EP1753632A1 - Air-conditioning installation - Google Patents

Abstract

The invention relates to an air-conditioning installation (10) for a motor vehicle comprising an internal combustion engine (12), said installation essentially comprising a heating heat exchanger (38), an evaporator (40), and an exhaust gas heat exchanger (22, 78) in a coolant circuit (26). During the heating operation, the coolant heated in the exhaust gas heat exchanger (22,78) is guided over the heating heat exchanger (38), and during the cooling operation, it is guided over an expansion device (46) and an evaporator (40) once it has been cooled in an environment heat exchanger (44). According to the invention, the coolant is low-boiling, and once it has passed through the exhaust gas heat exchanger (22, 78), it is supplied as a motive agent to at least one device (30, 42) for transporting the coolant.

Description

air conditioning

State of the art

The invention is based on an air conditioning system according to the preamble of claim 1.

In increasingly common air conditioning systems in vehicles that are driven by an internal combustion engine, compression refrigeration systems with an electric drive or mechanical drive by the internal combustion engine are used to generate cold. The main refrigerants used are hydrocarbons, eg Rl34a, with the heat being transferred to the vehicle interior air via a liquid-air heat exchanger, also called an evaporator. A transition to alternative coolants, such as carbon dioxide (C0 ₂ , R744), is foreseeable due to the poor environmental compatibility of the hydrocarbons currently used. A draft law from the European Union on the use of refrigerants with a Global Warming Potential (GWP) less than 150 has already been published. The C0 discussed as an alternative to hydrocarbons leads to much more complex and complicated mobile air conditioning systems due to the high pressures required. Flammable refrigerants like the R152a are not preferred for safety reasons and due to their low but still existing GWP.

EP 0 945 291 A1 discloses a device and a method for heating and cooling a useful space of a motor vehicle. The refrigerant is compressed by a compressor in heating mode and passes through a 3/2-way valve to an evaporator, in which it contains part of the sion emits heat to the colder vehicle interior air. The refrigerant flows from the evaporator to an expansion device, in which it is cooled to such an extent that it can absorb heat from the ambient air in a gas cooler arranged downstream. Further heat is supplied to the refrigerant in a downstream exhaust gas heat exchanger, which is subjected to hot exhaust gases from the internal combustion engine. The refrigerant returns to the compressor from the exhaust gas heat exchanger, which closes the refrigerant circuit.

During the cooling operation, the refrigerant flows into the ambient heat exchanger after compression and is subjected to cool ambient air there. The refrigerant then flows through the expansion device, is expanded there and, in the following indoor heat exchanger, is subjected to warmer, usable air supplying the usable space. The warmed refrigerant then flows back to the compressor. The compressor is driven by the drive shaft of the internal combustion engine. The useful power of the internal combustion engine is reduced by the compressor power ^. Furthermore, fuel consumption increases.

Advantages of the invention

According to the invention, the refrigerant, preferably an alcohol-water mixture, has a low boiling point and is supplied as a blowing agent after flowing through an exhaust gas heat exchanger to at least one device for conveying the refrigerant. The use of such refrigerants offers the advantage of a low greenhouse effect and zero GWP. In addition, the required system pressures, if appropriately designed, are in the vacuum range or in a pressure range that is clear is lower than with conventional R134a air conditioning systems. This means a significant safety advantage over high-pressure systems, for example with the refrigerant carbon dioxide (R744).

The exhaust gas heat exchanger can be used in a simple thermosiphon version or in a valve-controlled version. In the exhaust gas heat exchanger, the refrigerant absorbs the energy from the exhaust gases required to air-condition the vehicle. A pump, a so-called feed pump, expediently supplies the refrigerant to the exhaust gas heat exchanger. The pump is preferably a rotary piston pump, e.g. a gear pump, vane pump or the like. A motor, which is one of the devices for conveying the refrigerant and can be an electric motor or advantageously a vane motor, drives the pump via a drive shaft. Motor and pump can have an essentially identical outer diameter and can be combined to form a structural unit. The refrigerant serves as a propellant for the vane cell motor and can be taken from the exhaust gas heat exchanger in liquid form or as steam. Since the energy for conveying and compressing the refrigerant is not drawn from the drive shaft of the internal combustion engine in the air conditioning system according to the invention, the performance of the internal combustion engine is not impaired by the air conditioning system.

