ES2699190T3 - Air conditioner - Google Patents

Abstract

An air conditioner comprising, an outdoor heat exchanger (2a, 2b) capable of performing a heat exchange between a refrigerant and an outdoor air and which includes an adjustable valve (4a, 4b) whose opening area is variable in a way that the adjustable valve can be used as a desired one of an expansion valve for the refrigerant to use the external heat exchanger as an evaporator and a passage for the refrigerant to use the external heat exchanger as a condenser, a first heat exchanger indoor heat (6a) capable of performing a heat exchange between the refrigerant and an indoor air that has to be cooled and which includes another expansion valve (7a) for the refrigerant that allows the first indoor heat exchanger to be used as another evaporator, a second indoor heat exchanger (6b) capable of performing as another condenser a heat exchange between the refrigerant and an indoor air to be heated, and a compressor (1) to pressurize the refrigerant, characterized in that a valve means (3a, 3b, 4a, 4b, 5, 8a, 8b, 9a, 9b) is capable of change a path of a refrigerant flow between: a main cooling path in which the pressurized refrigerant discharged from the compressor (1) flows to each of the second internal heat exchanger (6b) and the external heat exchanger (2a, 2b) which include the adjustable valve used as the step to use the external heat exchanger (2a, 2b) as the condenser, subsequently the condensed refrigerant discharged from each of the second internal heat exchanger (6b) and the external heat exchanger (2a, 2b) flows to the first indoor heat exchanger (6a), and finally the evaporated refrigerant discharged from the first indoor heat exchanger (6a) returns to the compressor (1), and a main heating path wherein the pressurized refrigerant discharged from the compressor (1) flows to the second indoor heat exchanger (6b), then the condensed refrigerant discharged from the second indoor heat exchanger (6b) flows to each of the first indoor heat exchanger ( 6a) and the external heat exchanger (2a, 2b) which includes the adjustable valve used as the expansion valve to use the external heat exchanger (2a, 2b) as the evaporator, and finally the evaporating refrigerant discharged from each of the first internal heat exchanger (6a) and the external heat exchanger (2a, 2b) returns to the compressor (1); wherein the valve means (3a, 3b, 4a, 4b, 5, 8a, 8b, 9a, 9b) is for changing the flow path of the refrigerant from the main cooling path to the main heating path when a temperature of the outside air is not greater than a predetermined temperature, and a difference in absolute value between a desirable amount in absolute value of thermal energy per unit of time to be exchanged for the first indoor exchanger (6a) and a desirable amount in absolute value of thermal energy per unit of time to be exchanged for the second indoor heat exchanger (6b) is not greater than a predetermined value.

Description

DESCRIPTION

Air conditioner

Background of the Invention

The present invention relates to an air conditioner including a first indoor heat exchanger for heating an air with a refrigerant, a second heat exchanger for cooling the air with the refrigerant, and an outdoor heat exchanger for a required function of , either receive a heat energy from the refrigerant, or radiate the heat energy from the refrigerant as the occasion demands.

In a prior art air conditioner as described in JP-A-2003-130492, a gaseous refrigerant pressurized by a compressor is fed to an indoor heat exchanger to heat an ambient air so that the gaseous refrigerant It is condensed to change to a liquid refrigerant, and a gaseous refrigerant pressurized by another compressor is fed to an outdoor heat exchanger to be condensed and then fed to another indoor heat exchanger to cool the ambient air so that the condensed refrigerant that has of being liquefied by the heat exchanger is evaporated in the other indoor heat exchanger.

In another prior art air conditioner as described in EP1394476 A1 in which heating and cooling operations are performed at the same time, a number of connecting conduits connecting an outdoor unit A and a distributor B is simplified to three for a specific pressure and phase refrigerant to flow through each connecting conduit regardless of the operating condition. The air conditioner includes the outdoor unit A installed in an exterior location, and having in it a compressor and an outdoor heat exchanger, a plurality of indoor C units installed respectively in rooms or interior rooms, each of the C units having therein an electronic expansion valve and an indoor heat exchanger, the distributor B provided between the outdoor unit A and the plurality of indoor units C, for selectively guiding a refrigerant introduced from the outdoor unit A to the plurality of indoor units C according to an operating condition, a four-way valve provided on an outlet side of the compressor, for selectively switching a flow direction of the refrigerant flowing through the outdoor heat exchanger, a first connection conduit derived from a conduit that connects an input side of the compressor with the quarantine valve trodes, for connecting the distributor B to guide the refrigerant, a second connection conduit for connecting the external heat exchanger with the distributor B for guiding the refrigerant, and a selective expansion apparatus provided in the third connection conduit and including an electronic heating expansion unit for selectively expanding the refrigerant.

Brief summary of the invention

An object of the present invention is to provide an air conditioner by means of which the operating efficiency is improved by preventing or restricting an excessive cooling capacity or performance of the first indoor heat exchanger and an insufficient heating capacity or efficiency of the second indoor heat exchanger. when a temperature of an outdoor air is considered to be no greater than a predetermined temperature to cause an excessive heating performance for the outdoor air of the outdoor heat exchanger by decreasing the heating performance or capacity of the second indoor heat exchanger.

According to the invention defined in claim 1, an air conditioner comprising, an external heat exchanger capable of carrying out an exchange of heat between a refrigerant and an outside air and including an adjustable valve whose opening area (to leave passing the refrigerant through the adjustable valve) is variable so that the adjustable valve can be used as a desired (or selected) expansion valve for the refrigerant to use the outdoor heat exchanger as an evaporator and a passage for the refrigerant to use the outdoor heat exchanger as a condenser, a first indoor heat exchanger capable of carrying out a heat exchange between the refrigerant and an indoor air to be cooled (such that a difference between an actual temperature of the interior air that has to be cooled and a desirable temperature of the indoor air that has to be cooled is d is minimized, minimized or conserved automatically or manually, within a desirable range, with a change in a rate of amount of heat exchange energy for cooling with respect to a successive moment, ie, a change in the amount of exchange energy of heat to cool for each unit of time according to the difference between the actual temperature of the indoor air to be cooled and the desirable temperature of the indoor air to be cooled so that the greater the difference between the actual temperature of the indoor air to be cooled and the desirable temperature of the indoor air to be cooled, the higher the amount of energy of the heat exchange for cooling with respect to the next moment or the amount of heat exchange energy for cooling for each unit of time) and that includes another expansion valve for the refrigerant that allows the first heat exchanger inside is used as another evaporator, a second indoor heat exchanger capable of performing as another condenser an exchange of heat between the refrigerant and an indoor air to be heated (in such a way that a difference between a real indoor air temperature has to be heated and a desirable temperature of the indoor air to be heated is decreased, minimized or conserved automatically or manually within a desirable range, with a change in the amount of energy of the heat exchange for heating with respect to the successive moment, that is, a change in the amount of heat exchange energy for heating for each unit of time according to the difference between the actual temperature of the indoor air to be heated and the desirable temperature of the indoor air to be heated so that the greater the difference between the actual temperature of the indoor air to be heated and the desirable temperature of the indoor air to be heated, the higher the rate of amount of heat exchange energy for heating with respect to the succeeding moment or the amount of heat exchange energy for heating with respect to and the amount of heat exchanged. heat exchange energy for heating for each unit of time), and a compressor to pressurize the refrigerant,

