EP1698770A1 - Separate cooling of cylinder head - Google Patents

Abstract

The engine has a cylinder head with a cooling system for forming two cooling areas that are running from two coolant flows respectively, where one of the cooling areas is arranged at an outlet duct, and another cooling area is arranged at the remaining of the head. Control units (8) are arranged at the system in such a manner that the coolant flows are separately controllable from each other by the respective cooling areas.

Description

The invention relates to an internal combustion engine having at least one cylinder head for terminating at least one combustion chamber, the inlet side is assigned at least one inlet channel and outlet at least one outlet channel, wherein the cylinder head is associated with a flowed through by a coolant cooling system.

Such internal combustion engines are known.

DE 198 03 885 A1 relates to a cooling circuit arrangement for a liquid-cooled internal combustion engine,
wherein the internal combustion engine in the cylinder head and in the crankcase each controlled separately with separately conveyed by a single pump coolant flows through cooling channels, and
the as needed in the cylinder head cooling jacket pump on the suction side with a controlled via a 3-way valve / regulated bypass line to a connected thereto via a flow line and a return line heat exchanger in an outer cooling circuit is connected,
the crankcase cooling jacket via a controllable valve with the outer cooling circuit is separately connectable upon reaching a predetermined temperature in / on the crankcase.

The suction side connected to a drain of a arranged in the bypass line 3-way thermostat pump is the delivery side with an outlet side longitudinal channel of the cooling jacket in the inlet side to a longitudinal channel transversely flowed cylinder head in combination. The inlet side longitudinal channel is connected via a connecting line to the bypass line and the heat exchanger supply line. At least the crankcase cooling jacket is via a means of a electronic control unit map-controlled single or multi-way valve with the outer cooling circuit medium or directly connectable.

DE 41 00 459 C2 discloses a cylinder head of a liquid-cooled internal combustion engine with cylinders arranged in series, consisting of a casting with one of lateral outer walls, the cylinder head floor and a distance above it cylinder head center deck limited cooling space and above this from the cylinder head center deck to the top parting plane of Outer walls enclosed control chamber with through the refrigerator, from the mouth openings in the combustion chamber side portion of the cylinder head floor extending to the lateral outer walls valve channels and a cooling chamber and the control chamber parallel to the cylinder axis passing through approximately cylindrical chamber for a spark plug or injector and molded into the lateral support walls support columns for receiving the cylinder head bolts. The cylinder bank has a through-cooling compartment divided by vertical double ribs attached to the cylinder head floor and both sides of the cylinder head bolt support columns into sections substantially interspersed only with exhaust ports, intake ports and spark plug bosses for a cylinder, and the coolant flow through the double ribs in each case a main cooling flow which flows through a cooling space section, starting from at least one passage opening from the engine block, below the outlet ducts, transversely to the engine longitudinal axis, and cools the outside of the double ribs, and one auxiliary cooling flow, starting from at least one each Through opening from the engine block, which flows through the double-ribbed spaces approximately parallel to the cylinder axes and thereby cools the inner sides of the double ribs, and wherein main and secondary cooling streams combine at the top of the double ribs un d open into a below the inlet channels longitudinal coolant collecting channel.

A cooling device in a cylinder head of a water-cooled multi-cylinder internal combustion engine is disclosed in DE OS 38 38 953, comprising
a plurality of partitions disposed between the cylinders and water jacket formed in a cylinder head,
a plurality of candle insertion tubes vertically disposed above the substantially central portions of the associated cylinders,
a plurality of coolant inlet ports disposed on one side of the plug-in tubes, and a cooling water outlet port disposed on the other side of the plug-in tubes;
a plurality of walls projecting from the partitions toward the plug-in tubes, and
wherein each wall has a lower protruding part having a relatively small width in the vicinity of a wall of the cylinder head above a combustion chamber formed in each cylinder and an upper protruding part having a relatively large width.

