also provided with a cross flow fan 12 for sucking the indoor air and discharging the air after the heat exchange between the indoor heat exchangers 11 to the room. The cross flow fan 12 is formed in a cylindrical shape, and wings are provided on the circumferential surface in the direction of the rotation axis, and generate air flow in the direction crossing the rotation axis. The cross flow fan 12 is rotationally driven by a fan motor 13 provided in the indoor unit 2.

The outdoor air conditioning unit 5 includes a four-way switching valve 22 connected to the compressor 21 and the discharge side of the compressor 21, an accumulator 23 connected to the suction side of the compressor 21, The pressure reducer 25 which consists of the outdoor heat exchanger 24 connected to the 4-way switching valve 22, and the electric expansion valve connected to the outdoor heat exchanger 24 is provided. The pressure reducer 25 is connected to the local pipe 31 through the filter 26 and the liquid closing valve 27, and the indoor heat exchanger 11 through the local pipe 31. It is connected with one end of. In addition, the 4-way switching valve 22 is connected to the local pipe 32 via the gas closing valve 28, and is connected to the other end of the indoor heat exchanger 11 through the local pipe 32. These local pipes 31 and 32 are provided in the communication pipe 6 of FIG.

In the outdoor air conditioning unit 5, a propeller fan 29 for discharging air after heat exchange in the outdoor heat exchanger 24 to the outside is provided. This propeller fan 29 is rotationally driven by the fan motor 30.

[Configuration of Outdoor Unit]

The structure of the outdoor unit 3 is demonstrated using the exploded perspective view shown in FIG.

The outdoor unit 3 includes an outdoor unit including a bottom plate 41, a right plate 42, a left plate 43, a front plate 44, a protective wire mesh 46, an upper plate 47, a humidification unit casing 48, and the like. A casing is provided.

The fan suction port 45 and the partition plate 49 are mounted to the rear of the front plate 44. Moreover, the outdoor heat exchanger 24 which consists of a substantially L-shape in plan view is attached to the front surface of the protective wire mesh 46 located in the back of the outdoor unit casing.

The fan motor stand 50 is attached to the front surface of the outdoor heat exchanger 24, and the outdoor fan motor 30 is fixed to the fan motor stand. The outdoor fan motor 30 is equipped with an outdoor fan 29. The outdoor fan 29 is driven by the outdoor fan motor 30 to thereby form the bottom of the fan inlet 45, the partition plate 49, the left shaft plate 43, the outdoor heat exchanger 24, and the humidification unit casing 48. A negative pressure is formed in the space formed by the plate, and air introduced from the rear surface and the left side is brought into contact with the outdoor heat exchanger 24, and then exhausted to the front surface of the front plate 44.

Between the partition plate 49 and the right side plate 42, the compressor 21, the four-way switching valve 22, the electric valve 25, the liquid pipe closing valve 27, the gas pipe closing valve 28, etc. Coolant circuit components and a thermistor (51) for detecting the temperature of each portion are arranged. The right side of the right side plate 42 is equipped with a closing valve cover 52 for protecting the liquid pipe closing valve 27 and the gas pipe closing valve 28.

On the upper side of the outdoor fan 29, an electrical equipment box 53 is mounted. In this electrical equipment box 53, a printed circuit board 54 mounted with circuit components for controlling the respective parts is accommodated, and a heat radiating fan 55 for radiating heat generated from the circuit components is mounted.

Moreover, in the upper part of the space where refrigerant circuit components, such as the compressor 21, are accommodated, the ingress of the flameproof plate 56 for preventing combustion when it ignites, and the ingress of the water droplet from the humidification unit side are prevented. The spinning plate 57 is provided.

The humidification unit 4 is provided with the humidification unit casing 48 located in the upper part of the outdoor unit 3. The humidification rotor 58 is arrange | positioned in this humidification unit casing 48. The humidifying rotor 58 adsorbs moisture in the air to be contacted, and has a disk shape made of porous zeolite or the like having a property of releasing the adsorbed moisture by heating, and has a support shaft provided on the humidifying unit casing 48 side ( 59 is rotatably supported through the rotor guide 60. Gears are formed on the circumferential surface of the humidifying rotor 58 and mesh with the rotor drive gear 62 mounted on the drive shaft of the rotor drive motor 61.