Another device for conveying the refrigerant is advantageously an injector pump, which in cooling operation is supplied with hot refrigerant vapor or hot refrigerant liquid from the exhaust gas heat exchanger as a blowing agent via a line branch of the refrigerant circuit, and which is supplied via a suction line, an expansion valve and the evaporator. fer draws refrigerant from a reservoir. The motive steam may previously have driven the vane motor. The refrigerant cools the air flowing into the vehicle in the evaporator and is then conveyed into a storage container together with the motive steam by the injector pump.

For the air conditioning, in particular for the cooling of the motor vehicle interior, the previously required compressor for the refrigerant can be dispensed with by using the energy obtained from the combustion chamber with the heat exchanger in the form of evaporated refrigerant as motive steam for a refrigeration system operated according to the injector principle. Compared to an air conditioning compressor, the injector pump is a comparatively inexpensive and robust component. The elimination of the electric or direct from the

Compressor driven by the internal combustion engine avoids the additional fuel consumption resulting for the motor vehicle of conventional compressor air conditioning, which arises as long as no air conditioning is required, because at least the compressor must be driven by the internal combustion engine even when the air conditioning is regulated down.

The refrigerant vapor leaving the exhaust gas heat exchanger can also be used as motive steam for a Veuillemier heat pump or in the expeller of an absorption cooling system.

In heating mode, the refrigerant is passed through a heating heat exchanger and thereby heats the air flowing into the vehicle through the heating heat exchanger. The refrigerant is distributed to the injector pump and the heating heat exchanger by a three-way valve and / or by additional pumps that can be driven together by the motor and combined into a single unit.

According to one embodiment of the invention, two pumps are provided which are driven by the motor and of which the first pump conveys refrigerant from the reservoir to the exhaust gas heat exchanger with a larger delivery volume, while the second pump with a lower delivery volume for the removal of liquid refrigerant from the Exhaust gas heat exchanger is used. This has the advantage that low-boiling components of the refrigerant can be removed from the exhaust gas heat exchanger as steam for driving the vane cell motor, while the higher-boiling components can be supplied to the injector pump in cooling mode as driving steam or driving fluid. The low-boiling components come out of the vane motor into an ambient heat exchanger, condense there and are collected in a separate storage container. Due to their low boiling point, they are particularly suitable as a refrigerant for the cooling operation by using the expansion valve and the

Evaporators are sucked in by the injector pump. In the injector pump, the low-boiling components mix with the higher-boiling components and come together into the storage container, from which the feed pump sucks in the refrigerant again to convey it to the exhaust gas heat exchanger. '

In order to be able to cheaply separate the lower-boiling components from the higher-boiling components in the exhaust gas heat exchanger, according to one embodiment, the latter has an insert which is constructed in the manner of a rectification column for separating two-substance mixtures. It is furthermore expedient that at least one heat exchanger is combined with a storage container, so as to keep the construction volume and construction expenditure low.

5 The exhaust gas heat exchanger can be acted upon by the exhaust gases of the internal combustion engine and / or a combustion chamber. In the first case, it can basically be arranged anywhere in the exhaust line of the internal combustion engine. According to one embodiment of the invention, it becomes in the cylinder head

10 integrated into the internal combustion engine, the thermal energy of the exhaust gas can be taken directly from the exhaust valves of the internal combustion engine, as a result of which the exhaust valves, which are subjected to high thermal loads, are selectively cooled. If the exhaust gas heat exchanger is between the outlet of the combustion chambers

15 internal combustion engine and an exhaust gas turbocharger, so the exhaust gases in the gas stream in front of the turbine of the exhaust gas turbocharger are extracted and the thermally highly stressed drive side of the exhaust gas turbocharger is thermally released.