• mit einer Vielzahl von Einlaßkanälen, die jeweils in einen ersten Halbseitenabschnitt der Brennräume münden, um Einlaßluft oder Kraftstoff/Luftgemisch zuzuführen,
• mit einer Vielzahl von Auslaßkanälen, die jeweils in einen zweiten Halbseitenabschnitt der Brennräume münden, der dem ersten Halbseitenabschnitt gegenüberliegt, um Verbrennungsgase auszulassen,
• mit einem ersten Kühlkanal, der entlang der Reihe der Vielzahl von Brennräumen, daran nacheinander vorbeiführend in der Nähe der Einlaßkanäle auf einer Seite angeordnet ist, die zentralen Deckenabschnitten der Brennräume gegenüberliegt,
• mit einem zweiten Kühlkanal, der entlang der Reihe der Vielzahl von Brennräumen, daran nacheinander vorbeiführend in der Nähe der Auslaßkanäle, auf einer den zentralen Deckenabschnitten der Brennräume gegenüberliegenden Seite angeordnet ist, und
• mit einem dritten Kühlkanal, der entlang der Reihe der Vielzahl von Brennräumen, daran nacheinander vorbeiführend in der Nähe der zentralen Deckenabschnitte der Brennräume angeordnet ist,

ausgebildet ist.US 4,730,579 relates to a cylinder head of an internal combustion engine, which is attached to a cylinder block and together delimits a plurality of combustion chambers, which are arranged in series, wherein the cylinder head has a cooling jacket and wherein the cylinder head:

• having a plurality of intake ports each opening into a first half-side portion of the combustion chambers to supply intake air or fuel / air mixture,
• a plurality of outlet passages each opening into a second half-side portion of the combustion chambers opposite to the first half-side portion to discharge combustion gases,
• a first cooling passage disposed along the row of the plurality of combustion chambers, past it successively near the intake ports on one side, facing the central ceiling portions of the combustion chambers;
• a second cooling passage disposed along the row of the plurality of combustion chambers, successively past the exhaust ports, on a side opposite to the central ceiling portions of the combustion chambers, and
• with a third cooling channel arranged along the row of the plurality of combustion chambers, past it successively, near the central ceiling sections of the combustion chambers,

is trained.

The first, second, and third cooling channels are each independently connected at one end to the cooling jacket of the cylinder block to individually receive coolant, with three parallel flows of the coolant through the first, second, and third cooling channels having a triple distribution of flow rates corresponding to the predetermined flow rates. relative sizes of the flow resistance of the first, second and third cooling channel are made possible.

For the derivation of the resulting combustion gases, the cylinder head and an associated exhaust manifold are currently performed as two separate parts. The disadvantage here is that at partial and full load of the engine increased heat input into the cylinder head and the associated cooling system results. In particular, in the case of a coolant-flow-side cylinder head, this means an unequal temperature distribution between the outlet and inlet sides. If the internal combustion engine is hardly loaded (traffic jam, stop and go, overrun during a prolonged downhill descent), there is a higher heat emission from the exhaust gas upstream of the catalytic converter. As a result, the catalyst cools down too much, harmful exhaust gas components are converted only insufficient.

Therefore, the invention has for its object to improve an internal combustion engine of the type mentioned with simple means that a well-regulated and thus optimized heat balance of the engine, in particular the cylinder head, which also has a reduced fuel consumption and reduced emissions result, is reached.

According to the invention the object is achieved in that the cooling system of the cylinder head at least two cooling regions with a first cooling region, which is flowed through by a first coolant flow, and with a second cooling region, which is flowed through by a second coolant flow, wherein the first cooling region, the at least one outlet channel, and the second cooling area is associated with the rest of the cylinder head, and wherein the cooling system controls are assigned such that the separate coolant streams in the respective cooling areas are controlled separately.

In order for an internal combustion engine is provided, each having a separate in an exhaust region and in the remaining region of the cylinder head, independently controllable coolant flow. The outlet channel is in the context of the invention, a gas outlet.

Due to the separately controllable coolant flows in the respective cooling regions is advantageously achieved that after a cold start of the engine, a considerably shortened warm-up time is achieved, with warm engine in partial to full load operation improved heat dissipation between the two cooling regions of the respective cylinder can be achieved. In low load situations (stop & go, congestion, overrun on mountain descents) significantly lower exhaust gas heat losses (heat transfer through exhaust ducts in the cooling circuit), whereby cooling of the catalyst is reduced, so harmful components of the exhaust gas can be sufficiently converted at any time. At full load, the exhaust gas can be cooled specifically, whereby the Anfettungsbedarf for component protection can be reduced or reduced. This also reduces fuel consumption.

