DE102010015106B4 - Coolant circuit for an internal combustion engine of a motor vehicle - Google Patents

Abstract

Coolant circuit (1) for an internal combustion engine (2) of a motor vehicle, comprising a main circuit (3) with a main heat exchanger flow (6) upstream and a main heat exchanger return (7) downstream of a main heat exchanger (5), a heating circuit (4) with a Heating heat exchanger feed (9) upstream and a heating heat exchanger return (10) downstream of a heating heat exchanger (8), and an internal combustion engine (2) with at least one cylinder head (11), a cylinder crankcase (12), and at least one exhaust gas-carrying component (13, 14), which are beauschlagbar with coolant from the coolant circuit (1) and fluidly connected to each other for this purpose, wherein a main coolant pump (15) in the main circuit (3) and a secondary coolant pump (16) in the heating circuit (4) are arranged the heating heat exchanger return (10) on the cylinder head (11) or an exhaust gas-carrying component (13, 14), the Hauptwärmeta the main heat exchanger inlet (6) and the heater core (9) ) have a common portion (17), characterized in that the exhaust gas-carrying components (13, ...

Description

Coolant circuit for an internal combustion engine of a motor vehicle, wherein the internal combustion engine for the purpose of heat dissipation with coolant from a plurality of partial circuits having coolant circuit can be acted upon.

Such coolant circuits are used in motor vehicle construction to dissipate the waste heat generated during operation of the internal combustion engine to the ambient air with the aid of heat exchangers, or to use for targeted heating of other components of the motor vehicle.

The DE 195 06 935 C1 describes for this purpose a coolant circuit for an internal combustion engine of a motor vehicle with an engine cooling circuit and a heating circuit in which a heating system assigned to a heating system for an interior of the motor vehicle is arranged. In this case, the heating circuit is designed as a circuit independent of the engine cooling circuit and provided with an electric pumping device. An inlet and a return of the heating circuit are integrated in a common, arranged directly on an engine block of the internal combustion engine, connecting piece.

A disadvantage is that the formation of the connecting piece as an integrated connecting piece, with inlet and outlet of the construction of nested tubes, has difficulties in terms of manufacturability and tightness. In addition, the heating circuit can communicate only indirectly via the internal combustion engine with the engine cooling circuit, resulting in disadvantages in the coolant distribution between the circuits.

The generic DE 10 2007 027 719 A1 shows an internal combustion engine with a heating circuit and a cooling circuit, wherein the internal combustion engine has at least one cylinder with a head portion and a foot portion and the cooling circuit has a portion extending from the foot portion to the head portion. The heating circuit has a portion that extends from one point in the head area to another, adjacent point in the head area, in that the head area has at least one Heizmittelzuführanschluss and at least one Heizmittelablaufanschluss. In the cooling circuit, the coolant is circulated through a coolant pump, while in the heating circuit, the coolant is circulated through a heating medium pump. In addition, the heat exchanger area of a supercharger, in particular an exhaust gas turbocharger, is integrated in the heating circuit.

The disadvantage here is that four connections for tubing of the coolant circuits must be provided and sealed to the internal combustion engine, which is complicated and expensive. Furthermore, the heating circuit and the cooling circuit can only exchange coolant indirectly via the internal combustion engine, whereby there is no flexibility in the application.

The DE 100 47 810 A1 discloses a heating circuit with an auxiliary heating device for motor vehicles, which is part of a separate short circuit. The short circuit is switchable by means of a switching device in the heating circuit. As an auxiliary heater, an exhaust system of the engine of the motor vehicle is used, from which the exhaust heat is transferred into the heating circuit.

The DE 10 2008 007 766 A1 shows an apparatus for cooling an internal combustion engine, which is provided with a refrigerant circuit having coolant circuit and with an electromechanical assembly and serves to switch different operating conditions of the refrigerant circuit.

The DE 10 2006 044 680 A1 describes an embodiment for the integration of exhaust gas turbochargers in the cooling circuits of internal combustion engines. In this case, the internal combustion engine comprises at least one cylinder bank, and a cooler, which are part of a driven by the pump cooling circuit. An auxiliary pump connected to the cooling circuit serves to simultaneously convey a cooling fluid through the turbocharger and the cylinder bank.

