DE102015224593A1 - Charge air cooling device for a fresh air system of an internal combustion engine of a motor vehicle - Google Patents

Abstract

The invention relates to a charge air cooling device (1) for a fresh air system of an internal combustion engine of a motor vehicle. The charge air cooling device (1) comprises a heat exchanger (2) which can be integrated or integrated into an actively cooled first cooling circuit (5a) and / or into a passively cooled second cooling circuit (5b) by means of a (first) valve device (4).

Description

The invention relates to a charge air cooling device for a fresh air system of an internal combustion engine of a motor vehicle and a fresh air system with such a charge air cooling device.

The power density of internal combustion engines correlates with the air mass introduced into the displacement. To increase this, charging technologies, typically in the form of exhaust gas turbochargers, are used, which compress the intake air to the so-called charge air and thereby increase the pressure. A further increase in the charge air density is achieved by cooling the temperature of the charge air to near ambient temperature.

A further increase in the power density of internal combustion engine by supercharging is limited by too high peak temperatures in the combustion process, which can have a harmful knocking combustion result in gasoline engine. Therefore, excessive fuel gas temperatures must be avoided at all costs in order to avoid damaging the internal combustion engine. This can be achieved by retarded ignition and mixture enrichment, which, however, can negatively affect power density and noxious gas emissions.

In diesel engines, on the other hand, the limitation of high charging is mainly due to the increasing NOx formation rate due to combustion temperatures that are too high. Direct and increasingly indirect charge air cooling systems are therefore known from the prior art.

In the indirect charge air cooling systems, charge air in the fresh air system is cooled by a coolant, which in turn is kept at a near ambient temperature by means of a low-temperature radiator arranged in the cooling module. Due to the thermal storage effect of this cooling circuit can be transferred to the charge air for a short time high cooling performance.

The sensible heat absorbed by the cooling circuit can then be recooled to near ambient temperature over a longer period of time via a low-temperature cooler.

However, the indirect passive charge-air cooling concept still has the disadvantage that the charge air inlet temperatures in the internal combustion engine still comes to lie significantly above the ambient temperature. To avoid correspondingly high compression or combustion peak temperatures, power, consumption and / or emission-damaging measures of mixture formation and combustion management must therefore be taken.

Against this background, the DE 10 2010 062 714 A1 a method for controlling a high-temperature intercooler, which cooperates with an engine cooling circuit of an internal combustion engine. In the course of the process, the flow of a high temperature coolant through the high temperature charge air cooler is controlled in response to at least one predetermined parameter.

The DE 10 2011 003 664 A1 Treats a hollow element for a heat pump with two areas between which a working fluid is displaced. In the first area a sorbent for adsorption and desorption of the working fluid is arranged. In the second area, a receiving means for condensation and evaporation of the working fluid is arranged. At least one of the two areas is in heat exchange with a plurality of exchanger tubes.

It is therefore an object of the present invention to provide an improved charge air cooling device, which is characterized with an indirect intercooler by improved cooling performance and in particular is able to realize temporarily required high charge air peak cooling performance well below ambient temperature without additional fuel consumption.

This object is solved by the subject matter of the independent patent claims. Preferred embodiments are subject of the dependent claims.

An intercooler according to the invention for a fresh air system of an internal combustion engine comprises a heat exchanger, which can be incorporated or integrated into an actively cooled first cooling circuit and / or into a passively cooled second cooling circuit by means of a (first) valve device. In this way, the cooling power to be provided by the charge air cooling device can be individually adapted to external requirements. If the cooling power provided by the passive cooling circuit is insufficient to reduce the temperature of the coolant to the required extent, additional cooling power can be provided by incorporating the actively cooled, second cooling circuit.

In a preferred embodiment, a low-temperature radiator is arranged in the second cooling circuit. The low-temperature radiator is designed to cool the circulating coolant in the second cooling circuit by heat exchange with the surroundings of the charge air device. Farther In the first cooling circuit, an active cooling system for reducing the temperature of the coolant is arranged. In this way, depending on the required cooling capacity for cooling the coolant after it has absorbed heat from the charge air to be cooled in the indirect intercooler, be switched between the two cooling circuits.