since a valve means is capable of changing a flow path of the refrigerant between a main cooling path in which the pressurized refrigerant discharged from the compressor flows to each of the second indoor heat exchanger (like the other condenser) and of the outdoor heat exchanger that includes the adjustable valve used as the step to use the outdoor heat exchanger as the condenser, subsequently the condensed refrigerant discharged from each of the second indoor heat exchanger and the outdoor heat exchanger flows to the first heat exchanger lower heat (like the other evaporator), and finally the evaporated refrigerant discharged from the first indoor heat exchanger returns to the compressor, and a main heating path in which the pressurized refrigerant discharged from the compressor flows to the second lower heat exchanger ( like the other condenser), post The condensed refrigerant discharged from the second indoor heat exchanger flows to each of the first lower heat exchanger (like the other evaporator) and to the outdoor heat exchanger that includes the adjustable valve used as the expansion valve to use the heat exchanger. outside heat such as the evaporator, and finally the evaporated refrigerant discharged from each of the first indoor heat exchanger and the outdoor heat exchanger returns to the compressor, and the valve means changes the flow path of the refrigerant from the main cooling path to the main heating path when an outside air temperature is not greater than a predetermined temperature, and a difference in absolute value between a desirable amount in absolute value of thermal energy per unit time that has to be exchanged by the first indoor heat exchanger and a desired amount The absolute value of thermal energy per unit time that has to be exchanged for the second indoor heat exchanger is not greater than a predetermined value,

an operating efficiency is improved with a temperature of an outdoor air is considered to be no greater than a predetermined temperature which causes an excessive cooling capacity of the first indoor heat exchanger.

The various controls mentioned below do not necessarily need to be performed with calculation in the value or absolute values, and can be performed when the conditions or physical situations defined using the absolute value or values are actually met or fulfilled, regardless of whether the calculation in the value or absolute values is realized or not. That is, the value or absolute values are used to clearly define the conditions or physical situations over which control is performed, but are not used to restrict the scope of the various controls mentioned below to ways of calculating respective using the value or Absolute values.

It is preferable to improve operational efficiency of the air conditioner by preventing or restricting an excessive cooling capacity or performance of the first indoor heat exchanger and an insufficient heating capacity or efficiency of the second indoor heat exchanger that the valve means changes the travel of the flow of refrigerant from the main cooling path to the main heating path

when a difference in absolute value between a desirable quantity in absolute value of thermal energy per unit of time that has to be exchanged by the first indoor heat exchanger and a desirable amount in absolute value of heat energy per unit of time that has to be exchanged by the second indoor heat exchanger is not greater than a predetermined value,

and a difference in absolute value between a quantity in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger and a quantity in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger less than the amount in absolute value of heat energy per unit of time actually exchanged by the first lower heat exchanger is greater than a predetermined reference value.

It is preferable to easily and appropriately estimate the desirable amount in absolute value of thermal energy per unit time that has to be exchanged for each of the first and second heat exchangers that a difference in absolute value between a real indoor air temperature has of being cooled by the first indoor heat exchanger and a desirable temperature of the indoor air to be cooled by the first indoor heat exchanger less than the actual temperature of the indoor air to be cooled by the indoor heat exchanger is a value corresponding to the desirable amount in absolute value of thermal energy per unit of time to be exchanged by the first indoor heat exchanger, and a difference in absolute value between a desirable temperature of the indoor air to be heated by the second internal heat exchanger and a real indoor air temperature that has to be heated When the second indoor heat exchanger is smaller than the desirable temperature of the indoor air to be heated by the second indoor heat exchanger, it is a value corresponding to the desirable amount in absolute value of thermal energy per unit of time to be heated. exchanged for the second interior heat exchanger.

It is preferable to easily and appropriately estimate the desirable amount in absolute value of thermal energy per unit of time to be exchanged for each of the first and second indoor heat exchangers as a product of an interior air flow flowing through the first indoor heat exchanger and a difference in absolute value between a real interior air temperature to be cooled by the first indoor heat exchanger and a desirable interior air temperature to be cooled by the first lower indoor heat exchanger that the actual temperature of the indoor air to be cooled by the first heat exchanger is a value corresponding to the desirable amount in absolute value of thermal energy per unit time that has to be exchanged by the first indoor heat exchanger, and a product of an internal air flow flowing through the second AC exchanger The interior temperature and a difference in absolute value between a real temperature of the indoor air to be heated by the second indoor heat exchanger and a desirable temperature of the indoor air to be heated by the second indoor heat exchanger greater than the temperature The actual interior air to be heated by the second indoor heat exchanger is a value corresponding to the desirable amount in absolute value of the thermal energy per unit time that has to be exchanged by the second indoor heat exchanger.

When at least one of the first and second indoor heat exchangers has a plurality of interior heat sub-heat exchangers connected hydraulically in parallel to each other, the desirable amount in absolute value of thermal energy per unit time that has to be exchanged for at least one of the first and second interior heat exchangers is a total amount of desirable quantities in absolute value of thermal energy per unit time that has to be exchanged by the internal sub-heat exchangers respectively.

To judge easily and appropriately the condition or situation in which the control of the air conditioner is carried out, it is considered when a difference in absolute value in temperature between the indoor air that has to be received from the first indoor heat exchanger and the indoor air discharged from the first indoor heat exchanger is greater than a first reference grade and a difference in absolute value in temperature between the indoor air to be received in the second indoor heat exchanger and the indoor air discharged from the second indoor heat exchanger. internal heat is less than a second reference degree, than the difference in absolute value between the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger and the amount in absolute value of heat energy per unit of time actually exchanged for the second heat exchanger inner less than the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger is greater than the predetermined reference value.

