Window-type air conditioner

Abstract

A split air conditioner having an indoor unit and an outdoor unit. A piping system interconnects the indoor unit with the outdoor unit. The indoor unit has an indoor heat exchanger for cooling or heating air in the indoor unit. The outdoor unit has a compressor, a first outdoor heat exchanger, and a second outdoor heat exchanger. The compressor is configured to drive a refrigerant via the first outdoor heat exchanger and the second outdoor heat exchanger in a refrigerant circuit. The piping system is configured to circulate an energy transport media from the first outdoor heat exchanger via the piping system to the indoor heat exchanger.

Claims

1. An air conditioner configured to be installed in a window, the air conditioner comprising: an indoor unit comprising a single first housing containing an indoor heat exchanger for cooling or heating air in the indoor unit; an outdoor unit comprising a single second housing containing a compressor, a first outdoor heat exchanger, and a second outdoor heat exchanger; a piping system interconnecting the indoor unit with the outdoor unit; and a liquid tank fluidly connected to the piping system and located outside and separate from the first housing and the second housing; wherein: the compressor is configured to drive a refrigerant via the first outdoor heat exchanger and the second outdoor heat exchanger in a refrigerant circuit; the piping system is configured to circulate an energy transport media along a continuous path from the first outdoor heat exchanger to the indoor heat exchanger; and the piping system is configured to receive the energy transport media from the liquid tank and not deliver the energy transport media to the liquid tank.

2. The air conditioner according to claim 1, wherein the energy transport media is a water based solution.

3. The air-conditioner according to claim 1, wherein a main pump is provided in the indoor unit to circulate the energy transport media.

4. The air-conditioner according to claim 1, further comprising a box located under the indoor heat exchanger for collecting condensate water.

5. The air-conditioner according to claim 4, further comprising a pump configured to pump condensate water from the indoor unit to the outdoor unit.

6. The air-conditioner according to claim 1, wherein the piping system comprises a connector provided in the piping system, wherein the connector is configured to connect a first portion of the piping system in the indoor unit to a second portion of the piping system in the outdoor unit.

7. The air-conditioner according to claim 1, further comprising an arrangement for switching the air-conditioner between a cooling mode and a heating mode.

8. The air-conditioner according to claim 1, wherein at least one of the first and second outdoor heat exchangers is made of aluminum.

9. The air conditioner according to claim 6, wherein the connector is located at a top part of the outdoor unit.

10. The air-conditioner according to claim 1, wherein, when the indoor unit is mounted, the liquid tank is located at a top position of the piping system.

11. The air-conditioner according to claim 1, wherein the liquid tank is connected to the piping system by a one-way valve.

12. The air conditioner according to claim 1, wherein the liquid tank is connected to the piping system solely by a tank outlet.

13. The air conditioner according to claim 3, wherein the liquid tank is connected to the piping system by a single flow path, the single flow path connecting the liquid tank to a suction port of the main pump.

14. The air conditioner according to claim 1, wherein the piping system is configured to circulate the energy transport media along the continuous path between the first outdoor heat exchanger and the indoor heat exchanger without passing through the liquid tank.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will now be described in more detail, by way of example, and with reference to the accompanying drawings, in which:

(2) FIG. 1 shows a general view of an AC installation in a window opening, and

(3) FIG. 2 illustrating a detailed exemplary embodiment of an Air-conditioner as shown in FIG. 1.

DETAILED DESCRIPTION

(4) The invention will now be described more fully hereinafter with reference to the accompanying drawings, in which certain embodiments of the invention are shown. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided by way of example so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. For example, like or similar components of different embodiments can be exchanged between different embodiments. For example, the system as described herein is described as a cooling system, but the cooler can equally be a heater if the system is run in a heating mode. Some components can be omitted from different embodiments. Like numbers refer to like elements throughout the description.

(5) As has been realized by the inventor, conventional air-conditioners of a split type are difficult and often expensive to install. Also, a system such as the one described in EP 0468576 requires the compressor, and all components of the refrigeration circuit, including the refrigerant, to be located in the space where cooling is to take place. This will add to space requirement of the indoor unit and also there will be a significant level of noise resulting from the operation of the compressor. Further, the refrigerant remains inside of the space to be conditioned, which is negative in case of leak of refrigerant. It would therefore be advantageous to provide a modified split air-conditioner that can be easily installed and that can provide an indirect-cooling air conditioner working with an external packaged refrigeration system.