In an advantageous development, the first cooling circuit to a cold storage, which is designed as a buffer for the circulating through the first cooling circuit coolant. In this way, the coolant can be cooled even at high cooling power to be provided.

Particularly expediently, the cold storage is essentially formed by the thermal mass of the first cooling circuit including the thermal mass of the coolant flowing through the first cooling circuit. The memory referred to as a buffer memory therefore does not have to be an additional component in this variant, but characterizes a thermal storage function of the first cooling circuit with the coolant contained therein, however this may be. In the simplest and preferred case, this can therefore be the sensitively stored refrigeration capacity of the thermal mass comprising the entire first refrigeration cycle.

According to an advantageous development, a cooling process is carried out in the active refrigeration system, by means of which the coolant can be cooled or cooled using waste heat or braking energy of a motor vehicle. In this way, a fast dischargeable refrigeration capacity can be provided for a short-time high discharge capacity that can be called up.

The desired high charge air cooling capacity is provided by the sensitive storage effect of the entire refrigeration capacity of the first cooling circuit, whereby it heats up. Particularly preferably, a large part of the thermal mass lies in the coolant which can be circulated in the first cooling circuit, since the cooling capacity contained therein can be transferred very quickly via the pumps to the indirect charge air cooler in order to achieve high cooling capacities. By absorbing heat from the charge air to be cooled, the coolant heats up.

In a particularly preferred embodiment, the active refrigeration system is arranged in a first coolant path of the first cooling circuit. In this variant, the cold storage is arranged in a fluidically parallel to the first coolant path, the second coolant path of the first cooling circuit. The active coolant system through which coolant flows in parallel counteracts too rapid heating of the coolant, but does not have to be able to supply the entire required cooling capacity.

Particularly preferably, a pump device for circulating the coolant is arranged in the first and / or in the second cooling circuit. In this way, it is ensured that for receiving heat from the indirect charge air cooler, the amount of coolant required for this purpose is circulated in the first or second cooling circuit.

In a preferred embodiment, the charge air cooling device comprises a sorption device. The sorption device is set up to cool the coolant. For this purpose, the sorption device comprises a sorption agent for adsorption and / or desorption of the coolant. Furthermore, the sorption device comprises a receiving means for condensation and / or evaporation of the working fluid. The sorption device proposed here in combination with the provision according to the invention of a first and second cooling circuit with active or passive cooling enables a particularly high variability with regard to the cooling power to be provided.

In an advantageous development, which is associated with a particularly simple construction of the sorption, the sorbent comprises activated carbon and the working fluid methanol. Alternatively, the sorbent may comprise zeolite and the working fluid may be water.

Further developments are also possible with chemisorptive material systems or thermochemical reaction systems whose transformation temperatures and pressures are in the range of application in accordance with their van't Hoff correlation. In such training, a reversible gas-solid reaction is generally used, which has a greater reaction enthalpy and, if possible, also achieves a greater specific mass conversion. An example of such reaction systems are salt hydrates, such as CaCl ₂ 2H ₂ O.

In an advantageous development, the charge air cooling device has a high-temperature cooling circuit in which a high-temperature charge air cooler cooperating with the low-temperature radiator is arranged. Thus, the removal of heat from the coolant can be ensured if this has already absorbed a large amount of heat. In this variant, the sorption device has a sorption region and a phase change region, in which a working medium which can be displaced between the two regions is present. In the sorption region, the sorbent is arranged. In the phase change region, the receiving means is arranged. The sorption area is at least one in the Sorptionseinrichtung existing and can be traversed by the coolant first fluid path in thermal operative connection. In an analogous manner, the phase change region is in thermal operative connection with at least one second fluid path present in the sorption device and permeable by the coolant.

Particularly preferably, the second fluid path is fluidically connected to the second coolant path, in which the cold accumulator is arranged.