To judge easily and appropriately the condition or situation in which the control of the air conditioner is carried out, it is considered when a pressure of the refrigerant evaporated by the first indoor heat exchanger is lower than a first comparison value and a condensed refrigerant pressure for the second heat exchanger is less than a second comparison value, than the difference in absolute value between the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger and the amount in absolute value of heat energy per unit of time actually exchanged by the second heat exchanger less than the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger is greater than the predetermined reference value.

In order to judge easily and appropriately the condition or situation in which the control of the air conditioner is carried out, it is considered when a difference in absolute value in temperature between the indoor air that has to be received in the first indoor heat exchanger and the air interior discharged from the first heat exchanger / a difference in absolute value in temperature between the indoor air to be received in the second indoor heat exchanger and the indoor air discharged from the second indoor heat exchanger is greater than a degree of reference, that the difference in absolute value between the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger and the amount in absolute value of heat energy per unit of time actually exchanged by the second exchanger of interior heat less than the amount in absolute value of energy The heat value per unit of time actually exchanged by the first indoor heat exchanger is greater than the predetermined reference value.

To correctly and easily detect the excessive cooling performance of the first heat exchanger, it is preferable that when the first heat exchanger has a plurality of first internal sub-heat exchangers connected hydraulically in parallel with each other, the difference in absolute value in temperature between the indoor air that is to be received in the first indoor heat exchanger and the indoor air discharged from the first indoor heat exchanger is the smallest of the differences in absolute value in temperature between the indoor airs that are to be received in the respective first interior sub-heat exchangers and the interior air discharged from the respective first internal sub-heat exchangers.

To correctly and easily detect the insufficient heating performance of the second indoor heat exchanger, it is preferable that when the second indoor heat exchanger has a plurality of second indoor heat sub-heat exchangers connected in parallel to each other, and the difference in absolute value in temperature between the indoor air that has to be received in the second indoor heat exchanger and the indoor air discharged from the second indoor heat exchanger is the largest of the differences in absolute value in temperature between the interior airs to be received taken in the second interior sub-heat exchangers and the interior airs discharged from the respective second interior heat sub-heat exchangers.

It is preferable to easily and appropriately estimate the amount in absolute value of thermal energy per unit of time actually exchanged for each of the first and second indoor heat exchangers that a difference in temperature in absolute value between the indoor air to be received in the first indoor heat exchanger and the indoor air discharged from the first indoor heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger, and a difference in temperature in absolute value between the indoor air to be received in the second indoor heat exchanger and the indoor air discharged from the second indoor heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged for the second exchanger of internal heat.

It is preferable to easily and appropriately estimate the amount in absolute value of thermal energy per unit of time actually exchanged for each of the first and second indoor heat exchangers as a product of an interior air flow flowing through the first heat exchanger interior and a difference in temperature in absolute value between the indoor air to be received in the first indoor heat exchanger and the indoor air discharged from the first indoor heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged for the first indoor heat exchanger, and a product of an internal air flow flowing through the second indoor heat exchanger and a difference in temperature in absolute value between the indoor air to be received in the second indoor heat exchanger and indoor air d charged from the second indoor heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger.

It is preferable to easily and appropriately estimate the amount in absolute value of thermal energy per unit of time actually exchanged for each of the first and second indoor heat exchangers that a difference in temperature in absolute value between the refrigerant received in the first heat exchanger inside and the refrigerant discharged from the first indoor heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger, and a difference in temperature in absolute value between the refrigerant received in the second indoor heat exchanger and the refrigerant discharged from the second indoor heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger.

It is preferable to easily and appropriately estimate the amount in absolute value of thermal energy per unit of time actually exchanged for each of the first and second indoor heat exchangers as a product of a mass flow rate of the refrigerant flowing through the first heat exchanger of heat and a difference in temperature in absolute value between the refrigerant received in the first indoor heat exchanger and the refrigerant discharged from the first indoor heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the first internal heat exchanger, and a product of a mass flow of the refrigerant flowing through the second indoor heat exchanger and a difference in temperature in absolute value between the refrigerant received in the second indoor heat exchanger and the refrigerant downloaded from the second Internal heat exchanger is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger.

It is preferable to correctly and stably detect at least one of actual and desirable amounts of heat energy exchanged by each of the first and second indoor heat exchangers that at least one of the actual and desirable quantities of heat energy exchanged for each of the first and second second interior heat exchangers are detected by the air conditioner after at least a predetermined period of time has elapsed since a change between the main cooling path and the main heating path.

To easily and appropriately judge the condition or situation in which control of the air conditioner is performed when the valve means has a four-way valve (3a, 3b), it is preferable that it be detected when the four-way valve is configured in a condition ON (ON) or in a condition OFF (OFF) from a value of electric current applied to the four-way valve, the indoor heat exchanger has a thermistor to measure the temperature of the refrigerant in the heat exchanger outside, and it is detected when the outdoor heat exchanger is used in the evaporator condition or in the condenser condition from the temperature of the refrigerant measured by the thermistor so that when the measured temperature of the refrigerant is less than a predetermined temperature , the outdoor heat exchanger is considered to be used as the evaporator, and when the measured temperature of The refrigerant is not less than the predetermined temperature, the outdoor heat exchanger is considered to be used as the condenser. It is preferable that the detected conditions of the four-way valve and the outdoor heat exchanger are indicated on at least one of the remote controller to control the air conditioner and the outdoor heat exchanger.

An air conditioner may comprise an outdoor unit having a compressor (1), a plurality of four-way valves (3a, 3b) connected to the compressor to change a flow direction of a refrigerant, a plurality of external heat exchangers ( 2a, 2b), and external electronic expansion valves (4a, 4b) connected to the external heat exchangers respectively, and a plurality of indoor units having respective internal heat exchangers, respective internal electronic expansion valves and respective cutoff valves and connected to the external heat exchangers through a conduit for gaseous state refrigerant and a conduit for liquid state refrigerant wherein a refrigerant cycle is formed having one of the indoor units operable to cool one indoor air and the other of indoor units operable to heat indoor air, and an operation n the air conditioner is switched to a main cooling mode using the outdoor heat exchanger as a condenser when a cooling load is greater than a heating load, and to a main heating mode using the outdoor heat exchanger as an evaporator when the heating load is greater than the cooling load,

wherein the operation of the air conditioner is changed from the main cooling mode to the main heating mode when a temperature of an outdoor air is not greater than a predetermined temperature, and a difference between the cooling load and the heating load is not is greater than a certain value.

