AT512807B1 - Vehicle, in particular racing vehicle - Google Patents

Abstract

The invention relates to a vehicle with a drive unit (1) having an internal combustion engine (2), wherein the internal combustion engine (2) has an exhaust gas turbocharger (5) with an exhaust gas turbine (5a) in the exhaust system and a charge air compressor (5b) in the intake system (3) , with at least one heat power plant (30) for recovering heat from a heat-emitting component or a heat-dissipating assembly, the component or assembly being adjacent to at least one space (6) through which a working gas, in particular air, flows, with a first compressor ( 9) and a first turbine (10), wherein a first outlet side (9b) of the first compressor (9) is flow-connected to an inlet region (7) of the space (6) and a second outlet side (9c) of one of the first turbine (10 ) driven second compressor (9 ') or a second outlet side (9d) of the preferably mehrflutig formed first compressor (9) with the inlet system (3) strömungsver is connected, and wherein the heat-emitting component or the heat-dissipating assembly by the exhaust system (4) of the internal combustion engine (2) is formed. In order to improve the efficiency of the vehicle in the simplest possible way, it is provided that the exhaust system (4) surround at least one exhaust manifold (4a) surrounded by at least one space (6) and / or at least one space (6) Exhaust duct in the cylinder head of the internal combustion engine (2).

Description

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The invention relates to a vehicle, in particular a racing vehicle, with a drive unit having an internal combustion engine, wherein the internal combustion engine has an exhaust gas turbocharger with an exhaust gas turbine in the exhaust system and a charge air compressor in the intake system, with at least one thermal power plant for the recovery of heat from a heat emitting component or a heat-emitting assembly, wherein the component or assembly adjacent to at least one of a working gas, in particular air, space, in particular is at least partially surrounded by the space flowed through, with a first compressor and a first turbine, wherein a first exit side of the first Compressor is flow-connected to an inlet region of the space and a second outlet side of a second compressor driven by the first turbine or a second outlet side of the preferably multi-flow formed first compressor with the Inlet system is flow-connected, and wherein the heat-emitting component or the heat-dissipating assembly is formed by the exhaust system of the internal combustion engine.

In racing and sports vehicles accelerations, decelerations and cornering accelerations are achieved, which exceed the value of 1 g (= gravitational acceleration) considerably. Such values are only possible if the limits of adhesion between the tires and the road surface are increased with aerodynamic aids. On the vehicle body strong downforce is generated. Front wing, rear wing and a special shaping of the actual vehicle body serve this purpose. A dominating role is played by the design of the vehicle underbody. The aim is to accelerate the air flowing under the vehicle floor as much as possible. The higher their speed, the stronger according to the Bernoulli law their suction power and the stronger the force exerted on the vehicle underbody downforce. To achieve the greatest possible acceleration of the underbody air, the kinetic energy of the exhaust gases is used in today's racing cars: The underbody is bent upwards at the rear of the vehicle and shielded to the side usually with vertical aerodynamic baffles and possibly divided in the middle. In this way creates a diffuser for the air flowing under the vehicle. Into this diffuser zone, the ends of the exhaust pipes are introduced with horizontal jet direction aiming backwards. The exiting at high velocity exhaust gases exert on the air under the subsoil a suction effect. They increase their speed and thus their suction on the underbody and thus the output of the vehicle.

DE 2 554 953 A1 describes a drive unit for a vehicle having an internal combustion engine with a device for recovering heat from the exhaust line, wherein a part of the exhaust system is surrounded by a jacket space, the inlet region with a compressor and the outlet region with a Hot air turbine is fluidly connected. The compressor is drive connected to the crankshaft of the internal combustion engine. The hot air turbine is in mechanical communication with the differential of the vehicle via a transmission and an overrunning clutch. The disadvantage is that mechanical power must be applied by the crankshaft to drive the compressor.

DE 40 15 104 A1 describes a combined heat and power plant from partly successively connected heat engines, which transfer their usable waste heat to one of the other combined other engines, the upstream heat engine supplies in the embodiment as an internal combustion engine exhaust as compressed gas for the subsequent heat engine and this drives a compressor and transfers the exhaust gas of the subsequent heat engine as heat input to a steam power plant.