In order to achieve that the catalyst of the internal combustion engine warms up faster after a cold start, or when the internal combustion engine is operated in the low load range, the corresponding control element is adjustable so that the required coolant flow, preferably a reduced or prevented coolant flow is applied to the first cooling region. On the other hand, if the internal combustion engine is operated in the partial or full load range, this is Control adjustable so that a correspondingly higher coolant flow flows through the first cooling area.

The first cooling area is arranged on the outlet side or exhaust side according to the invention, wherein the second cooling area in the context of the invention is assigned to the rest of the cylinder head, ie the respective combustion chamber and the inlet side.

In an advantageous embodiment of the invention it is provided that the cylinder head has a plurality of outlet channels, which are combined to form a main strand, wherein the first cooling region is associated with the main strand.

This advantageous embodiment is based on the finding that the cylinder head with its exhaust manifold can be combined in one unit. If both components, so the cylinder head and the exhaust manifold, executed as a unit, thereby the weight of the engine can be reduced, while the warm-up time can be shortened. The exhaust ports are combined in the cylinder head to a main strand

In a further embodiment of the invention is advantageously provided that the first cooling area is completely separated from the second cooling area, wherein the control elements are each arranged on an inlet side of the respective cooling area in a respective inlet conduit, so that the cooling system has completely separate coolant circuits in the cylinder head. In this case, the separate coolant flows in the respective cooling regions can be correspondingly controlled by means of the respective control element assigned to the respective inlet line. This results in a volume flow control / or. control of the respective coolant flow at the inlet side of the respective cooling area.

Conveniently, however, it may also be provided that the first cooling area is completely separated from the second cooling area, wherein the control elements are each arranged on an outlet side of the respective cooling area in outlet ducts, so that the cooling system in the cylinder head has completely separate coolant circuits. Here, the separate coolant flows in the respective cooling areas are controlled by means of the respective outlet line associated control accordingly. This results in a volume flow control / or. control of the respective coolant flow at the outlet side of the respective cooling area.

In a further advantageous embodiment of the invention is advantageously provided that the first cooling area is separated within the cylinder head of the second cooling area, wherein the control elements are each arranged on an inlet side of the respective cooling area in the respective inlet line. This results in a volume flow control / or. control of the respective coolant flow at the inlet side of the respective cooling area. In this advantageous embodiment, the two cooling areas on a common outlet, so that it can be dispensed with a second outlet. As a result, manufacturing costs of the internal combustion engine are reduced, since only one common for both cooling areas discharge line is provided. By controlling the controls, there are corresponding pressure differences in the individual cooling areas, so that a separate control of the coolant flows can be achieved.

In a further advantageous embodiment of the invention is advantageously provided that the first cooling area is separated within the cylinder head of the second cooling area, wherein the control elements are each arranged on an outlet side of the respective cooling area in a respective outlet conduit, wherein both cooling areas by a common inlet conduit with be supplied to the coolant. This advantageously results in a volume flow control / or control of the coolant flows at the outlet side of the respective cooling regions. In this advantageous embodiment, the two cooling regions on a common inlet line, so that it can be dispensed with a second inlet line. As a result, manufacturing costs of the internal combustion engine are reduced, since only one common for both cooling areas inlet line is provided. By controlling the controls, there are corresponding pressure differences in the individual cooling areas, so that a separate control of the coolant flows can be achieved.

Favorable in the context of the invention is when the controls are preferably designed as continuously adjustable valves, in particular as a thermostat. It is also possible, however, that in particular the controls assigned to the second cooling area are preferably configured as cost-effective flap valves, which only permit an entry or an exhibition.

In a further preferred embodiment of the invention, it is advantageously provided that the first cooling area within the cylinder head is separated from the second cooling area, wherein an outlet line of the second cooling area opens into an outlet line of the first cooling area, and wherein an inlet line common to both cooling areas is a continuously adjustable control element is assigned, and wherein the second cooling area, a further control element is arranged in its outlet conduit, which can be configured as a continuously adjustable control element, or preferably as a flap valve, which allows only an arrival or exhibition.

In a further advantageous embodiment, it is provided that the first cooling area is separated within the cylinder head from the second cooling area, wherein an outlet of the second cooling area in an outlet of the first cooling area opens, and wherein the outlet of the second cooling area is assigned a control that as continuous adjustable control element, or preferably as a flap valve, which allows only an arrival or exhibition, can be configured, and wherein in the outlet of the first cooling area a continuously adjustable control is arranged, both cooling areas are supplied via a common inlet line with the coolant.