Object of the present invention is therefore to provide a coolant circuit for an internal combustion engine of a motor vehicle, in which a heating circuit and a main circuit can be provided inexpensively and, if necessary, operated independently, with the heating circuit and the internal combustion engine to warm up very quickly after a cold start of the engine.

This object is solved by the features of patent claim 1.

A coolant circuit for an internal combustion engine of a motor vehicle, comprising a main circuit with a main heat exchanger upstream and a main heat exchanger return downstream of a main heat exchanger, a heating circuit with a heater core and a heat exchanger return downstream of a heat exchanger, and an internal combustion engine with at least one cylinder head, a cylinder crankcase, and at least one exhaust gas component, which are beauschlagbar with coolant from the coolant circuit and fluidly connected to each other for this purpose, wherein a main coolant pump in the main circuit and a secondary coolant pump are arranged in the heating circuit, wherein the heating heat exchanger return the cylinder head or an exhaust gas carrying member, the main heat exchanger flow to the cylinder head or the cylinder crankcase and the main heat exchanger return is connected to the cylinder crankcase and wherein the main heat exchanger flow and the heater core have a common portion.

By having the main heat exchanger feed and the heater core, a common portion in which engine coolant may selectively flow to either the main heat exchanger, the heater core, or both, together with the heater core return and main heat exchanger return ports are in total to provide only three connections for the tubing on the internal combustion engine. As a result, a coolant circuit according to the invention can be provided more favorably than a coolant circuit according to the prior art. Another advantage is the flexible usability of the coolant circuit. Thus, the heating circuit provided with a secondary coolant pump can be operated independently of the main circuit, whereby also shortly after start-up or after switching off the internal combustion engine of this heated coolant to the heating heat exchanger can be provided. This independent of the main circuit heating operation increases the comfort of the vehicle occupants, which can be supplied earlier and longer heated by the heater core fresh air. The integration of exhaust gas-carrying components in the heating heat exchanger return leads to a particularly rapid heating of the coolant in the heating circuit, without the need for coolant from the cylinder crankcase must be used. The coolant in the cylinder crankcase can heat up independently of the operation of the heating circuit and thus reaches its optimum operating temperature faster, which reduces the friction of the arranged in the cylinder crankcase working cylinder of the internal combustion engine. Of course, the enumeration of the possible subcircuits of the coolant circuit is not limited to the main circuit and the heating circuit. Thus, in principle, further partial circuits, for example, for an oil cooler, an exhaust gas cooler or a fresh gas cooler, einbindbar in the coolant circuit shown. The internal combustion engine also contains more than the enumerated components and can be of various types, for example in a V-arrangement with two cylinder heads or in a W arrangement with three cylinder heads. Furthermore, a plurality of exhaust gas-carrying components can be arranged on it and be acted upon by coolant.

The exhaust gas-carrying components are designed as integrated exhaust manifold and exhaust gas turbocharger. An integrated exhaust manifold is formed on the cylinder head and usually has a double outer wall, wherein the cavity formed thereby can be filled with coolant. The turbocharger is usually downstream of the exhaust manifold and flanged to this. This can also be acted upon for cooling the shaft bearings with coolant, wherein preferably there is no internal fluidic connection for the exchange of coolant between the exhaust manifold and turbocharger. The heating heat exchanger return line is divided at a branch point into a first partial return, in which the exhaust manifold and the cylinder head are integrated, and a second partial return, in which the exhaust gas turbocharger is integrated, wherein the second partial return, bypassing the internal combustion engine opens into the main circuit , Exhaust gas turbocharger and exhaust manifold are supplied via separate supply lines with coolant from the heater core return line. For this purpose, the tubing of the heating heat exchanger return line is divided at a branch point, wherein a first partial return flows directly into the exhaust manifold and a second partial return includes the exhaust gas turbocharger. The second partial return can also open into the internal combustion engine or one of its parts, but preferably bypasses the second partial return the engine and flows into the main circuit, in particular the main heat exchanger flow. As a result, the entry of waste heat from the exhaust-gas-carrying components is maximized in the heating circuit, while the internal combustion engine does not or only rarely with coolant flows through it.

