KR100724376B1 - Unitary airconditioner - Google Patents

Abstract

The unitary air conditioner according to the present invention includes a common outdoor unit fixedly installed on the outside of a building and having an outdoor side heat exchanger therein, and connected to the common outdoor unit to be installed in the interior of the building and to heat exchange inside the inside of the building. A plurality of duct-type indoor units having a group, and connected to the air inlet and exhaust of the duct-type indoor unit to supply the cold or hot air generated in the duct-type indoor unit to each area of the building, and separated into the wall of each area of the building A plurality of air supply ducts and exhaust ducts to be buried, and a temperature controller installed in each area of the building to detect the room temperature of the corresponding area and determine whether to drive the common outdoor unit by comparing the room temperature with a set temperature. Connected to receive the signal transmitted from the temperature controller, the operation and cooling of the compressor provided in the common outdoor unit It includes a refrigerant distributor which connects the common outdoor unit and each duct type indoor unit in parallel so that the refrigerant can be selectively exchanged between the common outdoor unit and each duct type indoor unit while controlling the flow direction of the common outdoor unit. Can be operated and if additional indoor unit is installed as needed, there is no need to add a separate outdoor unit, which can greatly reduce the cost.

Description

Unitary air conditioner {UNITARY AIRCONDITIONER}

1 is a schematic diagram showing an example of a conventional unitary air conditioner,

Figure 2 is a schematic diagram showing an example of the unitary air conditioner of the present invention,

Figure 3 is a schematic view showing a dispenser of the present invention unitary air conditioner.

** Description of the main parts of the drawing **

110: outdoor unit 121,122: duct type indoor unit

121a, 122a: refrigerant pipe 131,132: air supply duct

141,142 Exhaust duct 151,152 Temperature controller

160: refrigerant distributor 161: control unit

161a: Micom 162a, 162b, 162c: flow control valve

170: detachable indoor unit 170a: refrigerant pipe

The present invention relates to a unitary air conditioner, and more particularly, to a unitary air conditioner having a distributor in the middle thereof so as to connect several indoor units to one outdoor unit.

In general, a unitary air condition system (Unitary Air Condition System) is used to create a cold or hot air in one place by using the air-conditioning equipment provided in the basement of factories, offices, hotels, homes, etc. It is a kind of centralized heating and cooling system that transfers and supplies to individual spaces through.

Unitary air conditioners usually have a zone controller in the middle of the duct so that they can independently supply cold or warm air to individual areas by separating the areas that need air conditioning and heating. Air conditioning equipment is installed independently.

1 is a schematic diagram showing an example of a conventional stand-alone unit air conditioner.

As shown in the drawing, a conventional unitary air conditioner includes a plurality of independent outdoor units 11 and 12 fixedly installed outside a building (two-story house in the drawing) and each having an outdoor heat exchanger therein, and each independent outdoor unit. (11) (12) A plurality of duct-type indoor units having a heat exchanger in the building and fixedly installed at a specific position for each floor in the building as described above, respectively connected in series by the refrigerant pipes (21a) and (22a), respectively. (21) (22), and the cold air or hot air produced by each of the duct type indoor units (21, 22) are connected to the air supply and exhaust ports of the duct type indoor units (21, 22) to supply the interior of the building, respectively. In order to be electrically connected to the plurality of air supply ducts 31, 32 and exhaust ducts 41, 42 which are separately embedded in the wall and ceiling of each floor of the building, and each duct-type indoor unit 21, 22. Installed in each area of the building to detect the room temperature Based on and includes a plurality of temperature controllers 51 and 52 for controlling whether the driving of the outdoor units 11 and 12.

In addition, in the space where the air supply ducts 31 and 32 and the exhaust ducts 41 and 42 cannot be embedded, a separate cold / hot air fan such as a window air conditioner 60 is provided so that the air can be independently matched.

In the conventional stand-alone unit air conditioner as described above, for example, in the case of a two-story house, the temperature controllers 51 and 52 of the respective duct-type indoor units 21 and 22 detect the load of each floor, and the load is the temperature controller. If it is equal to or larger than the preset value set in (51) (52), the compressor provided in the outdoor unit (11) (12) is driven to generate cold air or hot air, and the cold air or hot air is supplied to the air supply duct (31) of the floor. Feed through the 32 evenly throughout the layer.

At this time, if the load of all the floors is higher than the set value, the compressors of all the independent outdoor units 11 and 12 are driven to supply cold or warm air to all the floors. Only the compressors of the outdoor units 11 and 12 were driven to generate and supply cold air or warm air.

However, in the conventional unity air conditioner as described above, as described above, a plurality of independent outdoor units 11 and 12 should be provided in consideration of the temperature deviation in each indoor area, resulting in excessive cost.

