DE19927879C2 - Process for the air conditioning of vehicles and adsorption refrigeration system for carrying out the process - Google Patents

Description

The present invention relates to a method for air conditioning vehicles with a Adsorption refrigeration system and an adsorption refrigeration plant for carrying out the process.

For the air conditioning of vehicles so far mainly compression refrigeration machines used. Lately, too, is the technical Use of sorption processes for heating or cooling Generation for the air conditioning of motor vehicles been proposed.

DE 41 26 960 A1 describes an adsorption refrigeration system for generating heat or cold in Motor vehicles. This system turns to cold generating a liquid in a first working phase Refrigerant evaporates, is fed to a sorbent and there adsorbed. In a second phase of work, this will be Sorbent heated to desorbed the refrigerant beers. The gaseous desorbed refrigerant finally liquefies and stands again for the Use available in the first phase of work. The to evaporate the refrigerant in the first work energy required is a liquid or withdrawn gaseous medium, which cools down as a result. The adsorption refrigeration system of this publication works with water as the refrigerant and with zeolite as the sorbent.  

Requires the use of water as a refrigerant changes due to the low vapor pressure of Water has an extremely low evaporator pressure. The individual units of the presented adsorption refrigeration system must therefore be extremely vacuum-proof, so that the manufacturing cost of such a system increase. Furthermore, it has the disadvantage that the water vapor circulating in the refrigeration system low pressure a very large specific volume having. The resulting large volume flows inside the facility require a generous size sioning of the units and pipe used links. This leads to an increased weight also at higher manufacturing costs.

Another disadvantage of that in the publication proposed facility is that in this Case to generate the required high Desorption or regeneration temperatures one additional electrical heating device used must become. The desorption temperature is at combination of water as refrigerant and Zeolite as a sorbent so high that only heat potentials with a temperature level above 250 ° C can be used to carry out the desorption can.

DE 43 34 808 C1 is an improvement on Such adsorption refrigeration system proposed. Here, the sorbent is not in the adsorption phase as in the above DE 41 26 960 A1 directly electrically heated but with hot air flowing through it, so that the heat transfer into the sorbent is significantly improved and so the desorption is accelerated strongly. The  semi-open refrigerants also proposed Circulation leads to less effort in terms of maintaining a vacuum, however, pulls inevitably a loss of refrigerant. This is with a comfort disadvantage for the operator connected to the facility, as this occurs in regular Refrigerant intervals must be refilled.

Furthermore, it is expected that the heating of the sorbent used outside air over time Pores of the sorbent clog, so that the sorption capacity and thus the cooling capacity of such Plant can be negatively influenced in the long run.

This plant also uses zeolite as a sorbent and water or brine are used as refrigerants. It is therefore, just like in DE 41 26 960 A1, a electric heating device - here for heating the blown air - necessary to the for the Desorption required temperatures to reach. Alternatively, it is proposed in this publication that the air introduced for desorption with an external current-carrying waste heat source of very high temperature, a high temperature used in electric vehicles raturbatterie, to heat.

In the first variant of electrical heating however, the efficiency of the Vehicle because it also generates electrical energy must become. The second variant has the disadvantage that a corresponding high temperature for their realization raturbatterie must be present in the vehicle.

Use of other driving heat potentials Stuff for the provision of desorption required high temperatures, such as  the exhaust gas heat, comes because of this complex constructional measures not in Question. Other heat sources, such as that Cooling water of the vehicle, in turn, do not reach that necessary for the regeneration of the loaded zeolite high temperatures.

DE 36 38 706 A1 describes a device for continuous generation of heat and cold by means of of a sorption system. This becomes a two-stage Process with a cascade of two in a row arranged reactors used as refrigerants / Sorbent pairs of zeolite / water and activated carbon / methanol contain. Due to the two-stage structure and the the associated space requirement is such a system not for the air conditioning of motor vehicles suitable. Also those specified for desorption Temperature levels of around 300 ° C or 120 ° -170 ° C are not reached by the cooling water of a vehicle.

The object of the present invention is therein, based on the generic State of the art a method and an adsorption refrigeration system ready for air conditioning of vehicles deliver that without complex construction measures use of heat sources in the vehicle Desorption enables. In particular, the facility should without additional electrical heating with the cooling water of the Vehicle engine can be operated.

The task is with the procedure and the Adsorption refrigeration system according to claims 1 and  5 solved. Advantageous configurations of the system and the procedure are the subject of the subclaims.