'&> tet. The exhaust gas heat exchanger can expediently be carried out after a

20 catalyst can be arranged. This prevents the catalyst from reaching its operating temperature too late due to the heat removal.

If the thermal energy of the exhaust gas is not sufficient to operate the air conditioning system, it is advisable to connect a combustion chamber on the exhaust gas side of the exhaust gas heat exchanger, through which additional energy can be supplied, for example, by a burner. Similar to the known auxiliary heaters with combustion chamber, independent air conditioning of the vehicle is also possible, independent of the operation of the internal combustion engine. Furthermore, modern concepts of motor vehicle internal combustion engines with a high degree of efficiency, for example petrol and gasoline, are not required Direct diesel injection, the need for additional heating, which is usually operated electrically.

According to one embodiment of the invention, the exhaust gas heat exchanger is only supplied with exhaust gases or combustion gases from a combustion chamber. The combustion chamber can be operated independently of the internal combustion engine, so that an autonomous air conditioning system is created and can be cooled and / or heated without the internal combustion engine operating. Furthermore, in particular in the case of liquid-cooled internal combustion engines, the motor vehicle heater responds much more quickly, since it is no longer necessary to heat the high heat capacity of the entire heating and cooling circuit, but only by means of the separate combustion chamber, which can be heated by the air conditioning circuit which can be designed for much lower heat capacity. The separation between the cooling circuit of the internal combustion engine and the air conditioning system simplifies the design of the cooling circuit, since its design only has to satisfy the aspects of cooling the internal combustion engine and <"ό no longer those of the motor vehicle heating. Because the combustion chamber is operated before the internal combustion engine is started and thus If the passenger compartment of the motor vehicle can be preheated or pre-cooled, the air conditioning system can be designed for a much lower cooling and heating peak output than with conventional systems.

Instead of the previously common division of motor vehicle air conditioning in a heating circuit with operation from the cooling of the internal combustion engine or exhaust gas heat and a cooling circuit operated with a separate compressor, linked by the control elements, which work against one another for the usual operating states of heating, cooling and dehumidification Individual systems had to be prevented, an integrated system occurs, which avoids interfaces known from the past between the cooling of the internal combustion engine and the air conditioning system. A control concept integrated in the air conditioning system according to the invention allows, depending on which individual functions, heating or cooling, or in which combination of the individual functions, heating and cooling, dehumidification, the output of the combustion energy used for the operation of the combustion chamber with heat exchanger available is provided to create an air conditioning system that is both quick-acting and energy-saving and operates independently of the function of the internal combustion engine of the motor vehicle.

drawing

Further advantages result from the following description of the drawing. Exemplary embodiments of the invention are shown in the drawing. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into useful further combinations. 1 shows a schematic structure of an air conditioning system, FIG. 2 shows a variant of FIG. 1 with a combustion chamber, FIG. 3 shows a schematic representation of an embodiment of an exhaust gas heat exchanger, FIG. 4 shows a variant of FIG. 3, FIG. 5 1 shows a schematic representation of a drive of a pump, 6 an insert in the exhaust gas heat exchanger for the refrigerant,

7 shows a variant of FIG. 2 with a combustion chamber independent of the internal combustion engine,

Fig. 8 shows a variant of a heat exchanger according to Fig. 3 with an integrated combustion chamber and

9 shows a variant of FIG. 8.

Description of the embodiments

1 is coupled in terms of energy to an exhaust system of an internal combustion engine 12 via an exhaust gas heat exchanger 22. The internal combustion engine 12 has a row of cylinders 14, the cylinders of which discharge exhaust gases into the environment via an exhaust manifold 16, an exhaust pipe 18, a catalytic converter 20, the exhaust gas heat exchanger 22 and a silencer 24. The exhaust gas heat exchanger 22 can be integrated in the cylinder head of the cylinder bank 14. In the exemplary embodiment according to FIG. Iv, it is arranged in the exhaust line downstream of the catalytic converter 20.