By means of the two last-mentioned advantageous embodiments of the invention, a combined inlet-outlet control or control of the coolant flow through the cylinder head in its respective cooling areas can be achieved.

Figuren 1 bis 6

Prinzipskizzen getrennter Kühlkreisläufe in einem Zylinderkopf, und

Figuren 7 bis 23

weitere Ausführungsbeispiele.

Further advantageous embodiments are disclosed in the subclaims and the following description of the figures. Show it:

FIGS. 1 to 6

Schematic diagrams of separate cooling circuits in a cylinder head, and

FIGS. 7 to 23

further embodiments.

In the different figures, the same parts are always provided with the same reference numerals, which is why these are usually described only once.

1 shows a cylinder head 1 shown schematically. The cylinder head 1 terminates in a known manner from a combustion chamber, not shown. The combustion chamber inlet and outlet channels for supplying air or a fuel-air mixture or discharge of combusted fuel-air mixture are assigned as exhaust gas, which are not shown in Figure 1. The cylinder head 1 is associated with a cooling system 2 through which a coolant flows.

The cooling system 2 of the cylinder head 1 has two cooling regions 3, 4 with a first cooling region 3, through which a first coolant flow (arrow 6) flows, and with a second cooling region 4, through which a second coolant flow (arrow 7) flows.

The first cooling area 3 is assigned to the exhaust passage or exhaust channels, the second cooling area 4 being assigned to the remainder of the cylinder head 1, that is to say to the combustion space and the intake passage (s). In the illustrated preferred embodiment, the cylinder head 1 has a plurality of outlet channels, which are combined within the cylinder head 1 to form a main strand. Of course, the cylinder head 1 complete several combustion chambers, the internal combustion engine may be, for example, a series engine or a V-engine. In a V-engine, of course, two cylinder heads 1 are provided.

The cooling system or the cooling zones 3, 4 control elements 8 and 9 are assigned such that the separate coolant streams in the respective cooling areas 3.4 are separately controllable.

The control element 8 assigned to the exhaust-side cooling region 3 and the second cooling region 4 is in each case preferably designed as a continuously adjustable valve, in particular as a thermostat, wherein a control element 9 assigned to the second cooling region 4 can preferably be designed as a flap valve which permits only one inlet or outlet , The control element 9 is not shown in FIGS. 1 to 4. In these embodiments, only controls 8 are shown, which are each replaced by controls 9.

The cooling system of the cylinder head 1 is separable by means of a thermostat or the like from a cooling system of a cylinder block associated with the cylinder head 1.

In FIGS. 1 and 2, the two cooling regions 3, 4 each have an inlet line 12 on their inlet side 11 and an outlet line 14 on their outlet side 13 opposite the inlet side 11.

In the embodiment shown in Figure 1 each of the inlet conduit 12 is associated with a control element 8, in contrast to which in the embodiment shown in Figure 2, the control elements 8 are each associated with the outlet conduit 14.

In both embodiments, both cooling areas 3.4 are completely separated from each other within the cylinder head 1, so that the cooling system has completely separate coolant circuits within the cylinder head 1. The complete separation can be seen by means of a partition wall 16 shown in principle, which extends continuously from the inlet side 11 to the outlet 13. In the embodiment according to FIG. 1, a volume flow regulation or control of the coolant flows 6, 7 on the inlet side 11 is effected by means of the control elements 8. In contrast, the volume flow control or control of the coolant flows 6.7 in the embodiment of Figure 2 on the outlet side 13th

In a further embodiment according to Figures 3 and 4, the two cooling areas 3.4 are separated within the cylinder head 1, so that a common outlet conduit 17 (Figure 3) and a common inlet conduit 18 (Figure 4) is provided.

In the exemplary embodiment according to FIG. 3, the respective cooling area 3, 4 has an inlet line 19 with control elements 8 associated therewith. In contrast, in the embodiment according to FIG. 4, the control elements 8 are assigned to the respective outlet lines 21. Of course, in these embodiments, as already described for the embodiments of Figures 1 and 2, a second cooling region 4 associated control element 9 may be configured as a flap valve, which is controllable between an on-off position.