In a preferred embodiment, the main heat exchanger flow is connected to the cylinder crankcase. The connection of the main heat exchanger flow to the cylinder crankcase is preferably in a geodetically upper region near the cylinder head above.

In a preferred embodiment, the main coolant pump is arranged in the main heat exchanger return, wherein the main heat exchanger return is shut off by a first actuator. By the first control element, the main heat exchanger return flow in the cylinder crankcase can either close or open. A closed main heat exchanger return has a positive effect on a particularly fast Heating of the coolant in the internal combustion engine, in particular in the cylinder crankcase from. Due to the common arrangement of the first control element and the main coolant pump in the main heat exchanger return line, the flow rate of the main coolant pump can be regulated indirectly.

In a preferred embodiment, the secondary coolant pump is arranged in the heating heat exchanger flow, wherein the heating circuit can be shut off by a check valve. The check valve can open or close the heating circuit depending on the current heating demand. For example, when the passenger compartment heater is off, it is not necessary to circulate the coolant through the heater core. The lack of coolant circulation in the heating circuit, however, promotes faster heating of the coolant in the internal combustion engine. For this purpose, the secondary coolant pump should preferably be designed as an electrically drivable secondary coolant pump which can be switched on or off as required.

In a preferred embodiment, the main heat exchanger flow is connected to the cylinder crankcase that the coolant located in the cylinder crankcase is mixed as little as possible with the main heat exchanger return flow and the open heating circuit. The main heat exchanger flow is so connected to the cylinder crankcase that an overflow of the cylinder head with coolant from the heater core return is possible in which there is little or no mixing of the coolant in the cylinder head with the cylinder crankcase. When the main heat exchanger return line is closed, it is thus possible to carry out a coolant circulation in the heating circuit and at the same time "stop" the coolant in the cylinder crankcase for faster heating.

In a preferred embodiment, a check valve is arranged in the first partial return. The non-return valve arranged in the first partial return of the heating heat exchanger return upstream of the exhaust manifold prevents undesired backflow of coolant from the cylinder head or the exhaust manifold to the heater core.

In a preferred embodiment, the first actuator and a second actuator are arranged in a common housing and together form a rotary valve, wherein the first and the second actuator are hollow and each having a plurality of radial openings, which upon rotation of the first and / or the second Control element can be overlapped with correspondingly corresponding openings in the housing to form a flow path for the coolant, wherein the centrifugal pump designed as a main coolant pump sucks the coolant axially from the second actuator and promotes radially to the first actuator. For this purpose, the first and the second adjusting element are preferably designed as pipe sections which are rotatable about an axis of rotation and have openings in their lateral surface. The housing has corresponding openings, which are each associated with the connections of the Kühlkreislaufverschlauchung. The control elements are rotatable in dependence on each other, so that a defined flow path can be adjusted by the rotary valve by a variable overlap of the openings in the actuator with the associated openings in the housing. The main coolant pump is preferably designed as a centrifugal pump and arranged with its suction side axially aligned with the second actuator, while the first actuator is disposed on the radial pressure side, so that the main coolant pump sucks coolant from the second actuator and promotes to the first actuator.