The heater assembly 64 is arranged to cover approximately half of the top surface of the humidifying rotor 58. The heater assembly 64 discharges the heated air to the heater body 66, the upper cover 65 covering the heater body 66, the suction port 67 for sucking the air and the heater body 66. It consists of a lower cover 69 having an outlet 68, and is mounted above the humidification rotor 58 through the heater fixing plate 63.

A humidification fan 70 is disposed below the humidification rotor 58 and corresponding to the heater assembly 64. The humidification fan 70 is a centrifugal fan arranged in a casing continuous to the humidification side contact duct 72 and is integrally installed at the humidification fan inlet 71 mounted below the humidification rotor 58. The humidification fan 70 exhausts the air that has passed through the humidification rotor 58 to the humidification side contact duct 72, and passes through the humidifying air piping disposed in the humidification hose 73 and the communication pipe 6 to provide an indoor unit. Humidified air is sent out to (2) side.

An adsorption side contact duct 74 is provided so as to cover the upper surface of the humidification rotor 58 and the portion where the heater assembly 64 is not located. The suction side contact duct 74 allows the humidifying rotor 58 to pass from the lower part of the humidifying rotor 58 to the suction fan accommodating part 75 adjacent to the housing part of the humidifying rotor 58. Form a flow path.

Above the suction fan housing 75, an suction side bell mouse 84 having an opening 85 connected to the air flow path formed by the suction side communication duct 74 is provided. The suction fan 81 is rotatably housed in the suction fan housing 75. The adsorption fan 81 is a centrifugal fan configured to intake air from the adsorption side bell mouse 84 disposed above and to exhaust the adsorption fan housing 75 toward the rear side. The suction fan 81 is rotationally driven by the suction fan motor 83. The suction fan motor 83 is fixed in the humidification unit casing 48 by the motor holder 82.

In addition, in the humidification unit casing 48, the electrical equipment casing 76 which consists of the electrical equipment box 76 which accommodates the printed board 78 inside, the electrical equipment box cover 77, the power supply board 79, etc. are arrange | positioned.

In such a humidification unit 4, the adsorption fan 81 is rotationally driven to receive air from the outside, and a part of the humidification rotor 58 is passed through the adsorption side contact duct and the adsorption fan 81. Creates a stream of air outward. When the air received from the outside passes through the humidifying rotor 58, the humidifying rotor 58 absorbs moisture contained in the air.

Moreover, by rotationally driving the humidification fan 70, air is taken in from the outside, and the humidification rotor 58 is passed from the bottom to the top, and the upper cover 65 is formed from the inlet 67 of the lower cover 69. It is introduced into and discharged from the outlet port 68 and passes the humidification rotor 58 again from the top to the bottom, thereby producing an air flow exhausted through the humidification fan 70 to the humidification side contact duct 72 side. At this time, the air flow introduced from the outside is heated in contact with the heater body 66 located in the upper cover 65 of the heater assembly 64. Therefore, the moisture adsorbed to the humidification rotor 58 is released by the air flow generated by the humidification fan 70, and it is possible to supply the humidifier air to the indoor unit 2 side as humidified air.

(Indoor air conditioning unit)

4 is an exploded perspective view of the indoor unit 2.

In FIG. 4, the indoor unit 2 has a front grille assembly 101 and a front panel 102 mounted to the front of the front grille assembly 101. The front grille assembly 101 has an upper inlet 103 that defines a plurality of slit openings on its top surface. In addition, the front panel 102 is provided with a front suction port 104 that is opened up and to the side.

Located inside the upper inlet 103 of the front grill assembly 101 and inside the front inlet 104 of the front panel 102, an air cleaning air filter 105 is inserted.

The front grille assembly 101 is mounted to the bottom frame assembly 106 located rearward to constitute a casing that houses the internal components. The casing consisting of the front grille assembly 102 and the bottom frame assembly 106 is hung on a built-in plate 107 fixed to the wall of the room and mounted in the room.

