WO2008014730A1

WO2008014730A1 - Air-conditioning system for a vehicle and method for controlling an air-conditioning system

Info

Publication number: WO2008014730A1
Application number: PCT/DE2006/001357
Authority: WO
Inventors: Noureddine Khelifa; Steffen Korfmann; Wolfgang Krämer
Original assignee: Webasto Ag
Priority date: 2006-08-03
Filing date: 2006-08-03
Publication date: 2008-02-07
Also published as: DE112006004064A5

Abstract

The invention relates to an air-conditioning system for a vehicle. The control of the air-conditioning system takes place as a function of the ambient temperature and the interior temperature of the vehicle, wherein both the loading process and the unloading process can be influenced by said temperatures. It is also proposed to provide a solenoid valve in parallel with an electrical compressor, in order to thereby be able to generate a pressure compensation as the compressor is started.

Description

An air conditioning system for a vehicle and method for controlling an air conditioning system

Field of the invention

The invention relates to an air conditioning system for a vehicle, in particular such with a cold storage.

The invention further relates to a method for controlling such an air conditioning system.

Background of the invention

Air conditioning systems with cold storage are used in particular for standard air conditioning, and they operate on the principle that the cold storage integrated in a refrigeration circuit are charged during engine operation, to then recharge them for cooling purposes with the engine off. It can be provided to always charge the cold storage with the engine running or to keep it in its charged state or to charge it whenever the energy introduced by a compressor in the refrigerant circuit is not needed for direct air conditioning of the vehicle interior. As a result, there may be charge-discharge cycles in which the existing cold in the cold storage is not needed to cool the interior but is lost during the life of the vehicle unused.

Other problems are encountered in connection with the commissioning of a stationary air conditioning. The stationary air conditioning tion has two main tasks. One is to cool the interior of the vehicle for extended periods of time when the vehicle is at a standstill, for example the sleeping cabin of a commercial vehicle. Another advantage of stationary air conditioners is the possibility of pre-cooling a vehicle interior after the vehicle has heated up, for example due to intensive sunshine. The inmates thus have the opportunity to be in a refrigerated interior from the beginning. In this context, it has been noted as a problem that when ^■ heavily heated interiors an extremely high amount of energy must be dissipated via the cooled from the cold storage heat exchanger, which can sometimes lead to excessive discharge of the cold storage or incomplete cooling of the interior.

According to the prior art, various concepts exist for integrating a cold storage in a vehicle. One concept couples the cold storage with the primary air conditioning system of the motor vehicle, namely by connecting an evaporator arranged in a cold storage in parallel to an evaporator used as an air cooler. About this refrigerant circuit, the cold storage can then be loaded. The removal of the cold takes place via a further circuit which contains a heat exchanger in the cold storage and a further heat exchanger for cooling the air to be introduced into the interior. In addition to these integrated cold storage systems but so-called self-contained cold storage systems are known. These are installed in addition to the conventional refrigerant circuit in the vehicle, and they have their own refrigerant circuit with a preferably electrically driven compressor. These systems, which in themselves function well, are still in view of the starting behavior of the electrically driven compressor be improved, namely in relation to the power required when starting the compressor.

The object of the invention is to provide air-conditioning systems and methods for controlling air-conditioning systems in which unnecessary charging or inadvertent charging of the cold accumulator is avoided, the cooling of a strongly heated vehicle interior is accelerated and the start-up behavior of compressors is made less problematic ,

This object is achieved with the features of the independent claims.

Advantageous embodiments of the invention are indicated in the dependent claims.

Summary of the invention

According to a first aspect of the present invention, this relates to an air conditioning system for a vehicle, comprising a cold accumulator, a device for charging the cold accumulator and a control unit for influencing the operating states of the air conditioning system, wherein an ambient temperature sensor is provided, which supplies the control unit with the ambient temperature characterizing signals, and wherein the control unit is designed so that a charging process of the cold accumulator can be initiated or suppressed depending on the ambient temperature. The ambient temperature of the vehicle is a decisive criterion as to whether a charging process of the cold storage may be unnecessary or whether in any case a charging Operation should take place. By taking the ambient temperature into account, the charging behavior of the air conditioning system can be improved.