In addition, the space without the duct should be provided with an integrated air conditioner, such as a window type air conditioner (60), there was also a problem that the cost is excessive.

The present invention has been made in view of the problems of the heat exchanger of the conventional unity air conditioner as described above, and an object of the present invention is to provide a unity air conditioner that can reduce the cost by air-conditioning several areas at one outdoor unit at the same time.

In order to achieve the object of the present invention, a common outdoor unit fixedly installed on the outside of the building and having an outdoor heat exchanger therein, connected to the common outdoor unit, installed in the interior of the building, and inside the heat exchanger inside each of them. A plurality of duct-type indoor units having a group, and connected to the air inlet and exhaust of the duct-type indoor unit to supply the cold or hot air generated in the duct-type indoor unit to each area of the building, and separated into the wall of each area of the building A plurality of air supply ducts and exhaust ducts to be buried, and a temperature controller installed in each area of the building to detect the room temperature of the corresponding area and determine whether to drive the common outdoor unit by comparing the room temperature with a set temperature. Connected to receive the signal transmitted from the temperature controller and the operation and cooling of the compressor provided in the common outdoor unit At the same time, to control the flow direction and providing the public with the outdoor unit, each ducted the public outdoor unit with a unitary air conditioner comprising a refrigerant distributor that parallel connect each duct-type indoor unit between the indoor unit so that the refrigerant can be selectively exchanged.

Hereinafter, the unitary air conditioner according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

Figure 2 is a schematic diagram showing an example of the unitary air conditioner of the present invention, Figure 3 is a schematic diagram showing a distributor of the unitary air conditioner of the present invention.

As shown in this, the unitary air conditioner according to the present invention is fixed to the outside of the building (two-story house in the figure) and one common outdoor unit 110 having an outdoor heat exchanger (not shown) therein and And a plurality of duct-type indoor units each connected to the outdoor side heat exchanger of the common outdoor unit 110 in parallel with the refrigerant pipes 121a and 122a and fixedly installed at a specific position of each floor in the building, and each having an indoor side heat exchanger therein. Each of the duct type indoor units 121 and 122 is connected to an air supply port and an exhaust port of the duct type indoor units 121 and 122 so as to supply the cold or warm air generated by the duct type indoor units 121 and 122 to the interior of the building. Buildings are electrically connected to a plurality of air supply ducts 131 and 132 and exhaust ducts 141 and 142 which are separately buried on each floor wall and ceiling of a building, and each duct type indoor unit 121 and 122. Installed in each zone to check the room temperature Based on this, a plurality of temperature controllers 151 and 152 for controlling the driving of the common outdoor unit 110 and a plurality of duct types are coupled between the common outdoor unit 110 and the respective duct type indoor units 121 and 122. The indoor unit 121, 122 includes a refrigerant distributor 160 for selectively connecting any duct-type indoor unit to the common outdoor unit 110.

In addition, in a space where the air supply ducts 131 and 132 and the exhaust ducts 141 and 142 may not be buried, a separate hot and cold fan is installed so as to harmonize air independently. It is preferable to install it as a separate indoor unit 170 having an indoor side heat exchanger therein to be connected to the common outdoor unit 110 via the 160. Here, a temperature sensor (not shown) is installed in the indoor heat exchanger of the detachable indoor unit 170 to detect the room temperature and determine whether the refrigerant is supplied.
The temperature controllers 151 and 152 are installed in each room to determine the cooling or heating while detecting each room temperature and comparing with the set values set therein, so that the temperature of the refrigerant distributor 160 is changed through the first signal line 161b to be described later. It is connected to the microcomputer 161a.

The refrigerant distributor 160 includes a control unit 161 for controlling the operation of the compressor of the common outdoor unit 110, and a flow control valve 162a and 162b that opens and closes the corresponding indoor heat exchanger 121, 122, and 170 and the outdoor heat exchanger 110. , 162c).

The controller 161 determines whether to operate the compressor based on a signal transmitted through the temperature controllers 151 and 152 and a signal transmitted through a temperature sensor (not shown), and simultaneously opens or closes each flow control valve 162a162b or 162c. And a signal determined by the microcomputer 161a for determining the degree of opening and closing, the first signal line 161b for electrically connecting the temperature controllers 151, 152 and the temperature sensor to the microcomputer 161a, and the signal of the microcomputer 161a. To the compressor (not shown) of the common outdoor unit 110, the second signal line (161c), and the third signal line for transmitting the signal determined by the microcomputer (161a) to each flow control valve (162a, 162b, 162c) ( 161d).

The flow control valves 162a and 162b are made of solenoid valves which are electrically connected to the microcomputer 161a of the control unit 161 to be automatically opened and closed, and the other flow control valves 162c are supplied to the separate indoor unit 170. It consists of an electronic expansion valve to control the pressure of the refrigerant. This is preferably installed in the middle of the refrigerant pipes 121a, 122a, 170a connected to the inlet side of each indoor side heat exchanger by branching from the outlet side of the outdoor side heat exchanger 110.