The bottom frame assembly 106 is provided with a fan storage portion 109 for storing the cross flow fan 12. The cross flow fan 12 is rotatably mounted to the fan housing 109 via the bearing member 110, and an indoor fan motor 13 is provided on the side opposite to the bearing member 110. On the outer side of the indoor fan motor 13, the side plate 111 is mounted.

The indoor heat exchanger 11 is mounted to enclose the front, top and rear top of the cross flow fan 12. This indoor heat exchanger (11) is equipped with a plurality of heat dissipation fins in a heat pipe that is folded back and forth at both ends, and is sucked from the upper inlet port (103) and the front inlet port (104) by the drive of the cross flow fan (12). Passed air is passed to the cross flow fan 12 side, and heat exchange is performed between the refrigerant passing through the heat transfer tube. The indoor heat exchanger 11 is connected to a refrigerant pipe 108 branched from the communication pipe 6.

Below the indoor heat exchanger 11, a drain pan 112 for receiving condensate generated during heat exchange is provided. The drain pan 112 is equipped with a drain hose 113 for discharging the condensed water received to the outside. In the cooling operation, since the indoor heat exchanger 11 acts as an evaporator, moisture contained in the air in contact with the indoor heat exchanger 11 condenses. Such condensed water is received by the drain pan 112 and configured to be drained by the drain hose 113.

In the lower part of the front grill assembly 101, an electrical equipment box 114 for storing a printed circuit board on which a control circuit or the like is accommodated, and an electrical equipment cover 115 for covering the front surface of the electronic equipment box 114 are provided. Moreover, the blower outlet of the airflow generated by the cross flow fan 12 is formed in the lower part of the electrical equipment box 114. As shown in FIG. In this jet port, the horizontal blades 116 and 116 and the plurality of vertical blades 117 and 117 connected by the vertical blade connecting rod 118 are provided so as to be able to swing. These horizontal vanes 116, 116 are rotationally driven by the horizontal vane actuating motor 119, and the vertical vanes 117, 117 are configured to be rotationally driven by the vertical vane actuating motor 120.

On one side of the bottom frame assembly 106, a duct assembly 121 is mounted. The duct assembly 121 is provided with the humidification hose connection part 122 located in the lower part, the flow path formation part 123 located in the middle, and the humidification air blower outlet 124 located in the upper part. The humidification air pipe branched from the communication pipe 6 is connected to the humidification hose connecting portion 122 of the duct assembly 121 to introduce humidification air supplied from the humidification unit 14. The flow path forming portion 123 located in the middle portion constitutes a hollow portion for allowing humidifying air to pass therethrough, and conveys humidifying air introduced from the humidifying hose connecting portion 122 in a tip direction, thereby providing a humidifying air jet port. Emission from the air flow generated by the cross flow fan 12 from 124.

[Contact piping]

The cross-sectional structure of the communication pipe 6 is shown in FIG.

The piping member 161 is comprised by the heat insulation material, such as foamed polyurethane, in tubular form which has an internal hollow. Inside the piping member 161, the high pressure low temperature piping 162 at the time of heating, the high pressure high temperature piping 163 at the time of heating, and the humidification air piping 164 are arrange | positioned in the refrigerant pipe. Among these, the high pressure high temperature pipe 163 and the humidification air pipe 164 during heating are arranged in the high temperature holding space 165, and the high pressure low temperature pipe 162 during heating is separated from the high temperature holding space 165. It is arrange | positioned in the low temperature piping space 166.

The high pressure low temperature pipe 162 at the time of heating corresponds to the local pipe 31 (refer FIG. 2) taken out from the liquid closing valve 27 of the outdoor air conditioning unit 5, and the high pressure high temperature pipe 163 at the time of heating is outdoor. It corresponds to the local pipe 32 (refer FIG. 2) taken out from the gas closing valve 28 side of the air conditioning unit 5. As shown in FIG.