In a preferred embodiment, the main heat exchanger flow has a branch, which opens into the second control element, wherein the branch and the main heat exchanger return flow through the second actuator are fluidically connected, and wherein the second partial return of the heating heat exchanger return flows on the suction side of the main coolant pump , The rotary valve formed in this manner from the first and the second control element is preferably switched so that after the startup of the internal combustion engine below a predetermined temperature limit of the coolant or after stopping the engine with already heated coolant, first the first actuator the Hauptwärmetauscher- Return line shut off. The second actuator is rotated so that coolant from the second part return of the heater core return can get over the, departing from the common portion, branch in the common section, but can not penetrate via the main heat exchanger return from the main heat exchanger coming coolant in the second actuator , If heated coolant is needed on the heater core during this phase, the check valve will open the heater core, allowing the secondary coolant pump to circulate the coolant through the heater loop. In this case, the coolant is conveyed by the rapidly warming exhaust gas turbocharger and the exhaust manifold, so that the heater core can be supplied comparatively quickly with sufficiently warm coolant while the coolant in the cylinder crankcase is mixed as little as possible and thus to achieve the friction optimum in the cylinder crankcase cylinder in turn fast can warm up. Characterized in that in the heating circuit preferably those components of the internal combustion engine are involved, which heat up very quickly and have to give off much heat, the non-flow through the cylinder crankcase can be maintained much longer. With increasing coolant temperature in the cylinder crankcase, it is advantageous for achieving a uniform heating of the coolant contained therein to produce a weak flow of coolant in the cylinder crankcase. In order to still maintain a rapid heating of the coolant in the cylinder crankcase, opens the first actuator (intermittent), while the second actuator produces a flow path for the coolant from the branch from the common portion to the main coolant pump, whereby the main coolant pump, the coolant from the cylinder crankcase through the second Control element and the first control element can recirculate back into the cylinder crankcase. Characterized in that the second control element further prevents a possible ingress of coolant from the main heat exchanger in the main coolant pump, the main heat exchanger is not flowed through, which positively influences the warm-up phase of the internal combustion engine. If cooling of the same is required in a subsequent operating phase after reaching the desired operating temperature of the internal combustion engine or of the coolant, the first control element opens the main heat exchanger return, while the second control element decouples the branch and continuously opens the main heat exchanger return from the main heat exchanger to the cylinder crankcase so that the main coolant pump can generate a coolant circulation between the engine and the main heat exchanger. In this phase, the secondary coolant pump can be switched off at low coolant demand on the heater core, since the main coolant pump alone can represent a sufficient circulation in the main circuit and heating circuit.

In a preferred embodiment, the second actuator and the main coolant pump may form part of the heater core. In this alternative embodiment, parts of the second actuator and the main coolant pump may also belong to the heater core at the same time as the main heat exchanger return. In this case, the wiring harness leading to the heating heat exchanger branches off between the coolant pump and the first control element.

The rotary valve can also be used to set different coolant temperatures in the cylinder head and cylinder crankcase by the coolant flows are influenced by targeted switching of the respective heat exchanger forward and backward. Instead of a rotary valve analogous other control elements can be used, so it is conceivable, for example, to replace the first control element by a switchable main coolant pump. The use of suitable control elements and adapted tubing is at the discretion of the skilled person.

Further details, features and advantages of the invention will become apparent from the following description of a preferred embodiment with reference to the drawings.

Show:

1 a schematic view of a first embodiment of a coolant circuit according to the invention;

2 in a schematic view of a second embodiment of a coolant circuit according to the invention.

