ES2654777T3 - Air conditioner - Google Patents

Abstract

Air conditioner for conditioning a space (72) within a building (70) comprising: a heat source unit (30) having a heat exchanger unit (31) comprising a first heat exchanger (5) arranged in a first cover (2) and configured to exchange heat with a heat source and a compressor unit (32) comprising a compressor (37) arranged in a second cover (44) separated from the first cover; and at least one indoor unit (50) having a second heat exchanger (53) configured to exchange heat with the space to be conditioned and which is in fluid communication with the heat exchanger unit and / or with the heat exchanger unit. compressor, characterized in that the heat exchanger unit (31) is arranged inside the building and in fluid communication with the outside of the building.

Description

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compressor unit 32, the refrigerant flows partly through the refrigerant pipe 52 and then from the subcooling expansion valve 41 and the subcooling heat exchanger 40 and partly through the refrigerant pipe 49 which it is introduced through the third refrigerant pipe connection 46, a refrigerant pipe and the third refrigerant connection 54 until it enters the indoor unit 50. The refrigerant expands

5 then also by the internal expansion valve 56 and evaporates in the heat exchanger 53 (the heat exchanger 53 functions as an evaporator, cooling the space 72 to be conditioned. Consequently, the heat is transferred from the air into the space to be conditioned to the refrigerant flowing through the heat exchanger 53. Finally, the refrigerant is introduced again through the fourth refrigerant pipe connections 55, 47 and the refrigerant pipe in the unit compressor 32.

As is generally known, the capacity of an air conditioner on the inner side is the multiplication of enthalpy and mass flow. Therefore, a reduced mass flow can be used when the enthalpy is increased. The subcooling heat exchanger serves to increase the enthalpy on the inner side. As a consequence, mass flow can be reduced without negatively affecting capacity. As a result, the fall of

15 pressure in the liquid line so that compressor 37 needs to provide less work, improving the efficiency of the entire system.

During heating, this circuit is reversed, in which the heating is shown by dashed arrows in Fig. 1. The process is in principle the same. In any case, the first heat exchanger 5 functions as an evaporator while the second heat exchanger 53 functions as a condenser during heating. In particular, refrigerant is introduced into the compressor unit 32 through the first refrigerant pipe connection 42, flows through the four-way valve 39 until entering the accumulator 38 and then compressed into the compressor 37 before flow into the four-way valve 39 and through the fourth refrigerant pipe connections 47, 55 and the refrigerant pipe until entering the indoor unit 50 and in particular the

25 internal heat exchanger 53, where the refrigerant condenses (the internal heat exchanger 53 functions as a condenser). Subsequently, the refrigerant is expanded by the expansion valve 56 and then reintroduced through the third refrigerant pipe interconnections 54, 46 into the compressor unit 32 where the refrigerant flows into the pipe 49 and passes to the heat exchanger. subcooling heat 40. By means of an injection of refrigerant after the evaporator, suction overheating can be optimized before the compressor. As a result, the temperature discharge can be reduced with the beneficial effect of better system efficiency and a long service life.

Subsequently, part of the refrigerant flows into the refrigerant pipe 52, expands in the subcooling expansion valve 41 and flows through the subcooling heat exchanger 40 before being reintroduced into the refrigerant pipe 51 upstream of the accumulator 38, thereby precooling the refrigerant that flows through the refrigerant pipe 49 and that passes the subcooling heat exchanger

40. The remaining part flows into the heat exchanger unit 31 through the second refrigerant pipe connections 43 and 34 and the refrigerant pipe. The refrigerant continues to expand through the main expansion valve 33 in the heat exchanger unit 31 and then evaporates in the heat exchanger 5 (the heat exchanger 5 functions as an evaporator) before being reintroduced into the compressor unit 32 through of the first connections of refrigerant pipe 35 and 42 and of the refrigerant pipe.

Due to the division of the compressor module 32 and the heat exchanger module 31, the compressor unit 32 can be installed in areas that are not sensitive to noise so as not to cause discomfort due to

45 compressor even if it is arranged inside. In addition, the cover 44 of the compressor unit 32 may be well insulated with sound insulation. Furthermore, there is no compressor noise in the air flowing through the exchanger unit 31 due to the concept of division between the heat exchanger unit 31 and the compressor unit 32 that could be transferred to the space to be conditioned.

Due to the low weight per unit of the heat exchanger unit 31 and the compressor unit 32, the installation is improved. In addition, the compressor unit 32 can be installed on the ground so that there is no need to lift the heavy compressor module. Due to the relatively small plant (width and depth) of the compressor unit 32 and to a lower height of the compressor unit 32 and in particular its cover 44, the compressor unit 32 may even be hidden when it is disposed within the room to be conditioned, such

55 as under a sideboard or countertop.

The heat exchanger unit 31 also has the advantage that there are no noise disturbances. Because the compressor is not contained in the heat exchanger unit 31, the only noise that can enter the air stream is fan noise, so that the noise in the air stream is drastically reduced. In addition, the cover may be completely closed with respect to the space 72 to be conditioned, so that no sounds are transferred to the space. In addition, this cover can be well insulated with sound insulation. Due to the lower height of the heat exchanger unit 31, it is easy to hide the unit, for example in the ceiling. Therefore, unit 31 is not visible from the outside. The installation is also improved due to the lower weight compared to units that have the compressor on the same deck and due to the lower height of the

65 heat exchanger unit 31. The lower weight is obtained in particular with the use of the "V" shape of the heat exchanger 5, which allows high efficiency with a relatively low height.

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Claims (1)

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