When humidification operation is carried out at the time of synchronous drying, it is thought that heating operation is often performed at the same time because the outside temperature is low. Therefore, the refrigerant passing through the high-pressure high-temperature pipe 163 during heating by the heating operation is a high temperature, and the air in the humidifying air pipe 164 disposed in the same space as the high-pressure high-temperature pipe 163 during heating maintains a high temperature. Can be. Therefore, moisture in the air conveyed into the humidification air pipe 164 does not condense, and the fall of a humidification amount can be prevented. Since the high-pressure low-temperature pipe 162 at the time of heating becomes low in the low-temperature piping space 166 insulated from the high-temperature holding space 165 in the piping member 161, the high-pressure low-temperature pipe at the time of heating ( 162) is very small.

In addition, since the high pressure low temperature pipe 162 at the time of heating, the high pressure high temperature pipe 163 at the time of heating, and the pipe 164 for humidification air are arrange | positioned in one piping member 161, the whole pipe diameter becomes small and conventionally It is possible to store in the refrigerant piping duct of the.

[Other examples of contact piping]

(A) In FIG. 5, the hollow part 168 is provided in the high temperature holding space 165, The high pressure high temperature piping 163 and the humidification air piping 164 are accommodated in close contact at the time of heating.

In this case, the high temperature holding effect by the high pressure high temperature piping 163 at the time of heating is high, and the humidification amount in the humidifying air piping 164 can be hold | maintained moderately.

(B) As shown in FIG. 5, it is also possible to arrange | position the communication wire 167 in the piping member 161 for electrically connecting the outdoor air conditioning unit 5 and the indoor air conditioning unit 2 to it. In this case, the refrigerant pipe, the humidifying air pipe and the communication wire can be arranged integrally, thereby improving the work efficiency during processing.

In the air conditioner of Claim 1, the refrigerant piping which connects an outdoor refrigerant circuit and an indoor refrigerant circuit, and the humidification air piping which connects a humidification unit and an indoor air conditioning unit are in the communication piping cut off from the outside with the heat insulating material. At the same time, since the high-pressure high-temperature pipe during heating in the refrigerant pipe is arranged in the same space as the humidifying air pipe, the air temperature in the humidifying air pipe can be maintained at a high temperature, and the shortage of the humidification amount can be prevented. . Moreover, by arrange | positioning each pipe | tube integrally in a communication pipe | tube, it becomes possible to improve the work efficiency at the time of construction, and to make the whole pipe diameter small.

In the air conditioner according to claim 2, the humidifying air pipe is less affected by the refrigerant temperature passing through the high-pressure low-temperature pipe during heating, and the air temperature in the humidifying air pipe can be maintained at a high temperature.

In the air conditioner of Claim 3, it becomes possible to arrange | position a refrigerant | coolant piping, the humidification air piping, and a communication piping integrally, and it becomes possible to improve the work efficiency at the time of construction.

Claims (3)

An outdoor air conditioning unit 5 having an outdoor refrigerant circuit, An indoor air conditioning unit (2) having an indoor refrigerant circuit connected to the outdoor refrigerant circuit; Humidification unit 4 which adsorbs moisture from the outdoor air to generate humidified air, and supplies the humidified air to the indoor air conditioning unit 2. An air conditioner 1 having The refrigerant pipes 162 and 163 for connecting the outdoor refrigerant circuit and the indoor refrigerant circuit, and the humidifying air pipe 164 for connecting the humidification unit 4 and the indoor air conditioning unit 2 to the outside air by a heat insulating material. The high pressure high temperature pipe 163 is disposed in the same space 165 as the humidifying air pipe 164 during heating of the refrigerant pipe. Air conditioner. The method of claim 1, The high pressure low temperature pipe 162 during heating of the refrigerant pipe is an air conditioner disposed in a space 166 that is different from the space 165 in which the high pressure high temperature pipe 163 and the humidifying air pipe 164 are disposed. . The method according to claim 1 or 2, An air conditioner (167) disposed in the communication pipe (161) for electrically connecting the outdoor air conditioning unit (5) and the indoor air conditioning unit (2).