According to 1 has a coolant circuit 1 for an internal combustion engine 2 a motor vehicle, several partial circuits, wherein in the present case only one main circuit 3 and a heating circuit 4 are shown. The internal combustion engine 2 consists essentially of a cylinder crankcase 12 , which includes the displacement of the working cylinder, a cylinder head 11 , which includes, inter alia, required for the mixture supply and removal for the displacement devices, one in the cylinder head 11 integrated exhaust manifold 13 , through which the hot combustion exhaust gases can escape, as well as the exhaust manifold 13 downstream exhaust gas turbocharger 14 , which uses the remaining exhaust gas energy for the compression of fresh gas. The cylinder head 11 , the exhaust manifold 13 , the exhaust gas turbocharger 14 and the cylinder crankcase 12 are beauschlagbar each with coolant, wherein for the cylinder head 11 , the exhaust manifold 13 and the cylinder crankcase 12 by internal fluidic connections with each other a coolant exchange is possible. The main circuit 3 contains a main heat exchanger 5 , which has a main heat exchanger lead 6 and via a main heat exchanger return 7 to the cylinder crankcase 12 connected. In the main heat exchanger return 7 is also a main coolant pump 15 arranged, preferably as by the internal combustion engine 2 driven centrifugal pump with axial suction side and radial pressure side is formed. The heating circuit 4 has a heating heat exchanger 8th on, which is traversed by air for the passenger compartment of the motor vehicle, so that a heat exchange between coolant and this air takes place. The heating heat exchanger 8th is via a heating heat exchanger flow 9 to the cylinder crankcase 12 connected. In the heater core 9 is further a secondary coolant pump 16 , which is preferably electrically operated and a coolant circulation in the heating circuit 4 can generate. The heating circuit 4 can optionally by a check valve 20 in the heating heat exchanger flow 9 upstream of the secondary coolant pump 16 to be interrupted. The heating heat exchanger return 10 meanwhile shares at a branching point 22 on a first partial return 10a and a second partial return 10b on. The first partial return 10a flows into the exhaust manifold 13 and has a check valve 21 on, that is a backflow from the exhaust manifold 13 to the heating heat exchanger 8th in derogation. The turbocharger 14 is in the second partial return 10b involved. The heating heat exchanger flow 9 and the main heat exchanger feed 6 have starting from a common connection to the cylinder crankcase 12 a common section 17 , The connection for the common section 17 on the cylinder crankcase 12 is arranged so that coolant from the heater core return 10 the cylinder head 11 flow through and into the common section 17 can flow without dealing with the coolant in the cylinder crankcase 12 noticeably to mix. This is preferably achieved by the connection of the main heat exchanger flow 6 near the cylinder head 11 is arranged. For controlling and regulating the coolant circuit 1 are a first 18 and a second actuator 19 provided, which together form a rotary valve. The two control elements 18 and 19 are stored in a housing, not shown, and rotatable in dependence on each other, wherein the adjusting elements 18 and 19 are each formed as a hollow body and have openings through the coolant in the respective control element 18 and or 19 can flow in and out. By rotation of the corresponding actuating element 18 and or 19 can their openings with corresponding connection openings in the housing of the rotary valve, where the hoses of the coolant circuit 1 are connected, are brought into variable overlap and thus defined flow paths through the rotary valve form. These are the control elements 18 and 19 tubular formed with openings in the lateral surface. The actuator 19 is axially aligned on the suction side with the main coolant pump 15 arranged while the first actuator 18 radially on the pressure side of the main coolant pump 15 is arranged. The first control element 18 serves to block the main heat exchanger return 7 if necessary. The second control element 19 is also in the main heat exchanger return 7 integrated and is also from a branch 6a of the main heat exchanger flow 6 contacted. In the area between the main coolant pump 15 and second actuator 19 opens the second partial return 10b of the heater core return 10 , The coolant circuit 1 can be vented by known and not shown means for venting, preferably in a surge tank.

The one from the first 18 and the second actuator 19 formed rotary valve is preferably switched so that after the commissioning of the internal combustion engine 2 below a predetermined limit temperature of the coolant or after stopping the engine 2 with already heated coolant, first the first actuator 18 shuts off the main heat exchanger return. The second control element 19 is switched so that coolant from the second partial return 10b over the branch 6a in the common section 17 but not via the main heat exchanger return 7 from the main heat exchanger 5 Coming coolant in the second actuator 19 can penetrate. During this phase, heated coolant will reach the heater core 8th needed, the check valve opens 20 the heating heat exchanger flow 9 and the secondary coolant pump 16 circulates the coolant through the heating circuit 4 , In this case, the coolant is due to the rapidly warming exhaust gas turbocharger 14 and exhaust manifold 13 promoted so that the heater core 8th can be supplied comparatively quickly with sufficiently warm coolant, while the coolant in the cylinder crankcase 12 is mixed as little as possible and thus can heat up quickly to achieve the friction optimum of the cylinder in turn.

With rising coolant temperature in the cylinder crankcase 12 it is advantageous to achieve a uniform heating of the coolant contained therein, a weak flow of coolant in the cylinder crankcase 12 to create. Nevertheless, still a rapid heating of the coolant in the cylinder crankcase 12 maintain, opens the first actuator 18 while the second actuator 19 a flow path from the branch 6a to the main coolant pump 15 and the main coolant pump 15 the coolant from the cylinder crankcase 12 through the second actuator 19 and the first actuator 18 through back into the cylinder crankcase 12 circulated. The main heat exchanger 5 is thus not flowed through.