In particular, it is provided that a charging of the cold accumulator is suppressible when the outside temperature falls below a predetermined temperature threshold. At temperatures that are so low that it is likely that no removal of cold from the cold storage will be desired, the charging of the cold storage is prevented in this way, resulting in energy savings. However, it is preferably possible for the user of the vehicle to charge the cold accumulator even at low outside temperatures by active intervention in the air conditioning system, for example in the case when the driver is aware that he will reach warmer regions in the foreseeable future.

It is particularly useful that a charging process of the cold storage is automatically initiated when the outside temperature exceeds a predetermined temperature threshold and / or a predetermined temperature gradient. Occasionally, the charging function of the air conditioning system is inactive because either a low outside temperature is present or because the driver actively prevents the loading of the cold storage. In these cases, however, a charge of cold storage can be initiated automatically, either at a predetermined outside temperature, which may well remain unnoticed in the interior of the vehicle, or in the event of a sharp increase in temperature, for example after crossing a mountain pass.

According to the first aspect of the invention, this furthermore relates to a method for controlling an air-conditioning system. - -

a vehicle, with a cold storage, a device for charging the cold storage and a control unit for influencing the operating conditions of the air conditioning system, wherein an ambient temperature is detected and the control unit, the ambient temperature characterizing signals are supplied, and wherein a charging of the cold accumulator depending on the ambient temperature initiated or suppressed. In this way, the advantages and particularities of the inventive air conditioning system according to the first aspect of the invention are also realized in the context of a method. This also applies to the following particularly preferred embodiments of the method according to the invention.

This is usefully developed in the way that a charging of the cold accumulator is suppressed when the outside temperature falls below a predetermined temperature threshold.

Furthermore, it may be useful that a charging process of the cold accumulator is automatically initiated when the outside temperature exceeds a predetermined temperature threshold and / or a predetermined temperature gradient.

According to a second aspect of the present invention, this relates to an air conditioning system for a vehicle, comprising a cold accumulator, a device for charging the cold accumulator and a control unit for influencing the operating states of the air conditioning system, wherein an ambient temperature sensor is provided, which signals the ambient temperature characterizing signals to the control unit provides, wherein an internal temperature sensor is provided which provides the control unit, the vehicle interior temperature characterizing signals, and wherein the control unit so - -

is designed so that a discharge of the memory for cooling purposes is supported by an introduction of outside air into the interior when the outside temperature is lower than the internal temperature. The first step towards reducing the temperature in the vehicle interior can often be achieved by replacing the air in the interior with outside air. Only when the interior temperature is only a few degrees higher than the outside temperature, a further air exchange is no longer sufficient, so that then the cooling can be used useful by unloading the cold storage. This cooling then starts from a lower temperature level, so that ultimately the cold charged in the reservoir can provide a lower temperature value in the interior or leads to the desired interior temperature in a shorter time. It is also conceivable that the introduction of outside air into the interior is not carried out prior to the start-up of the storage cooling but simultaneously with this, since this too can favor the initial rapid lowering of temperature.

In particular, it is useful that the control unit is designed such that discharge of the accumulator for cooling purposes is assisted by an introduction of outside air into the interior when the outside temperature is lower than the inside temperature by a minimum amount. The introduction of outside air into the interior is all the more effective, the greater the difference between the interior temperature and the outside temperature. Consequently, it may be useful to make the air exchange only from a certain temperature difference, while waiving lower temperature differences on the initiation of measures for air exchange. _

Usefully it can be provided that the introduction of outside air into the interior takes place before the discharge of the storage. This allows the already mentioned advantageous pre-cooling.

The invention is advantageously further developed in that the introduction of outside air into the interior takes place by commissioning a blower.

It is also possible that the introduction of outside air into the interior takes place by opening a window and / or a sliding roof.

According to the second aspect of the invention, it further consists in a method for controlling an air conditioning system for a vehicle, comprising a cold accumulator, a device for charging the cold accumulator and a control unit for influencing the operating states of the air conditioning system, wherein an ambient temperature is detected and the control unit, the ambient temperature characterizing signals are detected, wherein a vehicle interior temperature is detected and the control unit, the vehicle interior temperature characterizing signals are supplied, and a discharge of the memory for cooling purposes by an introduction of outside air into the interior is then supported when the outside temperature is lower than that Internal temperature is. In this way, the advantages and peculiarities of the air conditioning system according to the second aspect of the invention are also realized in the context of a method. This also applies to the following particularly preferred embodiments of the method according to the invention. - o -

This can be developed in such a way that a discharge of the memory for cooling purposes by an introduction of outside air into the interior is then supported when the outside temperature is lower than the internal temperature by a minimum amount.