Other objects, features and advantages of the invention will become apparent from the following description of the embodiments of the invention taken in combination with the accompanying drawings.

Brief description of the different views of the drawings

Figure 1 is a block diagram showing a refrigeration cycle as an embodiment capable of heating an air and cooling the air simultaneously.

Figure 2 is a block diagram showing a flow path of a refrigerant and operations of elements in the refrigeration cycle in different operating modes.

Figure 3 is a flow diagram for changing the operating mode from a main cooling mode to a main heating mode.

Figure 4 includes diagrams showing relationships between a capacity (thermal energy) and a refrigerant pressure in main cooling mode and main heating mode.

Figure 5 includes diagrams showing relationships between capacity (thermal energy) and an ambient temperature in main cooling mode and main heating mode.

Figure 6 is a diagram showing a relationship between the cooling and heating capacities and the ambient temperature in main cooling mode and main heating mode.

Detailed description of the invention

Next, an air conditioner will be described as an embodiment of the invention with reference to the drawings.

Figures 1 and 2 show a cooling cycle capable of simultaneously heating and cooling, a top drawing of Figure 1 shows a full cooling mode, a lower drawing of the same shows a main cooling mode during simultaneous heating and cooling operations , a top drawing of Figure 2 shows a main heating mode during simultaneous heating and cooling operations, a lower drawing of the same shows a complete heating mode, and an arrow mark shows a flow of a refrigerant.

The refrigeration cycle is constituted by a compressor 1, a plurality of external heat exchangers 2a and 2b, externally controlled electronically controlled expansion valves 4a and 4b attached to the external heat exchangers 2a and 2b, a check valve 5, a unit outer including four-way valves 3a and 3b for changing a refrigerant flow path, and at least two, for example, k indoor units that are connected to the outdoor unit through gas and liquid conduits and include heat exchangers respective internal 6a and 6b with respective internal electronically controlled expansion valves 7a and 7b and respective pairs of valves 8a and 9a and valves 8b and 9b (one filled in black is closed, and one filled in white is open).

Next, the main cooling mode and the main heating mode will be described in detail.

In the main cooling mode (during simultaneous heating and cooling), the gaseous refrigerant discharged from the compressor 1 is fed to the outdoor heat exchanger 2b and the indoor heat exchanger 6b as condensers so that it is changed to the liquid refrigerant by the exchange of heat, and subsequently the liquid refrigerant is fed to the indoor heat exchanger 6a as an evaporator. The liquid refrigerant is vaporized in the indoor heat exchanger 6a, and the vaporized refrigerant is recovered in the compressor 1. When a quantity of absolute value heat energy exchanged through the indoor heat exchanger 6b as the condenser is less than the amount of absolute value heat energy exchanged through the indoor heat exchanger 6a as the evaporator, a difference between them is radiated from outdoor heat exchanger 2b as the condenser.

In the main heating mode (during simultaneous heating and cooling), the refrigerant discharged from the compressor 1 flows to the indoor heat exchanger 6b as the condenser to perform the heat exchange, and the liquefied refrigerant is fed to the outdoor heat exchanger 2a and to the indoor heat exchanger 6a as the evaporator, and the refrigerant vaporized by the heat exchange by them returns to the compressor 1. A quantity of heat exchange energy heat exchanged by the indoor heat exchanger 6b as the condenser is balanced with a quantity of heat exchange energy heat exchanged by the indoor heat exchanger 6a and the outdoor heat exchanger 2a as the evaporator.

As mentioned above, in the air conditioner for heating and cooling simultaneously, an intended purpose and / or capacity of the outdoor heat exchanger is changed to drive both the indoor room heater and the indoor room cooler, and a difference in The amount of thermal energy exchanged between the internal cooling and the internal heating is compensated by the external heat exchanger to form the refrigeration cycle. Incidentally, when an inner cooling load Qei and an inner heating load Qci are substantially equal to each other, an outer heat exchange quantity Qo for a heat other than a thermal input from the compressor is not necessary, and may be zero, of so that if the quantity Qo of external heat exchange by the outdoor heat exchanger is greater than zero as has been done in the prior art, the amount Qci of heat exchange of the indoor heat exchanger as the condenser is decreased by the amount QCO of heat exchange of the outdoor heat exchanger as the condenser when in main cooling mode. Furthermore, in the main heating mode, the quantity Qei of and heat exchange of the indoor heat exchanger as the evaporator is decreased by the amount Qeo of heat exchange of the outdoor heat exchanger as the evaporator. When the outside temperature is significantly low or high to increase the amount of heat exchange by the outdoor heat exchanger, an effect thereby increases.

In the main cooling mode and in the main heating mode, it is difficult for the cooling capacity to be sufficient and it is easy for the heating capacity to be sufficient when the ambient temperature is high, it is easy for the cooling capacity to be sufficient and it is difficult that the heating capacity is sufficient when the ambient temperature is low, and these relationships during simultaneous heating and cooling will be explained in detail with reference to Figure 4 showing a relationship in the refrigeration cycle (a diagram whose ordinates correspond to the pressure and whose abscissas correspond to the capacity (amount of thermal energy) and Figure 5 that shows a relationship between the ambient temperature (exterior) and the capacity (amount of thermal energy) of each part.

(in main cooling mode)

When the amount of heat exchange of the indoor heat exchanger to cool the ambient air and the amount of heat exchange of the indoor heat exchanger to heat the ambient air are balanced with each other except for the power Pc applied by the compressor to the refrigerant, an enthalpy would cease for the required cooling capacity is supplied from the indoor heat exchanger 6b to heat the ambient air. However, if the refrigerant flows through the outdoor unit, the high-pressure, high-temperature gaseous refrigerant flows through the outdoor heat exchanger 2b to generate the heat exchange amount Qco radiated from the outdoor heat exchanger as the heat exchanger. condenser. Therefore, when the quantity Qt of heat exchange on the absorption side of the heat energy in the refrigeration cycle is kept unchanged, as the enthalpy necessary for the required cooling capacity is a total amount of the amount of exchange Qco heat of the outdoor heat exchanger as the condenser and the Qci amount of heat exchange of the indoor heat exchanger as the condenser, the Qci amount of heat exchange of the indoor heat exchanger as the condenser is less than the quantity Qt of heat exchange heat from the absorption side of heat energy in the heat exchange quantity Qco of the outdoor heat exchanger as the condenser.