In another preferred embodiment, the charge air cooling device has a second valve device. By means of the second valve device, the intercooler between a first and at least a second operating state is switchable. The first operating state corresponds to an activation phase in which the sorption region of the sorption device is flown with the coolant circulating in the high-temperature cooler. In the first operating state, the first fluid path is integrated into the high-temperature cooling circuit, while the second fluid path is integrated into the second cooling circuit. In the at least one second operating state, the first fluid path is integrated into the second cooling circuit, and the second fluid path is fluidically separated from the heat exchanger. The second operating state corresponds to a useful phase of the intercooler device. The sorption area is thus flowed with coolant of the second cooling circuit and cooled in this way substantially to the ambient temperature of the environment. At the same time, the phase change region is flown with the coolant of the first cooling circuit. As a result of the temperature change and the resulting adsorption, the vapor pressure of the working medium in the sorption device is lowered so much that the liquid working medium present in the phase change region evaporates, thereby extracting heat from the cryogenic cycle and cooling it as a result. The vaporized working fluid is sucked in by the sorption region maintained at a near ambient temperature and adsorbed with the release of adsorption heat. The heat of adsorption is in turn discharged to the environment via the second cooling circuit and the low-temperature radiator arranged therein.

In an advantageous development, the charge air cooling device for temporary cooling of the charge air to be cooled below the temperature of the environment to a third operating state. In the third operating state, the heat exchanger is fluidly connected to the phase change region of the sorption device by means of the first and second valve device.

Suitably, the heat exchanger is additionally fluidly connected to the cold storage in the third operating state. This causes a temporary cooling of the charge air below the ambient temperature of the environment of the intercooler.

In a further advantageous development, the charge air cooling device has a fourth operating state. In the fourth operating state, the heat exchanger is fluidly connected to the cold storage of the first cooling circuit by means of the two valve devices. On the other hand, a fluid connection of the phase change region with the heat exchanger in the fourth operating state is interrupted by the valve devices. In this way, the heat exchanger can be supplied via the cold stored in the cold storage.

Particularly expedient, the sorption region of the sorption device is integrated into the second cooling circuit in the fourth operating state by means of the second valve device.

According to an advantageous development of the heat exchanger on two fluidly separate cooling units. The two radiator units are designed in such a way that the second radiator unit can be attached or attached downstream of the first radiator unit and upstream of the internal combustion engine to be supplied with intercooler when flowing through with intercooler air. In this variant, the first cooler unit is integrated into the second cooling circuit. In this way, it is ensured that not the entire cooling load for the charge air to be cooled is transferred to the second cooling circuit, but is first cooled by the low-temperature radiator.

Particularly preferably, the second cooler unit can be integrated by means of the first valve device optionally in the first or second cooling circuit. This measure allows, depending on the requirement, a variation of the required cooling capacity.

In another preferred embodiment, the first valve device is designed as a 4-2-way valve, which is adjustable between a first and a second adjustment position. In the first adjustment position, the first valve device connects the first cooling circuit with an input connection of the heat exchanger and the first cooling circuit with the second cooling circuit. In the second adjustment position, the first valve device connects the second cooling circuit to the input connection of the heat exchanger and separates the first cooling circuit fluidically from the second cooling circuit and from the high-temperature cooling circuit.

Particularly suitably, the two cooler units are fluidly connected in series with each other. This allows an extension of the provided by the indirect intercooler cooling path.

Preferably, the second cooling circuit merges fluidly into the high-temperature cooling circuit at a branch point.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawing and from the associated description of the figures with reference to the drawing.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

It show, each schematically:

1 the construction of an intercooler according to the invention in a block diagram,

2 a detailed view of the block diagram of 1 .

3 the intercooler of the 2 in an activation state,

4 . 5 the charge air cooling device in further operating states,

6 . 7 a first variant of the intercooler of the 2 to 5 in which the indirect intercooler has two separate radiator units.

8th . 9 a second variant of the intercooler of the 2 to 5 with a 4-2-way valve.

1 shows a block diagram of the structure of an intercooler according to the invention 1 for a fresh air system of an internal combustion engine. The intercooler 1 includes a heat exchanger 2 which is a majority of in 1 not shown in detail coolant paths 3 having. The coolant paths 3 of the heat exchanger 2 are by means of a valve device 4 optionally in an actively cooled first cooling circuit 5a or in a passively cooled second cooling circuit 5b involved.