Furthermore, it can be provided that the introduction of outside air takes place in the interior before the discharge of the memory.

For example, the inventive method may be designed so that the introduction of outside air into the interior takes place by commissioning a blower.

According to a third aspect of the invention, this consists in an air conditioning system for a vehicle, with a

Refrigeration circuit having a compressor, wherein parallel to the compressor, a controllable valve is connected, which can be controlled for the purpose of pressure equalization between the input side and the output side of the compressor in the open state. In this way, the start-up of the compressor is facilitated because it no longer has to work against the high pressure differences that exist otherwise before and during the start-up phase between the output side and input side of the compressor.

For example, it can be provided that the valve is a solenoid valve. - -

The invention is particularly useful in the context that the compressor is an electrically driven compressor. While mechanical compressors driven by the internal combustion engine are less problematic in terms of starting pressure difference, in the case of electrically driven compressors, the power peaks required for startup may become a problem. In this respect, the invention can be used particularly in connection with these electrically driven compressors in a particularly advantageous manner.

This aspect of the invention is further useful in the context that the refrigeration circuit has, in addition to the compressor, a condenser and an evaporator, wherein heat can be withdrawn by the evaporator from a cold storage. In such air conditioning systems, an electric compressor is often used to charge a cold storage, the air conditioning system is provided as a self-contained air conditioning system, that is, in addition to a conventional primary refrigerant circuit.

With regard to the operation of the air conditioning systems according to the invention may also be useful that a carbon dioxide sensor is provided in the interior of the vehicle, the output signals of a control unit are supplied, and that the control unit is designed so that depending on the detected carbon dioxide content fresh air operation, recirculation mode and mixed forms of these modes are selectable. The carbon dioxide content in the breathing air in the interior of the vehicle is a useful criterion for the need for air exchange. As air conditioning is often selected for stand air conditioning in order to be able to work as efficiently as possible in this way, carbon dioxide detection provides a safety concept available, can be switched over with the increased carbon dioxide concentration on fresh air mode or a mixed form of recirculation and fresh air mode.

The invention will now be described by way of example with reference to the accompanying drawings by way of particularly preferred embodiments.

Brief description of the drawings

Show it:

Figure 1 is a schematic representation for explaining an air conditioning system according to the first and the second aspect of the invention;

FIG. 2 is a flowchart for explaining a method according to the first aspect of the invention;

FIG. 3 is a flowchart for explaining a method according to the second aspect of the invention;

Figure 4 is a schematic illustration for explaining an air conditioning system according to the third aspect of the invention.

Description of preferred embodiments

In the following description of the drawings, like reference characters designate like or similar components. Figure 1 shows a schematic representation for explaining an air conditioning system according to the first and the second aspect of the invention. The air-conditioning system 10 comprises a refrigeration circuit 12. The refrigeration circuit 12 includes a compressor 14 driven by an engine, not shown, a condenser 16, a dryer / collector 32, an expansion valve 34, an evaporator 18, and a check valve 36 arranged in the order mentioned in the flow direction of the refrigerant. Parallel to the expansion valve 34 and the evaporator 18, a further expansion valve 38 and a further evaporator 20 may be arranged. The provision of an additional parallel arranged evaporator 20 with vorlagertem expansion valve 38 is optional, and it can be used, for example, useful in the event that the refrigeration circuit 12 is to be optimally used for cooling various areas of the vehicle interior, for example, for cooling a cab and a sleeping cabin arranged behind it. In this case, the evaporators acting as a heat exchanger 18, 20 can be arranged in an optimized manner, where the cold is needed. Solenoid valves 66, 68 are furthermore provided in the parallel paths equipped with the evaporators 18, 20, so that the evaporators 18, 20 can be integrated jointly or optionally. Next to the evaporators 18, 20 with upstream expansion valves 34, 38, an additional evaporator 40 is provided with upstream expansion valve 42. This evaporator 40 is arranged within a cold accumulator 22 so that the cold accumulator 22 can be charged by the evaporator 40. In order to connect the evaporator 40 and the upstream expansion valve 42 optionally in the refrigerant circuit 12 and thus to cause a charging of the cold accumulator 22 is a Solenoid valve 44 is provided. The cold storage 22 is further connected to a coolant circuit 24, can be removed via the cold from the cold storage 22. The coolant circuit 24 includes a heat exchanger 46, a surge tank 48 with level sensor, a pump 50 and a arranged in the cold storage 22 heat exchanger 62, wherein the coolant circuit 24 associated components are arranged in the flow direction of the coolant in that order. The refrigerant circuit 12 is furthermore equipped with a temperature sensor 52 arranged downstream of the evaporator 40 arranged in the cold storage 22. Furthermore, the coolant circuit is equipped with temperature sensors 54, 56 arranged on the input side and output side with respect to the heat exchanger 62 arranged in the cold accumulator 22, and a mass flow sensor 58 in the flow direction behind the pump 50. The aforementioned temperature sensors 52, 54, 56 and the mass flow sensor 58 are used to determine the state of charge in the cold storage 22, wherein the temperature sensor 52 in the refrigerant circuit 12, in particular in combination with the