(6) FIG. 1 shows a schematic diagram of an embodiment of an air-conditioner 100. The air-conditioner 100 can be said to be of a split type with an indirect cooling system comprising an indoor unit 101 and a packaged outdoor cooling unit 102. The units 101, 102 are interconnected via an intermediate piping system 103. The piping system 103 and can advantageously use an energy transport media that is safe to use such as an aqueous solution. For example, water or water with some additive can be used as an energy transport media. Further, a mechanism 104 for installation of the air conditioner 100 is depicted. Also depicted is a window 105 where the air-conditioner 100 is installed. In this exemplary embodiment the window 105 is a standard hung type window. The air conditioner as described herein can also be installed in other type of windows such as a sliding window or some other openable window. Thus, the cooling system comprises a packaged refrigeration system mounted outside in an outdoor unit 102, an indoor unit 101 installed inside and a circuit that connects both units, which contains an energy transport media. The energy transport media can be at atmospheric pressure. The system can also be operated in another mode where the system is configured to heat the indoor unit. The indoor unit 101 will then be used as a heater.

(7) In FIG. 2, an exemplary implementation of the split type air-conditioner 100 of FIG. 1 is shown in more detail. FIG. 2 shows the indoor unit 101, and the outdoor unit 102. The indoor unit comprises an air-to-liquid heat exchanger 203. The air-to-liquid heat exchanger 203 cools (or heats) the air flowing in the indoor unit 101. Further, a liquid-to-refrigerant heat exchanger 204 is provided in the outdoor unit 102. The liquid-to-refrigerant heat exchanger 204 works as evaporator. Further a main pump 205 is provided to circulate a liquid solution used as an energy transport media from the indoor unit 101 to the outdoor unit 102 (and back again). The main pump can also be located in the outdoor unit 102. The liquid solution is circulated via the piping system 103. In this example the connection system 103 is formed by two connection pipes 206 and 207. Since, the piping system 103 can be made to work at relatively low pressure (around 1 bar), the pipes 206 and 207 can alternatively be hoses or similar devices that are easy to handle and can be provided with connectors that can withstand a low pressure. The outdoor unit 102 further comprises a refrigeration system, comprising a compressor 216 driving a refrigerant via that an air-cooled heat exchanger 215 via an expansion valve 220 and the heat exchanger 204 back to the compressor 216. The refrigeration system of the outdoor unit can be factory installed such that the user or installer does not have to work with the circuit circulating the refrigerant. The refrigerant circulated via the air-cooled heat exchanger 215 can then be filled in the factory. There will then be no need to handle a refrigerant during installation, because the refrigerant circuit of the outdoor unit 102 is factory sealed.

(8) Further, a liquid tank 208 can be located on the top of the system. The liquid tank 208 can be connected to the circuit circulating the energy transport media. In accordance with one example the liquid tank can be connected to the suction port of the main pump 205. The tank 208 can include a level sensor 209 for controlling the amount of liquid solution circulated between the indoor unit 101 and the outdoor unit 102 needed for proper operation of the system 100. A box 210 can be provided under the indoor heat exchanger 203 for collecting any condensate that is generated on the indoor heat exchanger 203. A sensor 211 can be provided to detect the water level inside of the condensate box 210. The sensor 211 can generate a signal that can be used to control a condensate water pump 212. When activated the water pump 212 is adapted to pump water from the box 210 to outside of the indoor unit 101. In particular water can be pumped outside of the building where the indoor unit is mounted to be released on the outside. Hereby an arrangement that can pump condensate water from the indoor unit 101 to the outside is obtained.

(9) In accordance with some embodiments the water is pumped to the outside unit 102. The pumped water can then for example be pumped through a drainage line 213 towards a spray device 214 located on the top of the outdoor air-cooled heat exchanger 215, which is connected to the compressor 216. FIG. 2 further depicts a fan 221 provided in the indoor unit 101 for circulating air in the indoor unit. Also, a fan 222 is provided in the outdoor unit for circulating air in the outdoor unit 102. The piping system 103 can further be provided with a connection device 218. The connection device 218 can for example be a quick connection to in a quick and safe manner interconnect the piping of the indoor unit 101 with the piping of the outdoor unit 102. The connection device 218 can advantageously be located on the top part of the outdoor unit for easy access. By connecting the indoor unit 101 with the outdoor unit 102, an energy transport media can be circulated between the indoor unit 101 and the outdoor unit 102. Also, condensate water can be transported from the indoor unit to the outdoor unit 102 via the piping system 103.