From DE 10 2010 003 537 A1 discloses a thermal power plant with a compressor, a compressed gas working machine, a gas heater and a gas cooler in a pressure gas connection leading to the compressor, the compressor, the compressed gas working machine, the gas heater and the gas cooler in a closed Joule cycle 1/14

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The US 3,554,849 A discloses a vehicle with an internal combustion engine, the exhaust heat can be used via an opening into the exhaust system heat exchanger and a steam-powered engine.

Furthermore, from US 5,806,332 A a power generation system for a motor vehicle with an internal combustion engine is known, the exhaust energy is recovered by means of a closed cycle with heat exchangers in the exhaust system and an expansion unit connected to a generator part, wherein energy is stored in a battery.

EP 1 408 224 A1 discloses a drive unit with an internal combustion engine for a vehicle, wherein the internal combustion engine has an exhaust gas turbocharger with an exhaust gas turbine in the exhaust system and a charge air compressor in the intake system. By means of a thermal power plant heat can be recovered from a waste heat-emitting component or a heat-emitting assembly, wherein the component or assembly adjacent to at least one of a working gas flowed through space. The thermal power plant comprises a compressor and a turbine, wherein an outlet side of the compressor is flow-connected to an inlet region of the space. With the turbine, another compressor is drive-connected, wherein the outlet side of one of the two compressors is flow-connected to the inlet system.

DE 199 60 762 A1 describes a gas turbine system for mechanical energy recovery in an internal combustion engine having at least a compressor, a heat exchanger and a turbine, wherein a compressor and a turbine are mechanically coupled together and wherein the compressor in front of the heat exchanger and the Turbine are arranged after the heat exchanger and connected to the primary side of the heat exchanger. The secondary side of the heat exchanger is connected to an exhaust pipe of the internal combustion engine. The exit side of a second compressor is fluidly connected to the intake system.

DE 10 2010 047 518 A1 describes a device for energy recovery from an exhaust gas stream of an internal combustion engine in a vehicle, wherein in a waste heat recovery device, a working medium is guided in a closed Joule cycle and the closed Joule cycle a Claudius-Rankine cycle is downstream. A turbine arranged in the Joule cycle and an expansion machine arranged in the Claudius-Rankine cyclic process can be mechanically coupled to a flywheel of the internal combustion engine.

Discloses a vehicle with an internal combustion engine having a drive unit, with at least one thermal power plant for the recovery of heat from a heat emitting component or a heat dissipating assembly, wherein the component or assembly adjacent to at least one of a working gas traversed space. The thermal power plant has a compressor and a turbine, wherein the outlet side of the compressor is flow-connected to an inlet region of the space.

The object of the invention is to use the exhaust heat as efficiently as possible in the simplest possible way. In this case, good flow properties of the vehicle to be achieved and in particular the flow resistance and the road holding of the vehicle to be improved.

According to the invention this is achieved in that the exhaust system comprises at least one of at least one space flowed through the exhaust manifold and / or at least one of at least one space flowed through the exhaust duct in the cylinder head of the internal combustion engine.

The first compressor is either drivingly connected to a second compressor, or has multiple floods. An exit side of at least one second tide of the multi-flood

ssierreic?> sches psfeniawt AT512 807B1 2014-01-15 formed the first compressor, or the outlet side of the second compressor opens into the intake system and thus causes a charge of the intake air in the intake system of the internal combustion engine.

The second compressor or the second tide of the first compressor can be arranged either in series or parallel to the charge air compressor of the exhaust gas turbocharger and thus support its charging work. Preferably, at least one charge air cooler is arranged downstream of the second compressor or the second flow of the first compressor. When connected in series with the charge air compressor of the exhaust gas turbocharger, an intercooler can be arranged between the second compressor or the second trough of the first compressor and the charge air cooler.

In order to reduce the cooling surfaces of the main radiator of the cooling system of the internal combustion engine, it is advantageous if at least one radiator, preferably for cooling a cooling and / or lubricating medium of the internal combustion engine, is arranged in the flow path to or from the first or second compressor.

The cooler may be formed by an oil cooler or radiator, which is integrated into the oil or cooling water circuit of the internal combustion engine.

Preferably, via a controllable switching or mixing valve, the radiator with the oil or cooling water circuit can be connected if necessary.

The cooler may be arranged upstream of the inlet region in the space through which it flows, for example downstream of the first compressor. This allows sufficient cooling of the cooling or lubricating medium. Alternatively or possibly additionally, it may be advantageous to arrange the first heat exchanger upstream of the second compressor.