The intercooler 1 also has a high temperature cooling circuit 13 in which circulates a coolant whose temperature is higher than the temperature of the coolant in the first and second cooling circuit 5a . 5b ,

For circulating the coolant in the first cooling circuit 5a serves a pumping device 11 which is preferably downstream of the heat exchanger 2 in the first cooling circuit 5a is arranged. The pumping device 11 can be realized as a centrifugal pump. The cold storage 9 can essentially by the thermal mass of the first cooling circuit 5a including the thermal mass of the coolant flowing through the first cooling circuit.

Corresponding 1 is in the second cooling circuit 5b a low temperature cooler 6 arranged, which for cooling the in the second cooling circuit 5b circulating coolant through heat exchange with the environment 7 of the low temperature cooler 6 is trained. The heat exchange with the environment 7 can from one in 1 only schematically indicated fan 19 get supported. In the first cooling circuit 5a In contrast, it is an active refrigeration system 8th arranged for cooling the coolant. In the first cooling circuit 5a is also a cold storage 9 present as a buffer for that through the first cooling circuit 5a circulating coolant is set up.

Like the block diagram of 1 clearly demonstrated, is the active refrigeration system 8th in a first coolant path 10a of the first cooling circuit 5a and the cold storage 9 in a fluidic parallel to the first coolant path 10a switched second coolant path 10b of the first cooling circuit 5a arranged. In the active refrigeration system 8th a cooling process is carried out, by means of which the coolant is cooled using waste heat or braking energy of a motor vehicle. In the example of 1 is the valve device 4 set so that the heat exchanger 2 in the first cooling circuit 5a is integrated.

2 shows a more detailed representation of the block diagram of 1 , In the example of 2 is the valve device 4 set so that the heat exchanger 2 in the second cooling circuit 5b is integrated. It can also be seen that the intercooler 1 a sorption device 12 includes. The sorption device 12 serves for cooling the coolant and for this purpose comprises a sorbent for adsorption and / or desorption of the coolant and a receiving means for condensation and / or evaporation of the working fluid. The sorbent is in the sorbent area 16 arranged and the receiving means is in the phase change region 17 arranged. The sorbent may be off Activated carbon or zeolite or comprise one of them. The receiving means may have a good thermal conductivity capillary structure for condensation, absorption and local fixation and a re-evaporation of working fluid such. For example, methanol and / or water.

The sorption device comprises a sorption housing 14 which has a housing interior 15 limited. The housing interior 15 is in a sorption area 16 and a phase change region 17 divided. In the housing interior 15 is also a working medium 18 existing between the two areas 16 . 17 is shifted cyclically.

The sorption area 16 is at least one in the sorption 12 existing and traversed by the coolant first fluid path 18a in thermal active connection. The phase change range is corresponding 17 with at least one in the sorption device 12 existing and traversed by the coolant second fluid path 18b in thermal active connection.

The heat exchanger 2 the intercooler 1 is about the valve device 4 , which is designed as a 3/2-way switching valve, alternatively with the first cooling circuit 5a or the second cooling circuit 5b connectable. In this way, at full engine power, the heat exchanger 2 used internal combustion engine 23 a charge air freezing to preferably well below the temperature of the environment 7 to enable. The sorption device is used 12 for cyclical cooling of the first cooling circuit 5a whose thermal mass is dimensioned so that the stored therein sensitive "cold energy" is sufficient to the heat exchanger 2 to provide sufficiently cool coolant for at least one full-load acceleration process.

Corresponding 2 has the intercooler 1 another, second valve device 20 on, by means of which the sorption 12 the intercooler 1 can be switched between a first and a second operating state. In the first operating state, the first fluid path is 18a in the high-temperature refrigeration cycle 13 switched, and the second fluid path 18b is in the second cooling circuit 5b connected. This scenario is in 2 shown. As 2 reveals possesses the valve device 20 for switching between the two operating states, two inlet-side valve elements 21a . 21b and two outlet-side valve elements 22a . 22b , In the in 2 shown first operating state provide the first inlet-side valve element 21a and the first outlet-side valve element 22a for fluid communication between the first fluid path 18a and the high temperature refrigeration cycle 13 , In contrast, interrupt the valve elements 21a . 22a a fluid connection of the first fluid path 18a with the second cooling circuit 5b in which the low-temperature cooler 6 is arranged.