(10) In use, the air conditioner 100 decreases the temperature of the energy transport media using the external packaged AC device of the outdoor unit 102. The cooling capacity of the outdoor-unit 102 is then transported in to the indoor unit 101 via the piping system 103. The cooling capacity is then delivered using the low-pressure air-to liquid heat exchanger 203 of the indoor unit 101. Heat is then returned from the inside unit 101 to the outside unit 102 by returning the energy transport media to the outside unit when having being heated in the indoor unit 101 that is installed in the indoor space to be conditioned. Because the cooling capacity is isolated to the outdoor unit 102 all heavy and noisy components can be confined to the outside unit and the indoor environment can be close to free of noise. Also, there is very little space required for the indoor unit. Because the piping system 103 used to transfer heat between the indoor unit 101 system can be a low-pressure system it can use an energy transport media that is easy to handle, such as water a water based solution, or some other liquid media such as ethanol.

(11) Thus, in accordance with some embodiments, an aqueous media can be used to transport the energy from the indoor space to be conditioned to the evaporator located in the external packaged device. The main pump 205 will ensure the flow of the energy transport media by pumping the aqueous media, and the external cooling unit will reject the heat generated in the process to the ambient outdoor air. This is made possible since the external, packaged cooling system located in the outdoor unit can comprise all the standard constitutive elements in a refrigeration system, such as compressor, condenser, expansion device, evaporator and control system, and refrigerant. In accordance with some embodiments the liquid to refrigerant heat exchanger 204 can be a light brazed plate heat exchanger or a coaxial-type heat exchanger. The liquid to refrigerant heat exchanger 204 can be made of aluminium to make the weight low. The air-to-refrigerant heat exchanger 215 can be a micro channels heat exchanger or a fins & tubes air cooled heat exchanger. The material of the micro channel heat exchanger and or the fins and tube heat exchangers can be Aluminum, and/or aluminum & copper.

(12) By using the system as set out herein, the refrigeration system becomes very small, given the possibility to decrease its size and weight, so facilitating its installation through a window in a residence. Additionally, by having such a compact system with a secondary circuit transporting energy between the indoor unit and the outdoor unit using an energy transport media, the installation will not need to be permanent, and it can be easily removed and reinstalled in different places any number of times according to the convenience of the user. This can be made without having to handle the refrigerant of the external packaged cooling system.

(13) The liquid tank 208 placed on the top of the indoor unit 101 can be provided with an internal one-way valve 224 (shown schematically). By providing the liquid tank 208 at a highest position of the piping system and providing the one-way valve 224 at the liquid tank filling of the piping system with water or any other energy transport media used, can be made once the installation has been done. The positioning of the liquid tank 208 and the one-way valve 224 allows in turn the elimination of the air from the system. This ensures a proper operation of the air-conditioner, and prevents problems like galvanic corrosion due to interaction between e.g. an aqueous solution and oxygen from air.

(14) In accordance with one embodiment, the external packaged cooling system can be provided with a 4-way valve (not shown) in the refrigerant to enable a switch in the direction of the refrigerant flow, allowing the system to work as a heat pump device for winter conditions. Hereby an arrangement is provided whereby the air-conditioner can be switched between a cooling mode and a heating mode. In the heating mode, the energy transport media will introduce the heat generated in the external packaged cooling device of the outdoor unit 102, to circulate to the indoor unit 101 to heat the indoor space where the indoor unit 101 is located.

(15) While it is possible to use any energy transport media to transport energy between the indoor unit 101 and the outdoor unit 102 via the connection system 103, the use of an aqueous solution as energy transport fluid offers the advantage of being innocuous and safe for the user. Further there is no need to pressurize the media in the connection system 103, since it can work at a relatively low pressure, in particular at or near atmospheric pressure. Hereby, the connections of the connection system 103 interconnecting the indoor unit 101 with the outdoor unit 102 can be made less complex compared to systems using pressurized gases above atmospheric pressure.

(16) The present invention offers all the advantages of a standard split AC, in terms of performance, low noise, reliability, but adding versatility and flexibility to the installation process. It also solves the problem of the high initial investment, normally associated to the additional installation cost of standard split AC's.