The first turbine may be formed by a hot air turbine, wherein at least one outlet region of the space flowed through may be fluidly connected to the hot air turbine. Alternatively, the first turbine may be an exhaust gas turbine arranged in the exhaust system of the internal combustion engine.

The first compressor and the second compressor are preferably driven by the first turbine. The first compressor driven by the first turbine delivers air, the compressed air being supplied to the space, heated by the hot gases, and used to drive the first turbine.

The second compressor also delivers air. Unlike the first compressor, however, this air is drawn in through the first radiator, whereby the air flows over the cooling surfaces of the first radiator with high flow velocity. The resulting cooling effect makes it possible to make the cooling surfaces of the first cooler smaller and / or possibly even to dispense with a separate fan.

After leaving the first turbine, the air still has temperatures above 400 ° C. In order to utilize the residual heat and to improve the efficiency, it is advantageous if the outlet flow path of the first turbine and the outlet flow path of the first compressor are thermally connected to one another, preferably via at least one heat exchanger. Preferably, it is provided that the thermal connection with the exit flow path of the first compressor in the outlet flow path of the first turbine upstream of an outlet opening of the outlet flow path of the first turbine, and the thermal connection with the outlet flow path of the first turbine in the outlet flow path of the first compressor upstream of the inlet region of the room is arranged. This allows a particularly high efficiency.

In vehicles with aerodynamic output-enhancing devices, especially in racing vehicles, it is particularly advantageous if the output-increasing device is arranged in the pressure-side flow path of the first and second compressor so that the compressed working gas, in particular compressed air, on the output-increasing third / 14

SftiRiä & AT512 807B1 2014-01-15

Institution is headed. Thus, both the effluent from the hot air turbine, as well as the exiting from the second compressor flow can be used to generate additional output. The outlet openings are arranged so that the resulting overpressure increases the efficiency of aerodynamic components. As a result, the output of the vehicle can be significantly increased. The output-increasing device can be formed by a rear wing, wherein preferably at least one outlet opening from the pressure-side flow path of the first compressor of the first turbine exit flow path in the area below the road surface facing bottom of the rear wing, particularly preferably arranged in the region of the front edge of the rear wing is. The output-increasing device can also be formed by a preferably formed by a vehicle underbody of the vehicle diffuser in the rear of the vehicle, wherein at least one outlet opening from the pressure-side flow path of the first compressor and / or one coming from the first turbine exit flow path is arranged in the region of the diffuser. In particular, the outlet opening can be arranged in the region of a stagnation point on the side of the diffuser facing the road surface or arranged on the side of the diffuser facing the roadway, the outlet opening preferably being arranged in an initial region of the diffuser.

Characterized in that the drive unit has a thermal power plant for the recovery of heat from a heat-emitting component or a heat-dissipating assembly, heat losses can be reduced. In this case, the component or the assembly is adjacent to at least one space through which a gas, preferably air, flows, wherein the component or the assembly may be surrounded at least partially or predominantly, preferably completely, by the space through which it flows. But it is also possible that the air-flow space is part of a second heat exchanger. At least one inlet region of the air-flowed space is flow-connected to the pressure side of the first compressor. In this embodiment, the first turbine is preferably formed by a hot air turbine, wherein at least one outlet region of the air-flow space is fluidly connected to the hot air turbine. The first turbine is thus arranged in the pressure-side flow path of the first compressor downstream of the air-flow space.

It when the first and second compressor and / or the first turbine, preferably via a common shaft, is drivingly connected to an electric machine is particularly advantageous. The residual kinetic energy of the hot air turbine remaining after driving the first and second compressors can thus be used to generate electrical energy. Furthermore, the power tool of the first turbine or of the first and / or second compressor can be brought to operating speed very quickly by means of the electric machine. Alternatively or additionally, it may also be provided that the first turbine is mechanically connected to the drive train of the vehicle, wherein preferably the first turbine may be arranged parallel to the internal combustion engine and / or parallel to an electric drive machine.

Both the hot air turbine, and the first compressor, are preferably substantially only of air - and not mainly about exhaust gas - flows through. Thus, in most cases no flow connection between the exhaust gas flow path and air-flow space is required.