Therefore, the greater the heat exchange quantity Qco of the outdoor heat exchanger as the condenser, the lower the heat exchange quantity Qci of the outdoor heat exchanger as the condenser (i.e. the capacity of the heat exchanger for heat the ambient air). This situation occurs when the ambient temperature is low to accelerate the heat radiation of the outdoor heat exchanger 2b as the condenser. Therefore, an operation efficiency for simultaneous heating and cooling is low.

Conversely, when the ambient temperature is high to decelerate the heat exchange amount Qco of the outdoor heat exchanger 2b as the condenser, the heat exchange amount Qci of the indoor heat exchanger as the condenser becomes large. With respect to the input power Pc from the compressor, when Qt is maintained unchanged, the heat exchange quantity Qei of the indoor heat exchanger as the evaporator and the input power Pc from the compressor change inversely with respect to each other , so that the heat exchange quantity Qei of the indoor heat exchanger as the evaporator is decreased in the input power Pc from the compressor.

(in main heating mode)

When the amount of heat exchange of the indoor heat exchanger to cool the ambient air and the amount of heat exchange of the indoor heat exchanger to heat the ambient air are balanced with each other in the main heating mode, an enthalpy necessary for the Required heating capacity is supplied from the Qei heat exchange quantity of the indoor heat exchanger as the evaporator and the power of Pc input from the compressor. However, if the heat exchange quantity Qeo of the outdoor heat exchanger as the evaporator exists and the quantity Qt of heat exchange on the heat energy emitting side in the refrigeration cycle is maintained unchanged, as the enthalpy difference necessary for the required heating capacity is a total amount of the heat exchange amount Qeo of the outdoor heat exchanger as the evaporator, the heat exchange quantity Qei of the indoor heat exchanger as the evaporator and the power input Pc from the compressor, the heat exchange quantity Qei of the indoor heat exchanger as the evaporator is less than the quantity Qt of heat exchange of the heat energy emitting side by the quantity Qeo of heat exchange of the outdoor heat exchanger as the evaporator.

Therefore, the Qeo amount of heat exchange of the outdoor heat exchanger as the evaporator and the heat exchange quantity Qei of the indoor heat exchanger as the evaporator change inversely with respect to each other, so that the amount Qei of exchange Heat of the indoor heat exchanger as the evaporator is decreased by the amount of heat exchange Qeo of the outdoor heat exchanger as the evaporator. This situation occurs when the ambient temperature is high to accelerate the heat absorption of the outdoor heat exchanger such as the evaporator, and increase the Qeo amount of heat exchange of the outdoor heat exchanger as the evaporator, the Qei amount of heat exchange of the heat exchanger. Indoor heat exchanger as the evaporator is decreased. Therefore, an operation efficiency for simultaneous heating and cooling is low.

As mentioned above, the heating capacity is insufficient at the low ambient temperature in the main cooling mode, and the cooling capacity is insufficient at the high ambient temperature in the main heating mode, so that an input power for the compressor it needs to be increased to compensate for this inadequacy of capacity, and an operational efficiency during simultaneous heating and cooling is diminished.

In the embodiment, the operating mode is changed between the main heating mode and the main cooling mode according to a detection of insufficiency of the heating or cooling capacity based on a decision value for each of the capacity of the internal heat exchanger to cool the ambient air and the capacity of the indoor heat exchanger to heat the ambient air, in addition to a judgment based on a rate between the cooling load and the heating load.

That is, when the cooling load of the ambient air and the heating load of the ambient air are substantially equal to each other, and the ambient temperature is low, the insufficiency of the heating capacity is detected so that the main cooling mode is replaced by the main heating mode in which the outdoor heat exchanger is used as the evaporator forming the refrigeration cycle. Therefore, the amount of heat exchange of the outdoor heat exchanger is decreased to prevent the condensing pressure from decreasing, so that the ability to heat the ambient air is maintained, and an excessive decrease in the evaporation pressure is prevented. Therefore, the cooling capacity is restricted so that it does not become excessive when the ambient temperature is low, and the efficiency for simultaneous heating and cooling is increased.

In the main cooling mode, when the heat exchange quantity Qco of the outdoor heat exchanger as the condenser is zero, the heat exchange is performed only by the indoor heat exchanger as the evaporator and the indoor heat exchanger as the heat exchanger. capacitor, so that the heat radiation or heat absorption added by the outdoor heat exchanger does not exist and all of the heat energy circulates between the indoor heat exchangers to increase the operating efficiency. As an indicator that shows the operational efficiency in simultaneous heating and cooling, the operational efficiency in simultaneous heating and cooling is indicated by COP (S) calculated by formula 1, and the heat exchange quantities in the modes are calculated by the formulas 2 and 3 respectively.

P (fórmula 1)operating efficiency:

P (formula 1)

main cooling mode; Qco Qci = Qei Pc (formula 2)

main heating mode; Qci = Qeo Qei Pc (formula 3)

operational efficiency (main cooling mode)

(fórmula 4) :

(formula 4)

operational efficiency (main heating mode)

Therefore, the operating efficiency (the main cooling mode) and the operating efficiency (the main heating mode) are calculated together with formulas 4 and 5.

As mentioned before, when Qei Pc = constant = Qt (in the main cooling mode) or Qci = Qt (in the main heating mode) the smaller the heat exchange quantity Qco of the outdoor heat exchanger as the Condenser or smaller is the Qeo amount of heat exchange from the outdoor heat exchanger as the evaporator, the higher the COP for simultaneous heating and cooling.

Incidentally, in Figure 6, the cooling and heating capacities in the main cooling mode as shown in Figure 5 and the cooling and heating capacities in the main heating mode overlap each other, cooling capacity Qei is excessive while the heating capacity Qci is insufficient during the main cooling mode at the purple room temperature in Figure 6, and a condition shown by the mark O is changed to a condition shown by the mark "¿and changing to the main mode of heating so that the equilibrium situation is obtained for the high operational efficiency of simultaneous heating and cooling.

A change from the main cooling mode to the main heating mode is carried out in the following condition.

condition (c1): Lh> 0 and a number of exchanger or internal heat exchangers in cooling operation = 0,

or

condition (c2): a number of indoor exchangers or heat exchangers in heating operation> 0 and Lh> 1.25 Lr and at least one minute elapsed after the increase in the number of exchangers or indoor heat exchangers,

or

condition (c3): a number of indoor exchangers or exchangers in heating operation> 0 and Lh> 0.9 Lr and AThm - ATcm <1 and at least one minute after the increase in the number of the indoor exchanger or heat exchangers.