If cooling of the same is required in an operating phase after reaching the desired operating temperature of the coolant, then the first actuating element opens 18 the main heat exchanger return, while the second actuator 19 the branch 6a decouples and the main heat exchanger return 7 from the main heat exchanger 5 to the cylinder crankcase 12 consistently opens, leaving the main coolant pump 15 a coolant circulation between the internal combustion engine 2 and main heat exchanger 5 can generate. In this phase, the secondary coolant pump 16 at low Coolant requirement at the heating heat exchanger 8th be shut off because the main coolant pump 15 only a sufficient circulation in the main circuit 3 and heating circuit 4 can represent.

The two control elements 18 and 19 In addition, you can set different coolant temperatures in the cylinder head 11 and cylinder crankcase 12 be used by the coolant flows inside the internal combustion engine 2 through targeted switching of the forward and reverse flows 6 . 7 and or 10 to be influenced.

According to 2 has a coolant circuit 1 for an internal combustion engine 2 a motor vehicle, several partial circuits, wherein in the present case only one main circuit 3 and a heating circuit 4 are shown. The internal combustion engine 2 consists essentially of a cylinder crankcase 12 , which includes the displacement of the working cylinder, a cylinder head 11 , which includes, inter alia, required for the mixture supply and removal for the displacement devices, one in the cylinder head 11 integrated exhaust manifold 13 , through which the hot combustion exhaust gases can escape, as well as the exhaust manifold 13 downstream exhaust gas turbocharger 14 , which uses the remaining exhaust gas energy for the compression of fresh gas. The cylinder head 11 , the exhaust manifold 13 , the exhaust gas turbocharger 14 and the cylinder crankcase 12 are beauschlagbar each with coolant, wherein for the cylinder head 11 , the exhaust manifold 13 and the cylinder crankcase 12 by internal fluidic connections with each other a coolant exchange is possible. The main circuit 3 contains a main heat exchanger 5 , which has a main heat exchanger lead 6 and via a main heat exchanger return 7 to the cylinder crankcase 12 connected. In the main heat exchanger return 7 is also a main coolant pump 15 arranged, preferably as by the internal combustion engine 2 driven centrifugal pump with axial suction side and radial pressure side is formed. The heating circuit 4 has a heating heat exchanger 8th on, which is traversed by air for the passenger compartment of the motor vehicle, so that a heat exchange between coolant and this air takes place. The heating heat exchanger 8th is via a heating heat exchanger flow 9 to the cylinder crankcase 12 connected. In the heater core 9 there is also a secondary coolant pump 16 , which is preferably electrically operated and a coolant circulation in the heating circuit 4 can generate. The heating circuit 4 can optionally by a check valve 20 in the heating heat exchanger flow 9 upstream of the secondary coolant pump 16 to be interrupted. The heating heat exchanger return 10 meanwhile shares at a branching point 22 on a first partial return 10a and a second partial return 10b on. The first partial return 10a flows into the exhaust manifold 13 and has a check valve 21 on, that is a backflow from the exhaust manifold 13 to the heating heat exchanger 8th in derogation. The turbocharger 14 is in the second partial return 10b involved. The heating heat exchanger flow 9 and the main heat exchanger feed 6 have starting from a common connection to the cylinder crankcase 12 a common section 17 , The connection for the common section 17 on the cylinder crankcase 12 is arranged so that coolant from the heater core return 10 the cylinder head 11 flow through and into the common section 17 can flow without dealing with the coolant in the cylinder crankcase 12 noticeably to mix. This is preferably achieved by the connection of the main heat exchanger flow 6 near the cylinder head 11 is arranged. For controlling and regulating the coolant circuit 1 are a first 18 and a second actuator 19 provided, which together form a rotary valve. The two control elements 18 and 19 are stored in a housing, not shown, and rotatable in dependence on each other, wherein the adjusting elements 18 and 19 are each formed as a hollow body and have openings through the coolant in the respective control element 18 and or 19 can flow in and out. By rotation of the corresponding actuating element 18 and or 19 can their openings with corresponding connection openings in the housing of the rotary valve, where the hoses of the coolant circuit 1 are connected, are brought into variable overlap and thus defined flow paths through the rotary valve form. These are the control elements 18 and 19 tubular formed with openings in the lateral surface. The actuator 19 is axially aligned on the suction side with the main coolant pump 15 arranged while the first actuator 18 radially on the pressure side of the main coolant pump 15 is arranged. The first control element 18 serves to block the main heat exchanger return 7 if necessary. The second control element 19 is both in the main heat exchanger return 7 , as well as the heater core 9 integrated and is also from a branch 6a of the main heat exchanger flow 6 contacted. In the area between the main coolant pump 15 and second actuator 19 opens the second partial return 10b of the heater core return 10 , Between main coolant pump 15 and first actuator 18 separate over the second actuator 19 and the main coolant pump 15 co-running main heat exchanger return 7 and the heater core 9 on by the heater core 9 from the main heat exchanger return 7 branches. The coolant circuit 1 can be vented by known and not shown means for venting, preferably in a surge tank.