Mass flow sensor 58 and the pump power 50 is used to determine the state of charge, while the temperature sensors 54, 56 in the coolant circuit 24 by comparing the coolant inlet temperature and Kühlmittelausgangstem- temperature and by using stored maps allow a determination of the state of charge of the cold accumulator 22. For detecting and influencing the operation of the air conditioning system 10, a control unit 26 is provided. This control unit 26 receives signals from the temperature sensors 52, 54, 56, the mass flow sensor 58, a

Speed sensor 28, which determines the speed of the motor vehicle engine, a speed sensor 30, a temperature sensor 60 for determining the ambient temperature, a temperature sensor 70 for determining the vehicle interior temperature and a carbon dioxide sensor 74. Furthermore, the control unit 26 is assigned a main switch 64.

The air conditioning system 10 of the invention operates as follows. In the conventional air conditioning of the vehicle interior of the refrigerant circuit 12 is in a known manner in operation. The evaporators 18, 20 can be activated selectively or jointly. The air to be supplied to the interior is supplied to the evaporators 18, 20 by means of unillustrated blowers. In this first operating state of the air conditioning system 10, the interior of the motor vehicle is thus cooled via the evaporators 18, 20 or optionally by one of these evaporators 18, 20. The cold storage tank 22 is discharged by activation of the coolant circuit 24 by the pump 50 being switched on by the control unit 26. Consequently, refrigerant flows through the heat exchanger 62, it can give off heat there and then supplied to the heat exchanger 46 in the cooled state. There, the cooled coolant is supplied with an air flow, which can subsequently be supplied to the interior. After flowing out of the heat exchanger 46 and flowing through the surge tank 58, the coolant is fed back to the pump 50. The discharging of the cold accumulator 22 thus represents, with regard to the cooling of the vehicle interior, a second operating state, which is conventionally used for stationary air conditioning.

If, owing to the values transmitted by the sensors 28, 30, it is determined by the control unit 26 that the engine speed exceeds a predetermined value, so that there is typically a high load condition of the vehicle engine, the control unit 26 causes the control unit 26 to operate when the vehicle engine is running Cooling circuit 12 is deactivated while the coolant circuit 24 is activated. _

In this way, the vehicle engine is relieved in an advantageous manner.

The temperature sensors 60, 70, that is the outside temperature sensor 60 and the interior temperature sensor 70, are of particular importance. Since charging the cold accumulator 22 is undesirable when there is a relatively low outside temperature, it is possible for the controller 26 to suppress a charge even if it is requested for other reason at low outside temperature. On the other hand, when an outside temperature threshold or a rapid increase in the outside temperature is exceeded, the charging process can be initiated, even if this was not intended per se. For example, the desire expressed by the driver via input means that no charging of the cold accumulator 22 should take place can be ignored due to high temperatures or rapid temperature increases.

Further, the outside temperature sensor 60 and the interior temperature sensor 70 influence the manner in which a heated vehicle is pre-cooled by means of cold accumulation discharge. If the outside temperature sensor 60 indicates a lower value than the inside temperature sensor 70, fresh air is supplied from the outside to pre-cool the interior. At the same time or only later, the unloading process is started for the purpose of cooling. The fresh air can be supplied via the not shown control of a blower, the sunroof motor and / or a Fenstermo- Torik, this control directly by the

Control unit 26 or indirectly via the vehicle data bus, which is then usefully connected to the control unit 26, takes place. - -

A further special role is played by the carbon dioxide sensor 74 arranged in the interior of the motor vehicle. If this determines a carbon dioxide content above a predetermined threshold, then recirculation mode switches over to mixed air or fresh air operation so as to avoid a depletion of oxygen in the interior space.