The second inlet-side valve element 21b and the second exhaust-side valve element 22b provide fluid communication between the second fluid path 18b and the second cooling circuit 5b in which the low-temperature cooler 6 is arranged. The first operating state of the active cooling system 8th corresponds to an activation phase in which the sorption 16 with the in the high temperature cooler 12 circulating coolant (see arrows 50 in 2 ) is flowed. At the same time, the phase change range with that in the second cooling circuit 5b with the low temperature radiator 6 circulated coolant flowed (arrows 51 ). In this way, the working fluid of the sorption device is desorbed by absorbing heat from the sorption region and in the phase change region 17 condensed. The resulting heat of condensation is via the second cooling circuit 5b with the low temperature cooler 6 dissipated.

In the second operating state, which is a useful phase of the intercooler device 1 corresponds and in 3 is shown, is the first fluid path 18a in the second cooling circuit 5b switched, in which the low-temperature cooler 6 is arranged. The second fluid path 18b is fluidly isolated from the heat exchanger and instead with the second coolant path 10b connected, in which the cold storage 9 is arranged. This operating state is switched when the passive intercooling via the second cooling circuit 5b sufficient, so no full-load acceleration phase is required by the internal combustion engine.

In the in 3 shown second operating state provide the first inlet-side valve element 21a and the first outlet-side valve element 22a for fluid communication between the first fluid path 18a and the second cooling circuit 5b with the low temperature cooler 6 , In contrast, the valve elements provide 21b . 22b for a fluid connection of the second fluid path 18b with the cold storage 9 and a circulation of the coolant by means of the pumping device 11

The sorption area 16 This is done with coolant from the second cooling circuit 5b flows and in this way essentially to the temperature of the environment 7 cooled. At the same time the phase change range 17 with the coolant of the first cooling circuit 5a flow-type. Due to the temperature change and the resulting adsorption of the fluid pressure of the working fluid in the sorption 12 so strong lowered that in the phase change region 17 existing liquid working fluid evaporates and thereby removes heat from the cryogenic cycle and thereby cools it. The vaporized working fluid is held by the sorption area kept at near ambient temperature 16 sucked and adsorbed with release of adsorption. The heat of adsorption is in turn via the second cooling circuit 5b and the low temperature radiator disposed therein 6 to the environment 7 dissipated.

In 3 So is a switching position of the valve device 4 shown in which the heat exchanger 2 in a classic way with the ambient temperature close to ambient 7 cooled coolant of the second cooling circuit 5b is flowed through and at the same time the first temperature circuit 5a with the cold storage 9 to a temperature below the ambient temperature of the environment 7 is cooled. Also at the in 2 shown activation phase is the first valve device 4 in the same position as in the use phase of the 3 ,

A temporary cooling of the charge air under the temperature of the environment 7 the intercooler 1 takes place in a third operating state of the intercooler 1 according to the 4 and 5 by an adjustment of the first valve device 4 such that the heat exchanger 2 directly with the first cooling circuit 5a is connected.

In the switching position of the two valve devices 4 . 20 corresponding 4 is the still unaffected cycled sorption 12 of the first cooling circuit 5a in the utility process. The pumping device 11 promotes this through the indirect intercooler 2 heated coolant through both the phase change region 17 the sorption as well as the cold storage 9 ,

In the event that the sorption 12 just in the activation process according to 2 is the intercooler 1 in a fourth operating state in the switching position of the two valve devices 4 . 20 to 5 operated. This differs from the switch position accordingly 4 in that the fluid connection of the phase change region 17 with the heat exchanger 2 through the valves 21a . 21b . 22a . 22b is interrupted and the heat exchanger 2 fluidic with the cold storage 9 of the first cooling circuit 5a connected is. This means that the heat exchanger 2 exclusively from the cold storage 9 sensibly stored cold is supplied. As 5 can be further seen, in the fourth operating state of the sorption 16 the sorption device 12 by means of the second valve device in the high-temperature cooling circuit 13 involved.