A change from the main heating mode to the main cooling mode is carried out in the following condition.

condition (c4): a number of exchangers or internal heat exchangers in the heating operation = 0, or

condition (c5): a number of indoor exchangers or heat exchangers in cooling operation> 0 and L ^r > 1.25 L ^h and at least one minute elapsed after the increase in the number of indoor exchangers or heat exchangers, or

condition (c6): a number of indoor exchangers or heat exchangers in cooling operation> 0 and L ^r > 0.9 L ^h and AThm - ATcm <1 and at least one minute elapsed after the increase in the number of the exchanger or exchangers of internal heat.

Here, the notes are as follows:

L ^r : a total quantity of heat exchanger loads or internal heat exchangers for heating, L ^h : a total amount of exchanger cooling loads or indoor heat exchangers for cooling, T ^s : set temperature, Ti: temperature of air in the room, ATc: a difference between the air temperature in the room and the temperature set for the cooling operation, ATh: a difference between the air temperature in the room and the temperature set for heating operation, hp ( R): capacity of indoor heat exchanger for cooling, hp (H): capacity of indoor heat exchanger for heating, HP: capacity of external heat exchanger,

AThm: a maximum value of ATh, ATcm: a maximum value of ATc,

K: correction coefficient has a value of 1.0 when a flow of air is high, a value of 1.0 when thermostat is activated, a value of 0.1 when thermostat is deactivated, and a value of 0 when it is stopped , V: correction coefficient of a value of 1.0 when a flow of air is high, a value of 7/8 when the air flow is medium, and has a value of 3/4 when the air flow is low .

Under these conditions (c1) - (c6) to change the operating mode, as only one rate is considered between the heating and cooling loads, at least one of the following conditions (C7-1), (C7-2) and ( C7-3) is considered to change from the main cooling mode to the main heating mode when the ambient temperature is low to increase the capacity of the heat exchanger to cool the ambient air.

condition (c7-1)

ATcmin> a and AThmax <b (and at least four minutes after changing the operating mode, and preferably a = 12 with b = 15

ATcmin is a minimum value of (Ti - Ti), AThmax is a maximum value of (Ti - Ti), and Ti is an air temperature after passing through the internal heat exchanger. That is, during the main cooling mode, when the minimum ATc of the temperature differences between the air received inside and flowing out of the respective indoor heat exchangers to cool the air is greater than at a maximum ATh of the difference of temperature between the air taken inside and flowing out of the respective indoor heat exchangers to heat the air is less than b, the operating mode is changed to the main heating mode.

condition (C7-2)

Ps <Pso - y (y = 0,17) and Pd <Pdo - ^ (^ = 0,15) (and preferably Pd / (Pso + 0,13) <£ (£ = 2,4)

Ps: coolant pressure on the low pressure side (evaporation pressure), Pd: coolant pressure on the high pressure side (condensing pressure), Pso: desired evaporation pressure for cooling, Pdo: desired condensing pressure for heating. That is, at least during the main cooling mode, when the evaporation pressure detected in the indoor heat exchanger to cool the ambient air is less than (the desired evaporation pressure - the predetermined value) and the condensing pressure detected in the indoor heat exchanger to heat the ambient air is less than (the desired condensing pressure - the default value ^), the operating mode is changed to the main heating mode.

condition (C7-3)

ATcmin / AThmax> 2.3 (and preferably at least four minutes after changing the operating mode).

So when the cooling capacitance is excessive and the heating capacitance is insufficient, the operating mode is changed from the main cooling mode to the main heating mode to improve a margin or operational reserve capacity, comfort and operational efficiency . On the other hand, when the cooling capacitance is insufficient and the heating capacitance is excessive, the operating mode is changed from the main heating mode to the main cooling mode.

Figure 3 shows a flow chart of control to change from the main cooling mode to the main heating mode based on the condition (C7-1), and first, during the main cooling mode, a number of exchanger or indoor heat exchangers that are operated to cool the air, and when the number of exchanger or indoor heat exchangers that are operated to cool the air is zero, the operating mode is changed to the main heating mode. When the number of the indoor heat exchanger or heat exchangers that are operated to cool the air is non-zero and the number of indoor heat exchangers or heat exchangers that are operated to heat the air is zero, the load to cool the ambient air and the charge to heat the ambient air are measured. On the other hand, when the number of exchangers or indoor heat exchangers that are operated to heat the air is greater than zero, after one minute elapsed to make the refrigeration cycle stable from an increase in the number of heat exchanger exchangers interiors operated, the charge for cooling the ambient air and the charge for heating the ambient air are measured, and subsequently when the charge for cooling the ambient air is less than the charge for heating the ambient air, ie, L ^h (the total amount of the heat exchange quantities of the cooling loads of the exchanger or indoor heat exchangers to cool the air) - L ^r (the total amount of the heat exchange amounts of the heat loads of the exchanger or indoor heat exchangers to heat the air) is less than a predetermined value B, the operating mode is changed to the main heating mode.

When the number of exchangers or indoor heat exchangers that are operated to heat the air is greater than zero, and not one minute has passed since the increase in the number of exchangers or indoor heat exchangers operated, the charge to cool the air environment and the charge to heat the ambient air are measured, and when the charge to cool the ambient air and the charge to heat the ambient air are substantially equal to each other and ATcmin> 12 and AThmax <15, the operating mode is changed from the Main mode of cooling to the main heating mode.

By changing the operating mode as described above, the operational efficiency for simultaneous heating and cooling is improved, and the operating mode performed is indicated on a remote controller for controlling the outdoor heat exchanger and / or the indoor heat exchangers. A detection of the operating mode to be indicated is made from the conditions of the four-way valves 3a and 3b, and the external heat exchangers (evaporators or condensers) 2a and 2b. With respect to the four-way valves 3a and 3b, the ON / OFF situations (ON / OFF) thereof are detected from electrical currents of the four-way valve coils, and with respect to the heat exchangers external 2a and 2b, the temperatures of the refrigerant are measured by thermistors connected to inputs of the external heat exchangers, so that when the temperature is high, they are considered as condensers and when the temperature is low, they are considered as the evaporators. From a combination of the purposes of using these four-way valves and the external heat exchangers, which operating mode is selected is detected.

As mentioned above, the simultaneous heating and cooling efficiency is increased to improve an annual power consumption efficiency such as a power consumption efficiency of about a given year together with JIS C 9612 and JRA4055 so that the discharge of CO ² is decreased and an amount of the refrigerant used in the air conditioner is decreased.

It should be further understood by those skilled in the art that while the foregoing description has been made on embodiments of the invention, the invention is not limited thereto and various changes and modifications may be made without departing from the scope of the appended claims.