The partition wall 16 shown in principle extends according to the embodiment of Figure 3 from the inlet side 11 to just before the outlet 13, wherein the partition wall 16 shown in Figure 4 extends from the outlet side 13 in the direction of the inlet side 11 and just before the inlet side eleventh ends. Thus, a separation of the two cooling area 3.4 is achieved within the cylinder head 1, wherein the two cooling areas are 3.4 completely separated according to the embodiment of Figures 1 and 2.

This results in a flow of coolant (arrow 6 or 7) due to differential pressures in the respective cooling areas 3 and 4. Closes the control 8 and the thermostat of the first cooling area 3, for example, a coolant flow (arrow 6) in the first cooling area 3 to prevent or reduce, the control 8 or 9 can open, so that the coolant mainly flows through the second cooling area 4 due to the pressure differences in the two cooling areas 3 and 4 respectively.

This may be desirable, for example, after a cold start of the internal combustion engine or during its low-load operation. In a first part of the warm-up phase, the exhaust gas side is preferably not cooled, so that a catalyst is led faster to operating temperature, since this is the uncooled exhaust gases be supplied. In the following second part of the warm-up phase, when the catalyst has reached its operating temperature, the exhaust gas side is cooled. In the first part of the warm-up phase of the internal combustion engine is achieved by the missing or reduced cooling that, for example, the downstream catalyst always receives exhaust gases with the required high temperature to convert harmful exhaust gas components. In the second part of the warm-up phase, the exhaust-gas-side region or the first cooling region 3 is cooled particularly intensively. The recovered energy (heat) is supplied to the internal combustion engine, so that it warms up faster, thereby reducing friction losses in the warm-up phase.

In a full load operation of the internal combustion engine, however, the exhaust gas side is sufficiently cooled by fully opening the control element 8 and 9, of course, the rest of the cylinder head 1 is sufficiently cooled. This of course also applies to the embodiments of Figures 1 and 2.

As in the exemplary embodiment of FIGS. 3 and 4, the two cooling regions 3, 4 are separated within the cylinder head 1 in the exemplary embodiments illustrated in FIGS. 5 and 6. The partition wall 16 shown in principle in Figures 5 and 6 extends from the outlet side 13 in the direction of the inlet side 11 and ends shortly before the inlet side 11. Here, a common inlet line 22 is provided for both cooling region 3 and 4, in the embodiment according to Figure 5 is associated with a control 8. On the outlet side, an outlet line 23 or 24 is assigned to each of the two cooling zones 3, 4, the outlet line 23 of the second cooling zone 4 opening into the outlet line 24 of the first cooling zone 3. The outlet conduit 23 of the second cooling area 4 is in each case assigned a control 9 in both examples (FIGS. 5 and 6).

In the exemplary embodiment illustrated in FIG. 6, the outlet conduit 24 of the first cooling area 3 is assigned a control element 8 which is arranged in the selected representation above the junction of the outlet conduit 23 into the outlet conduit 24.

The assignment of the control element 8 or the control elements 8 and 9 to the respective inlet and outlet lines 12,14,17,18,19,21,22,23,24 is not limited to the illustrated embodiments of Figures 1 to 6 , It is possible that the controls 8 and 9 are reversed on the inlet and outlet side. The partition wall 16 may extend from the outlet side to just before the inlet end ending or be executed continuously. Conceivable in the embodiments of Figures 1 and 2, for example, a cross arrangement of the respective controls 8 and 8 and 9. In the embodiments according to Figures 3 and 4, it would be possible, the respective common inlet and outlet line 18 and 17 a Assign control 8 or 9, in which case a control 8 or 9 would be arranged only in an inlet and outlet line 19 and 21 of the associated cooling area 3 or 4.

Conceivable embodiments are shown in Figures 7 to 23. A coolant flow direction is shown for all FIGS. 1 to 23 by means of the arrow 26.

In a modification of Figures 1 and 2, a cross arrangement of the controls 8 and 9 is shown in the respective embodiment to the figures 7 and 8 respectively. FIGS. 9 and 10 show a further exemplary embodiment of FIG. 4, whereby here too a cross arrangement of the control elements 8 and 9 is provided. In the exemplary embodiments of FIGS. 11 and 12, a crossover variant to the exemplary embodiment according to FIG. 3 is shown. FIG. 13 shows a variant of FIG. 6, in which a control element 8 or 9 is arranged in the flow direction 26 below the junction of the outlet line 23 into the outlet line 24, wherein a further control element 8 or 9 is arranged above the junction.