The one from the first 18 and the second actuator 19 formed rotary valve is preferably switched so that after the commissioning of the internal combustion engine 2 below a predetermined limit temperature of the coolant or after stopping the engine 2 with already heated coolant, first the first actuator 18 shuts off the main heat exchanger return. The second control element 19 is switched so that coolant from the second partial return 10b to the main coolant pump 15 and from there into the heater core 9 but not via the main heat exchanger return 7 from the main heat exchanger 5 coming coolant and over the branch 6a from the common section 17 coming coolant in the second actuator 19 can penetrate. During this phase, heated coolant will reach the heater core 8th needed, the check valve opens 20 the heating heat exchanger flow 9 and the secondary coolant pump 16 circulates the coolant through the heating circuit 4 , In this case, the coolant is due to the rapidly warming exhaust gas turbocharger 14 and exhaust manifold 13 promoted so that the heater core 8th can be supplied comparatively quickly with sufficiently warm coolant, while the coolant in the cylinder crankcase 12 is mixed as little as possible and thus can heat up quickly to achieve the friction optimum of the cylinder in turn.

With rising coolant temperature in the cylinder crankcase 12 it is advantageous to achieve a uniform heating of the coolant contained therein, a weak flow of coolant in the cylinder crankcase 12 to create. Nevertheless, still a rapid heating of the coolant in the cylinder crankcase 12 maintain, opens the first actuator 18 while the second actuator 19 a flow path from the branch 6a to the main coolant pump 15 and the main coolant pump 15 the coolant from the cylinder crankcase 12 through the second actuator 19 and the first actuator 18 through back into the cylinder crankcase 12 circulated. The main heat exchanger 5 is thus not flowed through.

If cooling of the same is required in an operating phase after reaching the desired operating temperature of the coolant, then the first actuating element opens 18 the main heat exchanger return, while the second actuator 19 the branch 6a decouples and the main heat exchanger return 7 from the main heat exchanger 5 to the cylinder crankcase 12 consistently opens, leaving the main coolant pump 15 a coolant circulation between the internal combustion engine 2 and main heat exchanger 5 can generate. In this phase, the secondary coolant pump 16 with low coolant requirement at the heating heat exchanger 8th be shut off because the main coolant pump 15 only a sufficient circulation in the main circuit 3 and heating circuit 4 can represent.

The two control elements 18 and 19 In addition, you can set different coolant temperatures in the cylinder head 11 and cylinder crankcase 12 be used by the coolant flows inside the internal combustion engine 2 through targeted switching of the forward and reverse flows 6 . 7 and or 10 to be influenced.

LIST OF REFERENCE NUMBERS

1

Coolant circuit

2

Internal combustion engine

3

Main circuit

4

heating circuit

5

Main heat exchanger

6

Main heat exchanger Lead

6a

junction

7

Main heat exchanger return

8th

Heater core

9

Heating heat exchanger Lead

10

Heater core return

10a

first partial return

10b

second partial return

11

cylinder head

12

cylinder crankcase

13

exhaust manifold

14

turbocharger

15

Main coolant pump

16

Secondary coolant pump

17

common section

18

first actuator

19

second actuator

20

check valve

21

check valve

22

branching point

Claims (9)