Claims (17)

1 An air conditioner comprising, an outdoor heat exchanger (2a, 2b) capable of exchanging heat between a refrigerant and an outdoor air and including an adjustable valve (4a, 4b) whose opening area is variable so that the adjustable valve can be used as a desired expansion valve for the refrigerant to use the outdoor heat exchanger as an evaporator and a passage for the refrigerant to use the outdoor heat exchanger as a condenser, a first interior heat exchanger (6a) capable of carrying out a heat exchange between the refrigerant and an indoor air to be cooled and including another expansion valve (7a) for the refrigerant which allows the first indoor heat exchanger be used as another evaporator, a second internal heat exchanger (6b) capable of performing as another condenser an exchange of heat between the refrigerant and an indoor air to be heated, and a compressor (1) to pressurize the refrigerant, characterized by that a valve means (3a, 3b, 4a, 4b, 5, 8a, 8b, 9a, 9b) is capable of changing a flow path of the refrigerant between: a main cooling path in which the pressurized refrigerant discharged from the compressor (1) flows to each of the second indoor heat exchanger (6b) and the outdoor heat exchanger (2a, 2b) which include the adjustable valve used as the step to use the outdoor heat exchanger (2a, 2b) as the condenser, subsequently the condensed refrigerant discharged from each of the second indoor heat exchanger (6b) and the outdoor heat exchanger (2a, 2b) flows to the first heat exchanger of inner heat (6a), and finally the evaporated refrigerant discharged from the first indoor heat exchanger (6a) returns to the compressor (1), and a main heating path in which the pressurized refrigerant discharged from the compressor (1) flows to the second indoor heat exchanger (6b), subsequently the condensed refrigerant discharged from the second indoor heat exchanger (6b) flows to each of the first indoor heat exchanger (6a) and outdoor heat exchanger (2a, 2b) that includes the adjustable valve used as the expansion valve to use the outdoor heat exchanger (2a, 2b) as the evaporator, and finally the evaporator refrigerant discharged from each of the first indoor heat exchanger (6a) and the outdoor heat exchanger (2a, 2b) returns to the compressor (1); wherein the valve means (3a, 3b, 4a, 4b, 5, 8a, 8b, 9a, 9b) is for changing the flow path of the refrigerant from the main cooling path to the main heating path when a temperature of the outside air is not greater than a predetermined temperature, and a difference in absolute value between a desirable amount in absolute value of thermal energy per unit time that has to be exchanged by the first indoor exchanger (6a) and a desirable amount in absolute value of thermal energy per unit of time to be exchanged by the second indoor heat exchanger (6b) is not greater than a predetermined value. An air conditioner according to claim 1, wherein the valve means (3a, 3b, 4a, 4b, 5, 8a, 8b, 9a, 9b) is for changing the flow path of the refrigerant from the main path cooling to the main heating path when a difference in absolute value between a desirable amount in absolute value of thermal energy per unit time that has to be exchanged by the first indoor heat exchanger (6a) and a desirable amount in absolute value of heat energy per unit of time to be exchanged by the second indoor heat exchanger (6b) is not greater than a predetermined value, and a difference in absolute value between a quantity in absolute value of heat energy per unit of time actually exchanged by the first internal heat exchanger (6a) and a quantity in absolute value of heat energy per unit of time actually exchanged by the second interca Inner heat exchanger (6b) is less than the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a) is greater than a predetermined reference value. 3. An air conditioner according to any of claims 1-2, wherein to estimate the desirable amount in absolute value of thermal energy per unit time to be exchanged by the first indoor heat exchanger (6a), a difference in absolute value between a real indoor air temperature to be cooled by the first indoor heat exchanger (6a) and a desirable interior air temperature to be cooled by the first lower indoor heat exchanger (6a) that the actual temperature of the indoor air to be cooled by the first heat exchanger (6a) is a value corresponding to the desirable amount in absolute value of thermal energy per unit time that has to be exchanged by the first heat exchanger interior (6a), and, to estimate the desirable amount in absolute value of thermal energy per unit of time that has to be exchanged for the second exchanger of internal heat (6b), a difference in absolute value between a desirable temperature of the indoor air to be heated by the second indoor heat exchanger (6b) and a real temperature of the indoor air to be heated by the second exchanger of internal heat (6a) lower than the desirable temperature of the indoor air to be heated by the second indoor heat exchanger (6b) is a value corresponding to the desirable amount in absolute value of the thermal energy per unit of time that has of to be exchanged by the second indoor heat exchanger (6b). 4. An air conditioner according to any of claims 1-3, wherein, to estimate the amount in absolute value of thermal energy per unit time that has to be exchanged by the first indoor heat exchanger (6a), a product of an interior air flow flowing through the first indoor heat exchanger (6a) and a difference in absolute value between a real indoor air temperature to be cooled by the first indoor heat exchanger (6a) and a desirable temperature of the indoor air to be cooled by the first indoor heat exchanger (6a) lower than the actual indoor air temperature to be cooled by the first indoor heat exchanger (6a) is a value corresponding to the desirable amount in absolute value of thermal energy per unit of time that has to be exchanged by the first indoor heat exchanger (6a), and a product of an air flow rate The flow rate through the second lower heat exchanger (6b) and a difference in absolute value between a real indoor air temperature to be heated by the second indoor heat exchanger (6b) and, to estimate the desirable amount in absolute value of thermal energy per unit of time to be exchanged by the second indoor heat exchanger (6b), a desirable temperature of the indoor air to be heated by the second indoor heat exchanger (6b) greater than the temperature The actual interior air to be heated by the second indoor heat exchanger (6b) is a value corresponding to the desirable amount in absolute value of thermal energy per unit time that has to be exchanged for the second indoor heat exchanger ( 6b). An air conditioner according to any of claims 1-4, wherein at least one of the first and second interior heat exchangers (6a, 6b) has a plurality of internal sub-heat exchangers connected hydraulically in parallel with each other , so that the desirable amount in absolute value of thermal energy per unit time that has to be exchanged for at least one of the first and second indoor heat exchangers (6a, 6b) is a total amount of desirable quantities in absolute value of thermal energy per unit of time that has to be exchanged by the internal sub-heat exchangers respectively. 6. An air conditioner according to claim 2, wherein it is considered when a difference in absolute value in temperature between the indoor air to be received by the first indoor heat exchanger (6a) and the indoor air discharged from the first indoor heat exchanger (6a) is greater than a first reference grade and a difference in absolute value in temperature between the indoor air to be received in the second indoor heat exchanger (6b) and the indoor air discharged from the second inner heat exchanger (6b) is smaller than a second reference degree, than the difference in absolute value between the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a) and the amount in absolute value of heat energy per unit of time actually exchanged for the second indoor heat exchanger (6b) lower than the The absolute value of the heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a) is greater than the predetermined reference value. An air conditioner according to claim 2, wherein it is considered when a refrigerant pressure evaporated by the first indoor heat exchanger (6a) is lower than a first comparison value and a condenser pressure condensed by the second exchanger of internal heat (6b) is less than a second comparison value, than the difference in absolute value between the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a) and the amount in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger (6b) less than the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a) is greater than the default reference value. 