Depending on the configuration, it may also be quite advantageous if between the exhaust system and the space at least one preferably via a valve controllable flow connection, for example upstream of a provided in the exhaust system of the internal combustion engine second turbine - an exhaust gas turbine of an exhaust gas turbocharger - is arranged. In this case, the controllable valve can replace, for example, the wastegate of the exhaust-gas turbocharger and be actuated, for example, as a function of the boost pressure. Thus, exhaust gas blown off via the valve into the space through which air flows can additionally be used to drive the hot air turbine. 4.14

By virtue of the fact that both the first compressor and the second compressor are driven directly by the hot-air turbine, no additional drive energy is required for the compression of the air, which is formed by the jacket, which is preferably designed as a jacket space Room of the heat-emitting component or the output-increasing device flows.

A particularly effective use of the heat energy of the exhaust system can take place when the first turbine is formed mehrflutig or multi-stage.

The invention is explained in more detail below on the basis of the figures: FIG. 1 shows schematically: [0033] FIG. 1 [0033] FIG. 2 to FIG. 4 [0035] FIG. 6 [0036] FIG 7 to 10 FIG. 11 [0038] FIG. 12 a drive unit of a vehicle according to the invention in a first embodiment variant; various embodiments of drive units of vehicles according to the invention; the detail V of Figures 1 to 4 in an embodiment of the invention. a detail of Figures 1 to 4 in an embodiment of the invention. various variants for the arrangement of the outlet opening of the compressor; a drive unit with parallel drive machines; and another variant of a drive unit with parallel drive machines.

Functionally identical parts are provided with the same reference numerals.

The drive unit 1 shown in FIG. 1 has an internal combustion engine 2 with an intake system 3 and an exhaust system 4. E is the exhaust gas flow and T is the inlet flow indicated. There is provided a thermal power plant 30 for recovering the heat energy from the exhaust gas. The exhaust system 4 is at least partially surrounded by an air-flow space 6 formed by a jacket space, which is flowed through with respect to the exhaust gas flow according to the DC or countercurrent principle of compressed air according to the arrows A. The space 6 has an inlet area 7 and an outlet area 8, wherein the inlet area 7 is flow-connected to a first compressor 9 and the outlet area 8 to a first turbine 10 formed by a hot-air turbine 100. The inlet side of the first compressor 9 is designated by 9a and the first outlet side of the first compressor 9 by 9b. The hot air turbine 100 is arranged in correspondence with the first compressor 9 and thus drives the first compressor 9 via the shaft 13. The Ansaugströmungsweg in the first compressor 9 is denoted by reference numeral 11, the downstream of the first compressor 9 arranged exit flow path from the hot air turbine 100 is denoted by reference numeral 12. In the intake and exhaust system 3, 4, an exhaust gas turbocharger 5 is arranged, which has a second turbine 5a (exhaust gas turbine) in the exhaust system 4 and a charge air compressor 5b in the intake system 3. The inlet side of the first turbine 10 is denoted by reference numeral 10a, the outlet side of the turbine 10 by 10b.

Over the Ansaugströmungsweg 11 9 ambient air is sucked in, for example, a temperature Ti = 20 ° C and compressed by the first compressor. After the first compressor 9, the compressed air, for example, a temperature T2 of about 90 - 100 ° C. The compressed air passes via the inlet region 7 into the space 6, which may be part of a second heat exchanger, and flows around the shrouded area of the exhaust system 4, for example, exhaust gas aftertreatment devices not shown further, the exhaust gas turbine 5a of the exhaust gas turbocharger 5, and the manifold assembly 4a of the outlet system 4 in countercurrent principle. The temperature of the air increases steadily in the space 6 and may be in the outlet 8 a temperature T3 = 530 ° - 600 ° C. The heated air leaves the 5/14

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Room 6 in the outlet region 8 and passes to the hot air turbine 100, wherein under Arbeitsverrichtung enters a relaxation of the compressed air. On the exit side 10b of the first turbine 10, for example T4 = 460 ° - 470 ° C can be observed. The hot air turbine 100 drives the first compressor 9. Via the outlet flow path 12, the expanded air is supplied to at least one outlet opening 12a.

As shown in Fig. 1 by dashed lines, the shaft 13 of the first compressor 9 and the hot air turbine 100 with an electric machine 14, which is connected to an electrical memory 15, be drivingly connected, whereby a part of the heat energy to Power generation can be used. Furthermore, the electric machine 14 can be used to start up the first compressor 9.