The exhaust gas heat exchanger 22 is connected to a refrigerant circuit 26. A pump 28, a so-called feed pump, conveys refrigerant from a storage container 34 into the exhaust gas heat exchanger 22. If the exhaust gas heat exchanger 22 has its

Reached operating temperature, the refrigerant leaves the exhaust gas heat exchanger 22 as refrigerant vapor and in the further course drives a motor 30, which can be an electric motor, but is expediently designed as a vane motor 80 (FIG. 5). This is drivingly connected by a drive shaft 32 to the pump 28, which is expediently designed as a gear pump 82 (FIG. 5). The rotary lines of the vane motor 80 and the gear pump 82 are indicated by arrows 84. The refrigerant flow resulting from the directions of rotation 84 is denoted by 66.

A three-way valve 36 branches the refrigerant flow downstream of the engine 30 onto two line branches 54 and 56. In heating mode, the refrigerant vapor passes back through the line branch 56 and a heating heat exchanger 38 into the storage container 34. The air flow 52 flowing into the vehicle is thereby in the heating heat exchanger 38 heated.

In cooling mode, the refrigerant vapor is supplied as motive vapor to an injector pump 42 via line branch 54. This sucks refrigerant from the storage container 34 via a suction line 60, an expansion valve 46 and an evaporator 40 and conveys the drawn-in refrigerant together with the motive steam via a collecting line 58 and an ambient heat exchanger 44 back into the collecting container 34. In the ambient heat exchanger 44, the refrigerant or heat is removed from the refrigerant vapor by an air flow 50 from the surroundings. To dehumidify the air flow 52 for the vehicle during heating operation, a mixed operation is possible in which part of the refrigerant vapor flows through the heating heat exchanger 38, while another part acts as the propellant gas on the injector pump 42. The air flow 52 can thus first be cooled in the evaporator 40 and then brought to the desired temperature in the heating heat exchanger 38.

Different designs can be used as the exhaust gas heat exchanger 22. Fig. 3 shows a tube heat exchanger 22, in which the refrigerant is passed through pipes 74 arranged parallel to one another, which at their ends through header boxes 70, 72 are interconnected. The tubes 74 and the header boxes 70, 72 are accommodated in a housing 68 through which the exhaust gas flow 48 flows. Heat is transferred from the exhaust gas stream 48 to the refrigerant stream 66. The exhaust gas heat exchanger 78 according to FIG. 4 is a so-called jacket heat exchanger 78, in which the refrigerant flow 66 is passed through a jacket room 76 through which the exhaust pipe 18 leads. Thus, thermal energy is transferred from the exhaust pipe 18 to the refrigerant.

In the embodiment according to FIG. 2, two pumps 28 and 64 are driven by the motor 30, of which the first pump 28 has a larger delivery volume and conveys refrigerant from the storage container 34 into the exhaust gas heat exchanger 22, while the second pump 64 with one smaller delivery volume liquid, heated refrigerant, which usually consists of higher-boiling components of the refrigerant, promotes from the exhaust gas heat exchanger 22 to the injector pump 42. The pumps 28, 64 can be of the same type, advantageously rotary pumps, and essentially differ only in width in accordance with the required delivery volume. The pump 28 or the two pumps 28 and 64 preferably form a structural unit with the motor 30. This results in a space-saving, compact and cost-effective solution, especially since the pumps 28, 64 essentially have the same exterior

Have diameters like the engine 30. The low-boiling components of the refrigerant leave the exhaust gas heat exchanger 22 in vapor form and drive the engine 30. After passing through the engine 30, the refrigerant vapor is condensed in an ambient heat exchanger 44 and collected in a second reservoir 62. This is via a suction line 60, an expansion valve 46 and an evaporator 40 with the I ejector pump 42 in connection. In cooling mode, in which the pump 64 conveys refrigerant with higher-boiling components to the injector pump 42, the latter draws in refrigerant from the additional reservoir 62, which consists of lower-boiling components and therefore easily evaporates in the evaporator 40 at lower pressures and generates cold. In the injector pump 42, the refrigerant, consisting of higher-boiling components, is mixed again with the evaporated refrigerant from lower-boiling components and fed to the common storage container 34.