It was recognized that a suitable Choice of the refrigerant / sorbent material pair for the Desorption or regeneration of the sorbent required Temperature can be reduced so that waste heat of the vehicle engine on a significantly lower Temperature level than this the state of the art Technique require regeneration of the loaded Sorbent can be used. Through this extended Waste heat can be used as a whole Efficiency of the vehicle improved. So with that inventive method or the associated  Adsorption refrigeration system in the cooling water of a vehicle Waste heat contained without expensive constructive Measures for the desorption process can be used. The pair of substances methanol / Activated carbon enables the direct integration of the Cooling water circuit in the regeneration heat circuit run of the sorption units. The hot cooling water can in addition from the motor by simple insulated pipe connection doses in the loaded sorption units become.

The activated carbon sorbent is preferably in the form a very fine-grained fill through metal grids or metal gauze directly on the heat exchange surface fixed within the sorption units. hereby an optimal heat transfer of cooling water heat in reached the sorbent.

The inventive method and the Invention appropriate adsorption refrigeration system advantageously allow the use of heat potential in the Motor vehicle, so far because of its lower Temperature levels could not be taken into account. By using the waste heat of the cooling water improve the overall efficiency of the vehicle. Furthermore, the system can have a very long service life guarantee with constant cooling capacity.

By using methanol instead of water as a refrigerant, refrigeration is below 0 ° C possible. Water would freeze at these temperatures and add the adsorption refrigeration system.

By using methanol as a refrigerant there is also the advantage of an im Compared to water of higher vapor pressure, so that a  higher evaporator pressure is permitted. this leads to both to lower requirements in terms of Tightness of the system as well as for the benefit of smaller size compared to the known sorption refrigeration systems with the material pair water / zeolite. The decreasing material requirements for the aggregates Adsorption refrigeration system with the refrigerant methanol also has a positive effect on dynamic behavior and thus on the performance of the system. Through the Possibility of cold at a temperature level below Providing 0 ° C will increase the efficiency of the Vehicle air conditioning system improved again.

The inventive method and the Invention appropriate system are subsequently based on an off example in connection with the drawings explained again in more detail. Here show:

Fig. 1 equilibrium isotherms for the pair of activated carbon (AK1700) / methanol compared to corresponding data from the literature for zeolite / water; and

Fig. 2 shows schematically an example of an embodiment of the adsorption refrigeration system according to the invention and its integration into the cooling water system of a motor vehicle.

In Fig. 1, the benefit of using activated carbon as the sorbent and methanol can be clearly seen as a refrigerant in comparison with the pair of substances zeolite / water in an adsorption refrigeration. The data were obtained by using the different working fluid pairs in the calculation of an adsorptive refrigeration model process. It can be seen from the figure that with regard to the use in adsorptive refrigeration processes, the investigated working material pair of highly activated activated carbon (AK1700) / methanol has a significantly higher quality grade compared to the material pair zeolite / H ₂ O, especially at low drive temperatures. For example, the maximum COP (coefficient of performance) for the activated carbon / methanol substance pair used according to the invention is already reached at a desorption temperature between 80 and 90 ° C., while the COP for the zeolite / H ₂ O material pair used in the prior art even at a desorption temperature of 120 ° C is still significantly below that of activated carbon / methanol.

In FIG. 2, the integration of an adsorption cooling according to the invention in the cooling water circuit of a vehicle engine schematically. The figure shows the various heat transfer circuits using an example of the system according to the invention, in which two storage containers containing the sorbent activated carbon are provided.

The adsorption refrigeration system 1 has two sorption units with the storage containers 2 and 3 . The storage containers each contain the sorbent 4 or 5 formed from a solid (activated carbon). In the adsorption refrigeration system are also a reservoir 6 with liquid sorbate (methanol), a condenser 7 , an evaporator 8 and a line system consisting of the steam channels 9 to 13 , the vapor barriers 14 to 17 and an expansion valve 18 . The expansion valve 18 fluidly connects the condenser 7 to the evaporator 8 via the reservoir 6 . The evaporator 8 is connected via a heat exchanger, not shown, to the vehicle interior 48 , from which it removes the heat required for the evaporation of the refrigerant (methanol) during operation for air conditioning.

In the storage tanks 2 and 3 , heat exchangers 19 and 20 are provided in addition to the sorbent, which serve on the one hand to supply the heat required for the desorption and on the other hand to dissipate the heat generated during the adsorption. The porous sorbent 4 or 5 consists of a loose, fine-grained bed of activated carbon 29 , which is held by means of a metal gauze 30 on the heat exchange surfaces 31 of the heat exchangers 19 and 20 . This can be seen in sub-picture A.