Fig. 5 shows a detail of an embodiment of the invention, in which the exhaust system 4 and the air-flow space 6 are interconnected by a flow connection 6a, wherein in the flow connection 6a, a valve 6b is arranged, which can be controlled, for example, in dependence on the boost pressure can be. The controllable valve 6b can assume the functions of a wastegate 5c of the exhaust gas turbine 5a of the exhaust gas turbocharger 5. But the valve 6b may also be a non-return valve actuated by differential pressure.

In addition to power generation, first compressor 9 and hot air turbine 100 can also be used to support the cooling of cooling circuits in the vehicle and / or to generate additional output force for the vehicle, as shown in FIGS. 1 to 9.

As can be seen in FIGS. 1 and 3, a second compressor 9 'can be provided coaxially with the first compressor 9, which is driven together with the first compressor 9 by the first turbine 10. The suction port of the first compressor 9 is denoted by 11a, the suction port of the second compressor 9 'by 11a'. The second outlet side 9 c of the second compressor 9 'opens into the inlet system 3.

FIGS. 2 and 4 show variant embodiments in which the first compressor 9 is designed to be at least double-flowed. The first outlet side 9b of the first flow of the first compressor 9 is - as in FIGS. 1 and 3 - fluidly connected to the inlet region 7 of the space 6. The second exit side 9d of the second tide 9 " On the other hand leads to the intake system 3 and supports - as in Figs. 1 and 3, the charging of the intake air of the internal combustion engine. 2

The second compressor 9 'or the second tide 9 " of the first compressor 9 may be arranged in series or parallel to the charge air compressor 5b of the exhaust gas turbocharger 5. FIGS. 1 and 2 show embodiments with serial arrangements, whereas FIGS. 3 and 4 show examples with parallel arrangements.

Downstream of the second compressor 9 'or the second tide 9 " of the first compressor 9, at least one intercooler LK can be arranged.

As can be seen from FIGS. 1 to 4, at least one cooler 40, preferably for cooling a cooling and / or lubricating medium of the internal combustion engine 2, may be arranged in the flow path to or from the first or second compressor 9 '.

The embodiment shown in FIG. 6 essentially corresponds to FIGS. 1 to 4, although the outlet flow path 12 of the first turbine 10 and the outlet flow path 11 b of the first compressor 9 are thermally connected to one another via at least one first heat exchanger 42. Thereby, residual heat of the discharge flow path 12 upstream of the inlet region 7 is supplied to the discharge flow path of the first compressor 9.

The outlet opening 12a from the outlet flow path 12 may be arranged so that the effect of an output-increasing device 32 can be increased, as will be explained in detail below with reference to FIGS. 7 to 10.

FIGS. 7 to 10 show variant embodiments in which a defined 6/14

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Arrangement of the outlet opening 12a of the first turbine 10 in the region of an output-increasing device 32, an output increase of the vehicle can be achieved. The output-increasing device 32 may be formed for example by a special shape of the body, the vehicle floor 19 and / or by aerodynamic elements such as the rear wing 22. A vehicle, for example a racing vehicle, is indicated schematically in FIGS. 7 to 10. Reference numeral 18 denotes the rear wheels of the vehicle. The vehicle underbody 19, which is formed in a wide area parallel to the roadway 20, has a rising area 19a in the area of the rear wheels 18, which forms a so-called diffuser 21. The fact that the vehicle underbody 19 is bent upwards at the rear of the vehicle and possibly shielded to the side with vertical aerodynamic air baffles creates a diffuser 21 for the air which flows under the vehicle, which effects the output in the remaining area of the vehicle underbody 19 elevated. Additional output forces can be generated by targeted positioning of the outlet opening 12a of the outlet flow path 12.

Fig. 7 shows an arrangement in which the outlet opening 12a below the - viewed in the direction of travel - front portion 22a of the rear wing 22 is arranged. An increase in output can also be achieved if the outlet opening 12a in the region of the stagnation point of the diffuser 21 (Fig. 8) or within the diffuser 21, for example in the beginning of the diffuser 21 (Fig. 9) or in a central region of the diffuser 21 (Fig 10).

In particular, for the increase of the output of the vehicle, the combination of the first compressor 9 and first turbine 10, in particular hot air turbine 100, and a second compressor 9 'can be used with particular advantage, since the hot air turbine 100 only very sluggish on speed - and Load changes of the internal combustion engine 2 reacts. While an output induced in a conventional manner by the exhaust flow is highly dependent on the engine speed, the output supported by the hot air turbine 100 can be maintained even with sudden reductions in engine 2 speed, especially when cornering. This significantly improves the road holding and driving safety of the vehicle.