By separating the refrigerant into the lower-boiling and higher-boiling components, the use of the higher-boiling components as motive steam or the propellant liquid for the injector pump 42 enables a higher vacuum to be evaporated and sucked in from the separate storage container 62 for the lower-boiling components. The lower-boiling components in the storage container 62 'at the same time allow a lower' evaporator temperature in the evaporator 40 and thus an improvement in the cooling capacity. Instead of the ambient heat exchanger 44, a heating heat exchanger 38 according to FIG. 1 can also be used. Furthermore, the heating heat exchanger 38 can be used in combination with the ambient heat exchanger 44. A further possibility is to connect the heating heat exchanger 38 in parallel to the injector pump 42 via a three-way valve 36, as is shown by broken lines.

In order to separate the lower-boiling components well from the higher-boiling components, an insert 100 is used for the exhaust gas heat exchanger 22 (FIG. 6) which, in the manner of a rectification column, is used to separate two-substance mixtures. is building. It has several bell bottoms 92 which divide the insert 100 in height and have openings 94 which have an upwardly directed collar. The openings 94 are covered at a distance from the bells 96, so that the collars of the openings 94 are axially overlapped by the bells 96. Overflows 98 are provided in the bell bottoms parallel to the openings 94. The refrigerant is supplied by the pump 28 via an inlet 86 in the upper part of the insert 100. Via an outlet 88 in the upper part of the insert 100, refrigerant can be removed as steam, consisting of lower-boiling components. In the lower part there is an intake line 90, via which the second pump 64 draws refrigerant with higher-boiling components. If the energy of the exhaust gas is not sufficient to operate the air conditioning system 10, it is expedient to connect a combustion chamber 102 to the exhaust line upstream of the exhaust gas heat exchanger 22, which has a fuel nozzle 104 and, if necessary, additionally heats the exhaust gases "T, or which, when the internal combustion engine is at a standstill, The combustion chamber 102 enables autonomous operation of the air conditioning system 10 with little energy input independently of the internal combustion engine 12. The air conditioning system 10 can, as the exemplary embodiment according to FIG Exhaust gas side as well as' on the refrigerant side from the internal combustion engine 12. In this case, the heat exchanger 22 is acted upon exclusively by a combustion chamber 106. This has a fuel nozzle 110 to which fuel 116 is supplied via a fuel line 108. The air 112 required for the combustion flows sideways the Fuel nozzle 110 into the combustion chamber 106. The combustion chamber 106 can advantageously with the Exhaust gas heat exchanger 22 form a structural unit. A separate exhaust pipe 18 can be provided for the exhaust gases 48 emerging from the exhaust gas heat exchanger 22 or the exhaust gases can be introduced into the exhaust system of the internal combustion engine 12. The air conditioning system 10 is thus quickly effective, energy-saving and independent of the functions of the internal combustion engine 12. It only needs to take into account the requirements of the air conditioning of the motor vehicle. The variants according to FIG. 8 9 show corresponding combustion chambers 118 and 120, which are integrated in heat exchangers 22 and 78 in the same way as the embodiments according to FIGS. 3 and 4.

1 and 2, the coolant flows through the heat exchanger 22 relative to the exhaust gas flow 48 in the countercurrent principle, the flow direction of the refrigerant and the exhaust gas in the exhaust gas heat exchangers 22 and 78 according to the explanations according to FIGS. 7 to 9 rectified.

Claims

Expectations

1. Air conditioning system (10) for a motor vehicle with an internal combustion engine (12), which essentially comprises a heating heat exchanger (38), an evaporator (40) and an exhaust gas heat exchanger (22, 78) in a refrigerant circuit (26) Heating operation, the refrigerant heated in the exhaust gas heat exchanger (22, 78) is passed via the heating heat exchanger (38) and in cooling operation, after it has been cooled in an ambient heat exchanger (44), via an expansion device (46) and an evaporator (40), characterized in that that the refrigerant has a low boiling point and, after flowing through the exhaust gas heat exchanger (22, 78), is supplied as a propellant to at least one device (30, 42) for conveying the refrigerant.