In 6 is a variant of the example of 2 to 5 shown. It differs from the system proposed above in that the heat exchanger 2 two fluidically separate radiator units 2a . 2 B having separate coolant connections.

In operation as part of a fresh air system of the internal combustion engine 23 is the second cooler unit 2 B when flowing with charge air downstream of the first cooler unit 2a and upstream of the internal combustion engine 23 arranged what is in 6 by the charge air denoting arrows 52 is reproduced.

Corresponding 6 is the first cooler unit 2a of the heat exchanger 2 stationary, ie permanently in the second cooling circuit 5b involved. The second cooler unit 2 B is, however, with the help of the first valve device 4 optionally in the first or second cooling circuit 5a . 5b includable. In the scenario of 6 is an integration of the second cooler unit in the second cooling circuit 5b shown.

The 7 shows a switching position of the first valve device 4 in which the second cooler unit 2 B in the first cooling circuit 5a is involved.

The division of the heat exchanger 2 in two cooler units 2a . 2 B causes not the entire cooling load of the charge air to be cooled on the first cooling circuit 5a is transferred, but the resulting at high temperature cooling load first of the second cooling circuit 5b arranged low temperature cooler 6 to the environment 7 is dissipated.

It should be mentioned at this point that as a further embodiment, a not-shown in the example of the figures trisection of the heat exchanger 2 can be provided with three cooler units. In this variant, a charge air side is first flowed through by the radiator unit from the high-temperature cooling circuit 13 cooled coolant, the second radiator unit of the coolant of the second cooling circuit 5b and the third cooler unit, if necessary, of the coolant of the first cooling circuit 5a flows through. Thus, the heat loads of the two cooling circuits 5a . 5b minimized.

A proposal variant with less Verschaltungsaufwand is in the 8th shown. This is characterized by the fact that the heat exchanger 2 is designed as a so-called countercurrent or cross-countercurrent heat exchanger and thereby only one input terminal 25a and an output terminal 25b needed. In this case, the first valve device 4 as a 4-2-way valve 26 executed, depending on the cooling requirement of the Internal combustion engine 23 between a normal charge air cooling mode and a charge air freezer mode can be adjusted. For this purpose, the first valve device is as a 4-2-way valve 26 formed, which is adjustable between a first and a second adjustment position.

In 8th shows the charge air freezer mode, in which the 4-2-way valve 26 located in its first adjustment position. The first valve device 4 connects in the first adjustment position the first cooling circuit 5a with an input connection 25a of the heat exchanger 2 and the first cooling circuit 5a with the second cooling circuit 5b , In this mode, the pump device promotes 11 corresponding 8th cooled coolant of the first cooling circuit 5a in a charge air exit side area 28 of the heat exchanger 2 , which is in countercurrent to the charge air to the charge air outlet side area 27 increasingly heated. On the outlet side, the coolant has such a high temperature that the heat initially exceeds that in the high-temperature cooling circuit 13 arranged high-temperature cooler 30 can be dissipated, as in 8th indicated on the air side in the cooling module of the vehicle behind the low-temperature cooler 6 is arranged.

A partial flow of the high-temperature cooler 30 Pre-cooled coolant is in a branch point 29 in the second cooling circuit 5b branched off and in the low temperature cooler 6 as close as possible to the temperature of the environment 7 zoom cooled. The second cooling circuit 5b So it's in a branch point 29 fluidic with the high temperature refrigeration cycle 13 connected. Finally, the coolant and finally again via the 4-2-way valve 26 back in the first cooling circuit 5a recycled.