The emerging from the outlet opening 12a air can not only be used to increase the output, but possibly also to disturb the output by deliberately causing a stall in output-increasing devices to reduce the flow resistance. This can be advantageous, for example, on long straight sections of a racetrack in order to increase the top speed. For this purpose, the air is supplied to the output-increasing device at a location which is particularly sensitive to stalls, for example, in a direction away from the direction of the rear wing or diffuser. It is advantageous if the air can optionally be switched manually or automatically with switching elements optionally between outlet-increasing and output-destroying outlet openings 12a as needed.

For starting the thermal power plant optionally compressed air between the space 6 and the first turbine 10, possibly through the driven via the electric machine 14 first or second compressor 9, 9 'are blown. Furthermore, in certain operating ranges, it may be advantageous to recirculate some of the hot air from the exit of the first turbine 10 upstream of the first compressor 9 or to supply it upstream of the second compressor 9 '.

The means 30 for recovering heat energy from the exhaust gas may further be arranged to drive the vehicle in the drive train parallel to the engine 2 and parallel to an electric drive machine 31, as shown in FIGS. 11 and 12. Here, the first turbine 10 - in particular the hot air turbine 100 - the thermal power plant 30, the internal combustion engine 2 and the electric drive machine 31 via one or more clutches 24, 25, 26, 27 and / or via gear and / or planetary gear 29, 29 a, 29b on a drive shaft 28 a. 7.14

Claims (29)