2. Air conditioning system (10) according to claim 1, characterized in that the refrigerant is an alcohol-water mixture.

3. Air conditioning system (10) according to claim 1 or 2, characterized in that the refrigerant vapor drives a motor (30) which is connected via a drive shaft (32) to at least one pump (28, 64) for the refrigerant.

4. Air conditioning system (10) according to claim 3, characterized in that two pumps (28, 64) are provided, of which the first pump (28) with a larger delivery volume of refrigerant from a reservoir (34) to the exhaust gas heat exchanger (22, 78) promotes and the second pump (64) with a lower delivery volume is used to remove liquid refrigerant from the exhaust gas heat exchanger (22, 78).

5. Air conditioning (10) according to claim 4, characterized in that the pumps (28, 64) are rotary piston pumps with the same outer diameter, which have different widths according to their delivery volumes.

6. Air conditioning (10) one of claims 3 to 5, characterized in that the pump (28, 64) with the motor (30) forms a structural unit.

7. Air conditioning system (10) according to one of claims 3 to 6, characterized in that the motor (30) is a vane motor (80).

8. Air conditioning system (10) according to one of the preceding claims, characterized in that the refrigerant is used as motive steam for a Veuillemier heat pump or in the expeller of an absorption cooling system.

9. Air conditioning system (10) according to one of the preceding claims, characterized in that in the refrigerant circuit

(26) an injector pump (42) is provided, which in cooling operation is supplied with hot refrigerant from the exhaust gas heat exchanger (22) as a propellant via a line branch (54) and which is supplied via a suction line (60), an expansion valve (46) and the evaporator ( 40) Sucks refrigerant from a storage tank (34 or 62).

10. Air conditioning system (10) according to claim 9, characterized in that the exhaust gas heat exchanger (22) for driving the engine (30) refrigerant vapor is taken from lower-boiling components, which condenses in an ambient heat exchanger (44) and in a second reservoir (62 ) collected is connected to the injector pump (42) via a suction line (60), an expansion valve (46) and an evaporator (40).

11. Air conditioning system (10) according to claim 10, characterized in that the exhaust gas heat exchanger (22) has an insert (100) which is constructed in the manner of a rectification column for separating two-substance mixtures.

12. Air conditioning system (10) according to one of the preceding claims, characterized in that at least one heat exchanger (38, 40, 44) is combined with a storage container (34, 62).

13. Air conditioning system (10) according to one of the preceding claims, characterized in that the exhaust side of the exhaust gas heat exchanger (22, 78) is connected to the exhaust system (16, 18, 20, 24) of the internal combustion engine (12).

14. Air conditioning system (10) according to claim 13, characterized in that the exhaust gas heat exchanger (22, 78) is integrated in the cylinder head of the internal combustion engine (12).

15. Air conditioning system (10) according to claim 13, characterized in that the exhaust gas heat exchanger (22, 78) in the exhaust line

Internal combustion engine (12) is arranged between an outlet of a combustion chamber and an exhaust gas turbocharger.

16. Air conditioning system (10) according to claim 13 or 15, characterized in that the exhaust gas heat exchanger (22, 78) in the exhaust line of the internal combustion engine (12) after a catalyst (20) is arranged.

17. Air conditioning system (10) according to claim 13, characterized in that a combustion chamber (102) is connected to the exhaust system (16, 18, 20, 24) in the flow direction of the exhaust gas flow (48) upstream of the exhaust gas heat exchanger (22, 78).

18. Air conditioning system (10) according to one of claims 1 to 12, characterized in that the exhaust side of the exhaust gas heat exchanger (22, 78) is connected exclusively to at least one combustion chamber (106, 118, 120) which is separate from the internal combustion engine ( 12) is operated.

19. Air conditioning system (10) according to claim 17 and 18, characterized in that the combustion chamber (102, 106, 118, 120) forms a structural unit with the exhaust gas heat exchanger (22, 78).

20. Air conditioning system (10) according to one of the preceding claims, dadurc (characterized in that the exhaust gas heat exchanger (22, 78) is flowed through by the exhaust gas relative to the refrigerant according to the co-current principle or counter-current principle.