8. An air conditioner according to claim 2, wherein it is considered when a difference in absolute value in temperature between the indoor air to be taken in the first indoor heat exchanger (6a) and the indoor air discharged from the first heat exchanger (6a) / a difference in absolute value in temperature between the indoor air to be received in the second indoor heat exchanger (6b) and the indoor air discharged from the second indoor heat exchanger (6b) is greater than a reference grade, than the difference in absolute value between the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a) and the amount in absolute value of heat energy per unit of heat time actually exchanged for the second indoor heat exchanger (6b) less than the amount in absolute value of heat energy per unit of The time actually exchanged by the first indoor heat exchanger (6a) is greater than the predetermined reference value. An air conditioner according to claim 6 or 8, wherein the first heat exchanger has a plurality of first interior sub-heat exchangers connected hydraulically in parallel with each other, and the difference in absolute value in temperature between the air interior that is to be received in the first indoor heat exchanger (6a) and the indoor air discharged from the first indoor heat exchanger (6a) is the smallest of the differences in absolute value in temperature between the indoor air that has to be received in the respective first interior heat sub-heat exchangers and the interior air discharged from the first interior heat sub-heat exchangers. An air conditioner according to any of claims 6, 8 and 9, wherein the second exchanger of inner heat (6b) has a plurality of second internal sub-heat exchangers connected in parallel to each other, and the difference in absolute value in temperature between the indoor air to be received in the second indoor heat exchanger (6b) and the interior air discharged from the second indoor heat exchanger (6b) is the greatest difference in absolute value in temperature between the interior airs to be taken in the second interior sub-heat exchangers and the interior air discharged from the interiors. second interior heat sub-heat exchangers. 11. An air conditioner according to any of claims 2-10, wherein a difference in temperature in absolute value between the indoor air to be received in the first indoor heat exchanger (6a) and the indoor air discharged from the first indoor heat exchanger (6a) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a), and a difference in temperature in absolute value between the air interior to be received in the second indoor heat exchanger (6b) and indoor air discharged from the second indoor heat exchanger (6b) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the second interior heat exchanger (6b). 12. An air conditioner according to any of claims 2-10, wherein, to estimate the amount in absolute value of thermal energy per unit of time actually exchanged by the first indoor heat exchanger (6a), a product of a flow of the interior air flowing through the first indoor heat exchanger (6a) and a difference in temperature in absolute value between the indoor air to be received in the first indoor heat exchanger (6a) and the indoor air discharged from the first indoor heat exchanger (6a) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a), and, to estimate the amount in absolute value of energy thermal per unit time actually exchanged for the second indoor heat exchanger (6b), a product of an internal air flow flowing through through the second inner heat exchanger (6b) and a difference in temperature in absolute value between the indoor air to be taken in the second indoor heat exchanger (6b) and the indoor air discharged from the second indoor heat exchanger ( 6b) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger (6b). 13. An air conditioner according to any of claims 2-10, wherein, to estimate the amount in absolute value of thermal energy per unit of time actually exchanged by the first indoor heat exchanger (6a), a difference in temperature in absolute value between the refrigerant received in the first indoor heat exchanger (6a) and the refrigerant discharged from the first indoor heat exchanger (6a) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a), and a difference in temperature in absolute value between the refrigerant taken in the second indoor heat exchanger (6b) and, to estimate the amount in absolute value of thermal energy per unit of time actually exchanged by the second indoor heat exchanger (6b), the refrigerant discharged from the second exchanged Internal heat r (6b) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger (6b). 14. An air conditioner according to any of claims 2-10, wherein, to estimate the amount in absolute value of thermal energy per unit of time actually exchanged by the first indoor heat exchanger (6a), a product of a mass flow of the refrigerant flowing through the first heat exchanger and a difference in temperature in absolute value between the refrigerant received in the first indoor heat exchanger (6a) and the refrigerant discharged from the first indoor heat exchanger (6a) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the first indoor heat exchanger (6a), and, to estimate the amount in absolute value of thermal energy per unit of time actually exchanged by the second internal heat exchanger (6b), a product of a mass flow of the refrigerant flowing through the second internal heat exchanger (6b) and a difference in temperature in absolute value between the refrigerant received in the second indoor heat exchanger (6b) and the refrigerant discharged from the second indoor heat exchanger (6b) is a value corresponding to the amount in absolute value of heat energy per unit of time actually exchanged by the second indoor heat exchanger (6b). 15. An air conditioner according to any of claims 1-14, wherein at least one of actual and desirable amounts of heat energy exchanged by each of the first and second interior heat exchangers (6a, 6b) is detected by the air conditioner after at least a predetermined period of time has elapsed between the main cooling path and the main heating path. 16. An air conditioner according to any of claims 1-15, wherein the valve means (3a, 3b, 4a, 4b, 5, 8a, 8b, 9a, 9b) has a four-way valve (3a, 3b), and if the four-way valve (3a, 3b) is set to an ON condition (ON) or an OFF condition (OFF) it is detected from a current value applied to the four-way valve (3a) , 3b), the indoor heat exchanger (2a, 2b) has a thermistor to measure a temperature of the refrigerant in the outdoor heat exchanger (2a, 2b), and if the outdoor heat exchanger (2a, 2b) is used in the evaporator condition or in the condenser condition is detected from the temperature of the refrigerant measured by the thermistor so that when the measured temperature of the refrigerant is less than a predetermined temperature, the outdoor heat exchanger is considered to be used as the evaporator, and when the measured temperature of the refrigerant is not less than the temperature By default, the outdoor heat exchanger (2a, 2b) is considered to be used as the condenser. An air conditioner according to claim 16, wherein the detected conditions of the four-way valve (3a, 3b) and the outdoor heat exchanger (2a, 2b) are indicated in at least one of a remote controller for control the air conditioner and the outdoor heat exchanger (2a, 2b).