The 9 shows the switching position as a 4-2-way valve 26 realized valve device 4 in normal charge air cooling mode. In this mode is the 4-way valve 26 in a second adjustment position. In the second adjustment position, the first valve device connects 4 the second cooling circuit 5b with the input connector 25a of the heat exchanger 2 and separates the first cooling circuit 5a fluidic from the second cooling circuit 5b and the high-temperature refrigeration cycle 13 ,

In this mode, the heat exchanger 2 via the 4-2-way valve 26 and the second cooling circuit 5b with coolant from the low-temperature cooler 6 acts and allows a conventional cooling of the charge air to a temperature level above the temperature of the environment 7 , In this mode is the first cooling circuit 5a from the remaining circuits 5b . 13 decoupled and can be cooled down well below the ambient temperature for the next frozen phase by the refrigeration process again.

As in the variant of 8th and 9 a high heating of the coolant in the heat exchanger 2 is allowed, the coolant side of the heat exchanger can 2 be designed for relatively small volume flows. So that there are no large temperature gradients transverse to the charge air flow direction, a pure countercurrent construction with great depth in the direction of the charge air flow and a small end face perpendicular is particularly advantageous.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010062714 A1 [0008]
• DE 102011003664 A1 [0009]

Claims (22)

Intercooler ( 1 ) for a fresh air system of an internal combustion engine of a motor vehicle, - with a heat exchanger ( 2 ), which by means of a (first) valve device ( 4 ) in an actively cooled first cooling circuit ( 5a ) and / or in a passively cooled second cooling circuit ( 5b ) einbindbar or is involved. Charge air cooling device according to claim 1, characterized in that - in the first cooling circuit ( 5a ) an active refrigeration system ( 8th ) is arranged to reduce the temperature of the coolant, and that - in the second cooling circuit ( 5b ) a low temperature cooler ( 6 ), which is used for cooling the in the second cooling circuit ( 5b ) circulating coolant by heat exchange with the environment ( 7 ) the intercooler ( 1 ) is trained. Charge air cooling device according to claim 1 or 2, characterized in that the first cooling circuit ( 5a ) a cold storage ( 9 ), which serves as a buffer for the flow through the first cooling circuit ( 5a ) is formed circulating coolant. Charge air cooling device according to claim 2 or 3, characterized in that the active refrigeration system ( 8th ) in a first coolant path ( 10a ) of the first cooling circuit ( 5a ) is arranged and the cold storage ( 9 ) in a fluidic parallel to the first coolant path ( 10a ) connected second coolant path ( 10b ) of the first cooling circuit ( 5a ) is arranged. Charge air cooling device according to one of the preceding claims, characterized in that in the first and / or in the second cooling circuit ( 5a . 5b ) a pumping device for circulating the coolant ( 11 ) is arranged. Charge air cooling device according to one of claims 2 to 5, characterized in that the cold storage ( 9 ) substantially by the thermal mass of the first cooling circuit ( 5a ) including the thermal mass of the first cooling circuit ( 5a ) flowing coolant is formed. Intercooler according to one of claims 3 to 6, characterized in that in the active refrigeration system ( 8th ), a cooling process is carried out, by means of which the coolant is coolable or cooled using waste heat or braking energy of a motor vehicle. Charge air cooling device according to one of the preceding claims, characterized in that the charge air cooling device ( 1 ) a sorption device ( 12 ), which is adapted to cool the coolant and for this purpose comprises a sorbent for adsorption and / or desorption of the coolant and a receiving means for condensation and / or evaporation of the coolant. Charge air cooling device according to claim 8, characterized in that - the sorbent activated carbon and the working fluid comprises methanol, or that - the sorbent zeolite and the working fluid comprises water. Charge air cooling device according to claim 8 or 9, characterized in that the charge air cooling device ( 1 ) a high-temperature cooling circuit ( 13 ) in which one with the low-temperature radiator ( 6 ) cooperating high temperature intercooler ( 30 ) is arranged, wherein in the high-temperature refrigeration cycle ( 13 ) circulates a coolant whose temperature is higher than the temperature of the coolant in the low-temperature radiator ( 6 ), - the sorption device ( 12 ) comprises a sorption area and a phase change area, in which one between the two areas ( 16 . 