Heat exchange surfaces, preferably as plates or tubular heat exchange surfaces, are provided in almost the entire inner volume of the sorption units or storage containers 2 , 3 and are supplied with heating water for desorption or cooling water for adsorption by means of tubes 21 to 24 . These pipes are integrated in two pipe systems, which form the heat exchange circuits and can be coupled in separately via valves 25 to 28 .

Between the individual tubes or plates of the heat exchange surfaces coated with activated carbon there is a vapor space 32 (see partial image A) through which the desorbed sorbate vapor reaches the connecting channels 9 to 12 . These connecting channels connect the interior of the storage containers 2 and 3 to the condenser 7 and the evaporator 8, respectively. They serve to transport the sorbate vapor during the desorption process from the storage container into the condenser 7 or during the adsorption process from the evaporator 8 into the storage container. In the connecting channels, vapor barriers 14 to 17 are arranged, by means of which the sorption units can be fluidically separated from the evaporator or the condenser, so that the sorbent 4 or 5 can be reactively isolated from the sorbate 33 .

The reservoir 6 contains the liquid sorbate 33 , which is supplied to it after liquefaction in the condenser 7 through the pipe section 13 a. From the reservoir, the liquid sorbate passes through the connection 13 b to the expansion valve 18 through which the liquefied sorbate can be relaxed via the connection line 13 b to the pressure level for the evaporation in the evaporator 8 .

When operating this vehicle air conditioning system, the two sorption units 2 and 3 are alternately operated in adsorption or desorption. To charge a sorption unit, cooling water is conveyed by the additional cooler 46, which is additionally provided in the engine compartment in addition to the engine cooler, through the heat exchanger of the respective sorption unit in order to dissipate the heat of adsorption generated there. When a sorption unit is discharged, hot water is led from the vehicle engine 45 via the pipes 38 and 22 (or 37 and 24) through the heat exchanger of the respective sorption unit in order to provide the heat required for desorption. The emerging from the sorption unit, cooled water is fed through the pipes 21 and 36 (or 23 and 35) to the engine cooler 34 , where the cooling water the residual heat necessary for cooling the engine is removed. The cold water then enters the motor 45 via line 47 . The individual on the connections to the coolant circuit of the vehicle engine provided valves 25 to 28 are controlled such that the corresponding heat flows to the respective sorption units. Here, one of the two sorption units is operated at the same time in a desorption phase and the other in an adsorption phase. In this way, it is possible to maintain a continuous operation of the air conditioning system by periodically actuating the valves 26 to 28 . A pause in the operation of the evaporator for the period of desorption is not necessary.

For example, during a phase of the air conditioning process, the heating circuit in sorption unit 2 is closed by valves 25 and 26 . As a result, hot cooling water from the vehicle engine 45 passes via the lines 38 and 22 directly into the heat exchanger 19 of the sorption unit 2 , as a result of which the sorbent is heated. This enables the desorption of sorbate bound to sorbent 4 . In this case, the temperature of the cooling water is sufficient for the desorption process, since the material mixture activated carbon / methanol enables sufficient desorption even at temperatures of 80 ° C.

The adsorption of sorbate in the sorption unit 3 releases heat of adsorption, which is dissipated via the heat exchanger 20 . To remove the heat, the heat exchanger 20 arranged in the sorbent 5 is fluidly coupled to the additional cooler 46 and cooled by switching the control valves 27 and 28 via the lines 23 , 24 , 39 and 41 . The additional cooler is located at the front of the vehicle and is cooled by ambient air.

In this phase of the operation of the air conditioning system, the sorbent desorbed from the sorption unit 2 passes via the steam lines 9 a, 9 b and the opened vapor barrier 14 into the condenser 7 , where it is liquefied. The heat of liquefaction is absorbed by a heat transfer fluid, which is also connected to the additional cooler 46 via the pipes 43 and 44 .

The condensate finally cools down in the storage container 6 to ambient temperature, is supplied via the expansion valve 18 to the evaporator 8 for evaporation and refrigeration and from there to the sorption unit 3 which is in the discharged or partially discharged state.

The enthalpy of vaporization required in the evaporator 8 for evaporation is taken from the vehicle interior 48 , which is cooled thereby.