A vehicle, in particular a racing vehicle, with a drive unit (1) having an internal combustion engine (2), the internal combustion engine (2) having an exhaust gas turbocharger (5) with an exhaust gas turbine (5). 5a) in the exhaust system and a charge air compressor (5b) in the intake system (3), comprising at least one thermal power plant (30) for recovering heat from a heat emitting component or a heat dissipating assembly, the component or assembly to at least one of a working gas , in particular air, flows through space (6) bordered, in particular at least partially surrounded by the space (6), with a first compressor (9) and a first turbine (10), wherein a first outlet side (9b) of the first compressor ( 9) is fluidly connected to an inlet region (7) of the space (6), and a second outlet side (9c) of a second Verd driven by the first turbine (10) ichters (9 ') or a second outlet side (9d) of the preferably multi-flow formed first compressor (9) with the inlet system (3) is fluidly connected, and wherein the heat-emitting component or the heat-dissipating assembly through the exhaust system (4) of the internal combustion engine ( 2), characterized in that the exhaust system (4) at least one of at least one flowed through space (6) surrounded exhaust manifold (4a) and / or at least one of at least one space flowed through (6) surrounded exhaust passage in the cylinder head of the internal combustion engine (2 ) having. 2. Vehicle according to claim 1, characterized in that the second compressor (9 ') or the second tide (9 ") of the first compressor (9) is arranged serially to the charge air compressor (5b) of the exhaust gas turbocharger (5). 3. Vehicle according to claim 1, characterized in that the second compressor or the second flow of the second compressor (9 ') is arranged parallel to the charge air compressor (5b) of the exhaust gas turbocharger (5). 4. Vehicle according to one of claims 1 to 3, characterized in that downstream of the second compressor (9 ') or the second flood (9 ") of the first compressor (9) at least one charge air cooler (LK) is arranged. 5. Vehicle according to one of claims 1 to 3, characterized in that in the flow path to or from the first or second compressor (9 ') at least one cooler (40), preferably for cooling a cooling and / or lubricating medium of the internal combustion engine (2). is arranged. 6. Vehicle according to claim 5, characterized in that the cooler (40) is formed by an oil cooler or water cooler, wherein preferably the cooler (40) in the Öloder cooling water circuit of the internal combustion engine (2), is integrated. 7. Vehicle according to claim 5 or 6, characterized in that the cooler (40) upstream of the inlet region (7) in the space flowed through (6) is arranged. 8. Vehicle according to one of claims 5 to 7, characterized in that at least one cooler (40) downstream of the first compressor (9) is arranged. 9. Vehicle according to one of claims 5 to 8, characterized in that at least one cooler (40) upstream of the second compressor (9 ') is arranged. 10. Vehicle according to one of claims 1 to 9, characterized in that the outlet flow path (12) of the first turbine (10) and the outlet flow path (11b) of the first compressor (9), preferably via at least one heat exchanger (42), with each other thermally are connected. 11. A vehicle according to claim 10, characterized in that the thermal connection with the outlet flow path of the first compressor in the outlet flow path of the first turbine upstream of an outlet opening of the outlet flow path first turbine (10) is arranged. 8/14 fcfemsä & AT512 807B1 2014-01-15 12. Vehicle according to claim 10 or 11, characterized in that the thermal connection with the outlet flow path (12) of the first turbine (10) in the outlet flow path (11b) of the first compressor (9) upstream of the inlet region (7) of the space (6). is arranged. 13. Vehicle according to one of claims 1 to 12, characterized in that the first compressor (9) with the first turbine (10), preferably via a common shaft (13), is drivingly connected. 14. Vehicle according to one of claims 1 to 13, characterized in that an outlet region (8) of the flow-through space (6) with an inlet side (10a) of the first turbine (10) is fluidly connected. 15. Vehicle according to claim 14, characterized in that the first turbine (10) by a hot air turbine (100) is formed wherein at least one outlet region (8) of the flowed space (6) with the hot air turbine (100) is fluidly connected. 16. Vehicle according to one of claims 1 to 15, characterized in that the first compressor (9), the second compressor (9 ') and / or the first turbine (10), preferably via a common shaft (13), with a electric machine (14) is drivingly connected. 17. Vehicle according to one of claims 1 to 16, characterized in that the first turbine (10) is formed mehrflutig or multi-stage. 18. Vehicle according to one of claims 1 to 17, characterized in that in the outlet flow path (12) of the first turbine (10), preferably downstream of the thermal connection with the outlet flow path (11b) of the first compressor (9), at least one output-increasing device ( 32), wherein preferably at least one outlet opening (12a) of the outlet flow path (12) of the first turbine (10) is arranged in the region of the output-increasing device (32) of the vehicle. 19. Vehicle according to claim 18, characterized in that the output-increasing device (32) by a rear wing (22) is formed, wherein preferably at least one outlet opening (12a, 12a ') in the region below the road (20) facing the underside of the rear wing (22), particularly preferably in the - viewed in the direction of travel - front region (22a), in particular in the front third of the rear wing (22), is arranged. 20. Vehicle according to one of claims 18 or 19, characterized in that the output-increasing device (32) by a preferably formed by a vehicle underbody (19) of the vehicle diffuser (21) is formed in the rear of the vehicle, wherein at least one outlet opening (12 a , 12a ') is arranged in the region of the diffuser (21). 21. Vehicle according to one of claims 18 to 20, characterized in that the outlet opening (12a, 12a ') in the region of a stagnation point on the roadway (20) facing side of the diffuser (21) is arranged. 22. Vehicle according to one of claims 18 to 21, characterized in that at least one outlet opening (12a, 12a ') on the roadway (20) facing side of the diffuser (21) is arranged, wherein preferably the outlet opening (12a, 12a' ) is disposed in an initial region of the diffuser (21). 23. Vehicle according to one of claims 1 to 22, characterized in that the first turbine (10) preferably via at least one clutch (24, 27) or a transmission (29 a, 29 b, 29) connected to a drive shaft (28) of the vehicle is, wherein preferably the hot air turbine (10) in the drive train of the vehicle parallel to the internal combustion engine (2), particularly preferably parallel to an electric drive machine (31) is arranged. 9.14 s ^ rrekMsches ps ("r: t3wt AT512 807B1 2014-01-15 24. Vehicle according to one of claims 1 to 23, characterized in that the space (6) through which flows is a jacket space which at least partially, preferably predominantly, surrounds the component or the assembly. 25. Vehicle according to one of claims 1 to 24, characterized in that the flow-through space (6) is part of at least one second heat exchanger. 26. Vehicle according to claim 25, characterized in that between the outlet system (4) and the space (6) at least one flow connection (6a) is arranged. 27. Vehicle according to claim 26, characterized in that the flow connection (6a) upstream of a in the exhaust system (4) of the internal combustion engine (2) arranged second turbine (5a) of an exhaust gas turbocharger (5) is arranged. 28. Vehicle according to claim 26 or 27, characterized in that in the flow connection (6a) at least one preferably controllable valve (6b) is arranged. 29. Vehicle according to one of claims 1 to 29, characterized in that the thermal power plant (30) has an open cycle. 4 sheets of drawings 10/14