17 ) is present displaceable working medium, wherein in the sorption ( 16 ) the sorbent and in the phase change region ( 17 ) the receiving means is arranged, - whereby the sorption area ( 16 ) with at least one in the sorption device ( 12 ) present and can be flowed through by the coolant first fluid path ( 18a ) is in thermal active connection and the phase change region ( 17 ) with at least one in the sorption device ( 12 ) and can be flowed through by the coolant second fluid path ( 18b ) is in thermal operative connection. Charge air cooling device according to claim 10, characterized in that the second fluid path ( 18b ) fluidically with the second coolant path ( 10b ), in which the cold storage ( 9 ) is arranged. Charge air cooling device according to claim 10 or 11, characterized in that - the charge air cooling device has a (second) valve device, by means of which the charge air cooling device ( 1 ) is switchable between a first and at least a second operating state, - wherein in the first operating state the first fluid path ( 18a ) in the high-temperature cooling circuit ( 13 ) and the second fluid path ( 18b ) in the second cooling circuit ( 5b ), wherein in the at least one second operating state the first fluid path ( 18a ) in the second cooling circuit ( 5b ) and the second one Fluid path ( 18b ) fluidly from the heat exchanger ( 2 ) is disconnected. Charge air cooling device according to claim 12, characterized in that the charge air cooling device ( 1 ) for temporary cooling of the charge air to be cooled below the temperature of the environment has a third operating state, in which the heat exchanger ( 2 ) by means of the first and second valve device ( 4 . 20 ) fluidically with the phase change region ( 17 ) of the sorption device ( 12 ) connected is. Charge air cooling device according to claim 13, characterized in that the heat exchanger ( 2 ) in the third operating state additionally fluidically with the cold storage ( 9 ) connected is. Charge air cooling device according to claim 13 or 14, characterized in that the charge air cooling device ( 1 ) has a fourth operating state in which the heat exchanger ( 2 ) by means of the two valve devices ( 4 . 20 ) fluidly with the cold storage ( 9 ) of the first cooling circuit ( 5a ) and a fluid connection of the phase change region ( 17 ) with the heat exchanger ( 2 ) through the valve devices ( 4 . 20 ) is interrupted. Charge air cooling device according to claim 15, characterized in that in the fourth operating state of the sorption ( 16 ) of the sorption device ( 12 ) by means of the second valve device ( 20 ) in the second cooling circuit ( 5b ) is involved. Charge air cooling device according to one of the preceding claims, characterized in that the heat exchanger ( 2 ) two fluidically separated cooling units ( 2a . 2 B ), in such a way that the second cooling unit ( 2 B ) when flowing through with charge air downstream of the first cooler unit ( 2a ) and upstream of the charge air to be supplied to internal combustion engine ( 23 ) is attachable or attached, wherein the first cooler unit ( 2a ) in the second cooling circuit ( 5b ) is involved. Intercooler according to claim 17, characterized in that the second cooler unit ( 5b ) by means of the first valve device ( 4 ) optionally in the first or second cooling circuit ( 5a . 5b ) is einbindbar. Charge air cooling device according to claim 17 or 18, characterized in that the first valve device as a 4-2-way valve ( 26 ) is formed, which is adjustable between a first and a second adjustment position, - wherein the first valve means ( 4 ) in the first adjustment position the first cooling circuit ( 5a ) with an input terminal 25a of the heat exchanger ( 2 ) and the first cooling circuit ( 5a ) with the second cooling circuit ( 5b ), - wherein the first valve device ( 4 ) in the second adjustment position the second cooling circuit ( 5b ) with the input terminal ( 25a ) of the heat exchanger ( 2 ) and the first cooling circuit ( 5a ) fluidically from the second cooling circuit ( 5b ) and of the high temperature refrigeration cycle ( 13 ) separates. Charge air cooling device according to claim 19, characterized in that the two cooler units ( 5a . 5b ) are fluidly connected in series with each other. Charge air cooling device according to one of the preceding claims, characterized in that the second cooling circuit ( 5b ) in a branch point 29 fluidically into the high-temperature cooling circuit ( 13 ) passes over. Fresh air system with a charge air cooling device ( 1 ) according to one of the preceding claims, characterized in that the heat exchanger ( 2 ) the intercooler ( 1 ) is integrated in a fresh air line of the fresh air system.

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