The vapor barriers 15 and 16 are closed in this phase, so that on the one hand no liquid sorbate flows into the adsorbing sorption unit 3 and on the other hand no vaporous sorbent from the evaporator is absorbed into the sorption unit 2 .

After completion of the desorption phase in sorption unit 2 or the adsorption phase in sorption unit 3 , the valves 25 to 28 and 14 to 17 are switched so that the discharge phase in sorption unit 3 and the loading phase in sorption unit 2 can be started.

In this case, the vapor barriers 14 and 17 are closed, while the vapor barriers 15 and 16 are opened. Hot cooling water from the vehicle engine 45 , which provides the heat required for the desorption in the heat exchanger 20 , is now fed to the sorption unit 3 via the lines 37 and 24 . The cooling water is fed via lines 23 and 35 into the engine cooler 34 and from there back into the vehicle engine. In the case of the sorption unit 2 , the heat exchanger 19 is supplied via the lines 40 and 22 cooling water from the additional cooler 46 , which is recirculated via lines 21 and 42 into the additional cooler after absorption of the heat of adsorption.

In this phase too, sorbate desorbed by the sorption unit 3 is liquefied in the condenser 7 and, in turn, supplied to the evaporator for evaporation and refrigeration via the storage container 6 . The periodic repetition of adsorption and desorption in the sorption units 2 and 3 enables continuous refrigeration to be achieved.

By regulating the delivery rate with the expansion valve 18 in conjunction with regulating the heat extraction from the adsorbing sorbent 4 or 5 , the adsorption rate of sorbate vapor and thereby the heating or cooling output can be controlled very sensitively.

This plant, which is called activated carbon sorbent and Refrigerant contains methanol, can therefore without additional electrical heating in a motor vehicle  be used. By using the im Motor vehicle already existing cooling water circuit systems can be advantageously the total improve vehicle efficiency. The integration such an air conditioning system in force vehicle does not require complex design Activities.

Claims (9)

1. Method for air conditioning vehicles with an adsorption refrigeration system,
in which liquid refrigerant is evaporated in order to extract the required heat from a liquid or gaseous medium for cooling,
the evaporated refrigerant is fed to a sorbent for adsorption,
the sorbent loaded with the refrigerant is heated to desorb the refrigerant,
and the refrigerant is then liquefied to be available for re-evaporation,
characterized by
that methanol is used as the refrigerant and activated carbon as the sorbent. 2. The method according to claim 1, characterized, that the heat required for desorption Waste heat from the vehicle engine is obtained. 3. The method according to claim 2, characterized, that the heat required for desorption Cooling water circuit of the vehicle is removed.   4. The method according to any one of claims 1 to 3, characterized, that the heat given off during adsorption Engine compartment of the vehicle, air-cooled additional cooler is supplied. 5. Adsorption refrigeration system for air conditioning vehicles
at least one sorption unit ( 2 , 3 ) with a sorbent ( 4 , 5 ),
a storage container ( 6 ) with a refrigerant ( 33 ) connected to it via a lockable line system ( 9-13 ),
a condenser ( 7 ) and an evaporator ( 8 ) for the refrigerant,
a first heat exchanger ( 19 , 20 ) in the sorption unit ( 2 , 3 ) and
a second heat exchanger on the evaporator ( 8 )
characterized,
that the sorption unit ( 2 , 3 ) contain activated carbon as sorbent ( 4 , 5 ) and the storage container ( 6 ) methanol as refrigerant ( 33 ). 6. Adsorption refrigeration system according to claim 5, characterized in that the sorbent ( 4 , 5 ) is present as a fine-grained bed in the sorption unit ( 2 , 3 ) and by metal gauze ( 30 ) directly on a surface ( 31 ) of the first heat exchanger ( 19 , 20th ) is fixed. 7. Adsorption refrigeration system according to claim 5 or 6, characterized in that two of the sorption units ( 2 , 3 ) are provided which are connected via switchable shut-off devices ( 14-17 ) in such a way to the line system ( 9-13 ) that one at the same time Unit ( 2 , 3 ) can go through a desorption phase and the other unit ( 3 , 2 ) through an adsorption phase. 8. Adsorption refrigeration system according to one of claims 5 to 7, characterized in that the first heat exchanger ( 19 , 20 ) has connections to the cooling water circuit ( 35-42 , 47 ) of the motor vehicle. 9. Adsorption refrigeration system according to one of claims 5 to 8, characterized in that an air-cooled additional cooler ( 46 ) is provided, to which the heat released during adsorption is dissipated.