FIG. 2 shows a flow chart for explaining a method according to the first aspect of the invention; Two control sequences are shown, which can run parallel to the constant monitoring. After initiation of the control sequences, according to a first control sequence, if loading of the memory is requested in step SO1, it is checked in step S02 whether the outside temperature is below an outside temperature threshold value. If this is the case, the memory is not loaded despite requesting the storage charge according to step S03. Otherwise, the memory is loaded according to step S04. According to the other control sequence, if no charging of the accumulator according to step S05 is to take place per se, for example due to the driver's request, it is checked in step SO6 whether the outside temperature is above an outside temperature threshold or if the temporal rate of change of the outside temperature is greater than a predetermined change. rate of change threshold. If one of these conditions is satisfied, the memory is loaded in step S07. Otherwise, the memory will not be loaded as originally scheduled in step 08. In the context of the control sequences described here, it should be noted that an intervention option should always be available. If, for example, a charging process is initiated against the driver's request, then this is preferably communicated to the driver via a display, so that he can in turn suppress the automatically initiated charging process. - Xo -

The same applies in the reverse case, if the driver actually wanted to load the memory, but due to low outdoor temperature charging was prevented. Even then, the driver should be able to enforce his original wish.

FIG. 3 shows a flowchart for explaining a method according to the second aspect of the invention. After initiation of the process for pre-cooling the interior before the vehicle is put into operation, it is checked in step S11 whether the outside temperature is lower than the inside temperature. If this is the case, the interior air is supplied to the interior in step S02. At the same time or after a delay, according to step S03, the accumulator is discharged so as to bring about interior cooling. If it is determined in step S11 that the outside temperature is not lower than the inside temperature, then the storage cooling is immediately proceeded to in step S03.

FIG. 4 shows a schematic illustration for explaining an air conditioning system according to the third aspect of the invention. The air conditioning system 10 shown here includes a refrigeration circuit 112 equipped with an electrically driven compressor 114. The cooling circuit 112 is used exclusively for charging the cold accumulator 122 via the evaporator 140 arranged in the cold accumulator 122. The electric compressor 114 is bridged by a solenoid valve 172 which can be controlled electrically by means of the control 26. As a result, before commissioning or at the same time as commissioning of the compressor 114

Pressure equalization between the input side and the output side of the compressor 114, whereby the start-up of the compressor 114 is facilitated and power peaks are avoided. The other components of the in Figure 4 illustrated air conditioning system 10 are the same or comparable to the explained with reference to Figure 1 components.

The features of the invention disclosed in the foregoing description, in the drawings and in the claims may be essential to the realization of the invention both individually and in any combination.

LIST OF REFERENCE NUMBERS

10 air conditioning system

12 refrigerant circuit 14 compressor

16 capacitor

18 evaporators

20 evaporators

22 cold storage 24 coolant circuit

26 control unit

28 speed sensor

30 speed sensor

32 Dryer / Collector Device 34 Expansion Valve

36 check valve

38 expansion valve 40 evaporator

42 expansion valve 44 solenoid valve

46 heat exchanger

48 expansion tank

50 pump

52 temperature sensor temperature sensor

temperature sensor

Mass flow sensor

temperature sensor

heat exchangers

main switch

magnetic valve

Magnetventi1

temperature sensor

carbon dioxide sensor

cooling circuit

compressor

Evaporator

Magnetventi1

Claims

_CLAIMS

An air conditioning system (10) for a vehicle, comprising a cold accumulator (22), a device (12) for charging the cold accumulator and a control unit (26) for influencing the operating states of the air conditioning system, characterized in that an ambient temperature sensor (60) is provided in that the control unit (26) supplies signals characterizing the ambient temperature, and in that the control unit is designed such that a charging process of the cold accumulator (22) can be initiated or suppressed as a function of the ambient temperature.

2. Air conditioning system (10) according to claim 1, characterized in that a charging of the cold accumulator (22) can be suppressed when the outside temperature falls below a predetermined temperature threshold.

3. Air conditioning system (10) according to claim 1 or 2, characterized in that a charging of the cold accumulator (22) is automatically initiated when the outside temperature exceeds a predetermined temperature threshold and / or a predetermined temperature gradient.