The unitary air conditioner of the present invention as described above has the following effects.

For example, in the case of a two-story house, the temperature controllers 151 and 152 of the respective duct type indoor units 121 and 122 detect the current room temperature and compare it with the set value in each area, and then the room temperature exceeds the set value. The operation of the compressor is determined according to the excess level, and the determined signal is transmitted to the microcomputer 161a provided in the control unit 161 of the refrigerant distributor 160 through the first signal line 161b. In the microcomputer 161a of the refrigerant distributor 160, it is determined that the load of the corresponding area needs to be eliminated, and the compressor is driven at an appropriate capacity through the second signal line 161c, and the third signal line 161d is applied. The flow control valves 162a and 162b connected to the indoor heat exchanger are opened to allow the refrigerant passing through the outdoor heat exchanger to flow into the indoor heat exchanger. At the same time, the temperature sensor (not shown) of the separate indoor unit 170 detects the room temperature of the current area and transmits the temperature to the microcomputer 161a of the refrigerant distributor 160 through the first signal line 161b. After receiving the signal, the microcomputer 161a of the refrigerant distributor 160 compares the room temperature with the set value and determines that the load needs to be released when the room temperature exceeds the set value. And the flow control valve 162c connected to the indoor heat exchanger through another third signal line 161d to allow the refrigerant passing through the outdoor heat exchanger to flow into the indoor heat exchanger, thereby reducing the load of the corresponding area. To get rid of it.

Here, when the load of all the areas of the building is higher than the set value, all of the flow control valves 162a, 162b, and 162c are opened by the microcomputer 161a, and the refrigerant passing through the outdoor heat exchanger is the refrigerant pipe 121a and 122a. While moving to each indoor side heat exchanger through 170a to supply cold or warm air to all areas of the building, if the load of all areas of the building is lower than the set value, the compressor is stopped by the microcomputer and each flow control valve (162a, 162b, and 162c) are also closed to maintain the present state.

In this way, each indoor unit installed in all areas of the building can be operated organically even with one outdoor unit, which not only saves costs but also eliminates the need to add a separate outdoor unit even if additional indoor units are installed if necessary. Can further reduce.

Unitary air conditioner according to the present invention, by connecting a plurality of indoor units in one outdoor unit in parallel and by installing a refrigerant distributor for distributing and circulating refrigerant therebetween, it is possible to operate several indoor units in one outdoor unit, Therefore, even if the indoor unit is installed more, it is not necessary to add a separate outdoor unit can greatly reduce the cost.

Claims (5)

delete A common outdoor unit fixedly installed outside the building and having an outdoor heat exchanger therein; A plurality of duct type indoor units connected to the common outdoor unit, installed in the interior of the building, and each having an indoor side heat exchanger; A plurality of air supply ducts and exhaust ducts connected to the air inlet and the exhaust port of the duct indoor unit so as to supply the cold air or the warm air made by the duct indoor unit to the respective walls of the building; , A temperature controller installed in each area of the building to detect the room temperature of the corresponding area and determine whether to drive the common outdoor unit by comparing the room temperature with a set temperature; The refrigerant may be selectively exchanged between the common outdoor unit and each duct-type indoor unit while controlling the operation direction of the compressor and the flow direction of the refrigerant provided in the common outdoor unit by receiving a signal transmitted from the temperature controller connected to the temperature controller. Unit air conditioner including a refrigerant distributor for connecting the common outdoor unit and each duct type indoor unit in parallel. The method of claim 2, The coolant distributor is electrically connected to a temperature controller and has a control unit having a microcomputer to determine whether to operate the compressor of the common outdoor unit, and electrically connected to the control unit according to the command of the microcomputer and the common outdoor unit and the corresponding duct type. Unitary air conditioner comprising a plurality of flow control valve for selectively opening and closing the refrigerant pipe between the indoor unit. The method according to claim 2 or 3, Detachable indoor unit installed in the area to directly intake air in the area without air supply duct and exhaust duct in the building, and supply it to the area after heat exchange, and detect the room temperature and transfer it to the refrigerant distributor and share the same in the refrigerant distributor. A unitary air conditioner including a temperature sensor installed in the separate indoor unit to determine whether to operate the compressor of the outdoor unit and to supply the refrigerant of the appropriate pressure to the separate indoor unit. The method of claim 4, wherein The detachable indoor unit is directly connected to the control unit of the refrigerant distributor by a communication line so that the unit can determine whether or not the flow control valve installed between the separate indoor unit and the common outdoor unit in the refrigerant distributor.

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