Coolant circuit ( 1 ) for an internal combustion engine ( 2 ) of a motor vehicle, comprising a main circuit ( 3 ) with a main heat exchanger flow ( 6 ) upstream and a main heat exchanger return ( 7 ) downstream of a main heat exchanger ( 5 ), a heating circuit ( 4 ) with a heating heat exchanger flow ( 9 ) upstream and a heater core return ( 10 ) downstream of a heating heat exchanger ( 8th ), as well as an internal combustion engine ( 2 ) with at least one cylinder head ( 11 ), a cylinder crankcase ( 12 ), and at least one exhaust gas-carrying component ( 13 . 14 ), which are supplied with coolant from the coolant circuit ( 1 ) beauschlagbar and for this purpose fluidically connected to each other, wherein a main coolant pump ( 15 ) in the main circuit ( 3 ) and a secondary coolant pump ( 16 ) in the heating circuit ( 4 ), wherein the heating heat exchanger return ( 10 ) on the cylinder head ( 11 ) or an exhaust-carrying component ( 13 . 14 ), the main heat exchanger flow ( 6 ) on the cylinder head ( 11 ) or the cylinder crankcase ( 12 ) and the main heat exchanger return ( 7 ) on the cylinder crankcase ( 12 ), the main heat exchanger flow ( 6 ) and the heating heat exchanger flow ( 9 ) a common section ( 17 ), characterized in that the exhaust gas-carrying components ( 13 . 14 ) an integrated exhaust manifold ( 13 ) and an exhaust gas turbocharger ( 14 ) and the heater core return ( 10 ) at a branching point ( 22 ) into a first partial return ( 10a ) into which the integrated exhaust manifold ( 13 ) and the cylinder head ( 11 ) and a second partial return ( 10b ), in which the exhaust gas turbocharger ( 14 ), the second partial return ( 10b ) bypassing the internal combustion engine ( 2 ) into the main circuit ( 3 ) opens. Coolant circuit according to claim 1, characterized in that the main heat exchanger flow ( 6 ) on the cylinder crankcase ( 12 ) connected. Coolant circuit according to claim 1 or 2, characterized in that the main coolant pump ( 15 ) in the main heat exchanger return ( 7 ), wherein the main heat exchanger return ( 7 ) by a first actuator ( 18 ) can be shut off. Coolant circuit according to one of claims 1 to 3, characterized in that the secondary coolant pump ( 16 ) in the heating heat exchanger flow ( 9 ), wherein the heating circuit ( 4 ) from a check valve ( 20 ) can be shut off. Coolant circuit according to one of claims 1 to 4, characterized in that the main heat exchanger flow ( 6 ) so on the cylinder crankcase ( 12 ), that in the cylinder crankcase ( 12 ) located coolant with closed main heat exchanger return ( 7 ) and opened heating circuit ( 4 ) is mixed as little as possible. Coolant circuit according to one of claims 1 to 5, characterized in that in the first partial return ( 10a ) a check valve ( 21 ) is arranged. Coolant circuit according to one of claims 3 to 6, characterized in that the first actuating element ( 18 ) and a second actuator ( 19 ) are arranged in a common housing and together form a rotary valve, wherein the first ( 18 ) and the second actuator ( 19 ) are hollow and each have a plurality of radial openings which, upon rotation of the first ( 18 ) and / or the second actuating element ( 19 ) can be overlapped with correspondingly corresponding openings in the housing to form a flow path for the coolant, wherein the main coolant pump designed as a centrifugal pump ( 15 ) the coolant axially from the second actuator ( 19 ) and radially to the first actuator ( 18 ) promotes. Coolant circuit according to claim 7, characterized in that the main heat exchanger flow ( 6 ) a branch ( 6a ), which in the second actuator ( 19 ), the main heat exchanger return ( 7 ) and the branch ( 6a ) by the second actuator ( 19 ) are fluidically connectable, and that the second partial return ( 10b ) of the heating heat exchanger return ( 10 ) on the suction side to the main coolant pump ( 15 ) opens. Coolant circuit according to claim 8, characterized in that the second actuating element ( 19 ) and the main coolant pump ( 15 ) a part of the heating heat exchanger flow ( 9 ) can form.

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