4. A method for controlling an air conditioning system (10) for a vehicle, with a cold storage (22), a device (12) for loading the cold storage and a control unit (26) for influencing the operating conditions of the air conditioning system, characterized in that detects an ambient temperature is supplied to the control unit (26) the ambient temperature characterizing signals, and that a charging operation of the cold accumulator _

is initiated or suppressed depending on the ambient temperature.

5. The method according to claim 4, characterized in that a charging of the cold accumulator (22) is suppressed when the outside temperature falls below a predetermined temperature threshold.

6. The method of claim 4 or 5, characterized marked, that a charging of the cold accumulator (22) is automatically initiated when the outside temperature exceeds a predetermined temperature threshold and / or a predetermined temperature gradient.

7. A climate control system (10) for a vehicle, in particular according to one of the preceding claims 1 to 3, with a cold storage (22), means (12) for charging the cold storage and a control unit (26) for influencing the operating conditions of the air conditioning system, characterized in

in that an ambient temperature sensor (60) is provided which supplies the control unit (26) with signals characterizing the ambient temperature,

that an internal temperature sensor (70) is provided, which provides the control unit, the vehicle interior temperature characterizing signals, and

- That the control device is designed so that a discharge of the memory (22) is supported for cooling purposes by introducing outside air into the interior when the outside temperature is lower than the internal temperature.

8. Air conditioning system (10) according to claim 7, characterized in that the control device (26) is designed so that a discharge of the memory (22) is supported for cooling purposes by introducing outside air into the interior when the outside temperature to a Minimum amount is lower than the indoor temperature.

9. Air conditioning system (10) according to claim 7 or 8, character- ized in that the introduction of outside air into the interior takes place before the discharge of the memory (22).

10. Air conditioning system (10) according to any one of claims 7 to 9, characterized in that the introduction of outside air takes place in the interior by commissioning a fan.

11. Air conditioning system (10) according to one of claims 7 to 10, characterized in that the introduction of outside air into the interior takes place by opening a window and / or a sliding roof.

12. A method for controlling an air conditioning system (10) for a vehicle, in particular according to one of claims 3 to 6, with a cold storage (22), a device (12) for charging the cold accumulator and a control unit (26) for influencing the operating conditions of Air conditioning system, characterized

detecting an ambient temperature and providing to the control unit (26) signals characterizing ambient temperature, - -

that an in-vehicle temperature is detected and the control unit is provided with the vehicle interior temperature characterizing signals, and

- That a discharge of the memory for cooling purposes by an introduction of outside air into the interior is then supported when the outside temperature is lower than the internal temperature.

13. The method according to claim 12, characterized in that a discharge of the memory (22) is supported for cooling purposes by introducing outside air into the interior, when the outside temperature is lower than the internal temperature by a minimum amount.

14. The method according to claim 12 or 13, characterized in that the introduction of outside air into the interior takes place before the discharge of the memory (22).

15. The method according to any one of claims 12 to 14, characterized in that the introduction of outside air takes place in the interior by commissioning a blower.

16. The method according to any one of claims 12 to 15, characterized in that the introduction of outside air in the

Interior is done by opening a window and / or a sunroof.

17. An air conditioning system (10) for a vehicle, in particular according to one of claims 1 to 3 or 7 to 11, with a refrigeration circuit (112) having a compressor (114), characterized in that parallel to the compressor (114 ) a controllable valve (172) is connected, which is for the purpose of pressure equalization between the input side and the output side of the compressor can be controlled in the open state.

18. Air conditioning system (10) according to claim 17, characterized in / that the valve is a solenoid valve (172).

19. Air conditioning system (10) according to claim 17 or 18, characterized in that the compressor (114) is an electrically driven compressor.

20. Air conditioning system (10) according to any one of claims 17 to 19, characterized in that the refrigerant circuit (112) in addition to the compressor (114) has a condenser (16) and an evaporator (140), wherein by the evaporator a Cold storage (122) heat is withdrawn.

21. Air conditioning system (10) according to any one of claims 1 to 3, 7 to 11 or 17 to 20, characterized in that in the interior of the vehicle, a carbon dioxide sensor (74) is provided, the output signals of a control unit (26) can be fed, and that the control unit is designed so that depending on the detected carbon dioxide content fresh air mode, recirculation mode and mixed forms of these modes are selectable.

22. A method for controlling an air conditioning system (10) according to any one of claims 3 to 6 or 12 to 16, characterized in that in the interior of the vehicle, the carbon dioxide content is detected and selected depending on the detected carbon dioxide fresh air mode, recirculation mode or mixed forms of these modes become.