FIGS. 14 and 15 each show a further embodiment of the example shown in FIG. In this case, an inlet line branches off from the other. In FIG. 14, a control element 8 or 9, viewed in the flow direction 26, is arranged below the branch, the other control element 8 or 9 being associated with the branch line. In contrast, in FIG. 15, the other control element 8 9 and 9 seen in the flow direction 26 above the branch arranged in the inlet conduit in which the first control 8 and 9 is arranged.

The embodiments of Figures 16 and 17 are in turn variants of the embodiment of Figure 2. Here, an outlet opens in the other outlet, wherein the outlet seen in the flow direction 26 above the junction a control 8 or 9 is assigned, wherein the other control 8 and 9, respectively, is arranged in the opening outlet line. In FIG. 17, based on FIG. 15, the second control element 8 or 9, viewed in the flow direction 26, is arranged below the junction.

Figures 18 and 19 show variants of the embodiment of Figure 1. The two separate inlet lines branch off from a common inlet line. The common inlet line is associated with a control 8 and 9, wherein the other control 8 or 9 is associated with an outlet. FIGS. 18 and 19 show a cross arrangement of the control element 8 or 9 assigned to the respective outlet line.

FIGS. 20 and 21 again show a variant of the exemplary embodiment according to FIG. The embodiment shown in each case in Figures 20 and 21 corresponds to the embodiments of Figures 14 and 15, wherein the partition is designed in contrast to the example shown in Figures 14 and 15 throughout.

A further variant of the embodiment of Figure 2 is shown in Figures 22 and 23. The two outlet lines open into a common outlet line, which is associated with a control 8 and 9 respectively. The other control element 8 or 9 is in each case associated with an inlet line, it being possible to deduce a cross arrangement on the inlet side when viewing FIGS. 22 and 23.

By means of the aforementioned merely exemplary embodiments, an internal combustion engine is provided, which has a well controllable and thus optimized heat balance, which also reduced Fuel consumption and emissions can be achieved. An internal combustion engine is provided which has a coolant flow 6 or 7, which can be controlled separately in an exhaust gas area and in the remaining area of the cylinder head 1 independently of each other.

The control elements 8, in particular the control element 9, can preferably be connected to a central control unit, which controls and / or actuates in particular the control element 9 in the different temperature ranges of the internal combustion engine.

Furthermore, it is possible to supply additional cooling areas, for example a third cooling area in the cylinder head and / or a block water jacket, in parallel or in series with the exemplary embodiments already described.

Claims (10)

Internal combustion engine having at least one cylinder head (1) for terminating at least one combustion chamber, the intake side is assigned at least one inlet channel and outlet side at least one outlet channel, wherein the cylinder head (1) is associated with a cooling system (2) through which a coolant flows,
characterized in that
the cooling system (2) of the cylinder head (1) has at least two cooling regions (3, 4) with a first cooling region (3) through which flows a first coolant flow (arrow 6) and with a second cooling region (4) that flows from one flows through the second coolant flow (arrow 7), wherein the first cooling region (3), the at least one outlet channel, and the second cooling region (4) associated with the rest of the cylinder head (1), and wherein the cooling system (2) controls ( 8, 9) are assigned in such a way that the separate coolant flows (arrows 6, 7) in the respective cooling regions (3, 4) can be controlled separately from one another. Internal combustion engine according to claim 1,
characterized in that
the cylinder head (1) has a plurality of outlet channels, which are combined to form a main strand. Internal combustion engine according to one of claims 1 or 2,
characterized in that
the first cooling zone (3) is completely separated from the second cooling zone (4), the control elements (8, 9) being respectively arranged on an inlet side (11) of the respective cooling zone (3, 4) in a respective inlet conduit (12), so that the cooling system (2) in the cylinder head (1) has two completely separate coolant circuits. Internal combustion engine according to one of claims 1 or 2,
characterized in that
the first cooling area (3) is completely separated from the second cooling area (4), the control elements (8, 9) being respectively arranged on an outlet side (13) of the respective cooling area (3, 4) in a respective outlet line (14), so that the cooling system (2) in the cylinder head (1) has two completely separate coolant circuits. Internal combustion engine according to one of claims 1 or 2,
characterized in that
the first cooling zone (3) within the second cylinder head (1) is separated from the second cooling zone (4), the control elements (8, 9) respectively on an inlet side (11) of the respective cooling zone (3, 4) in a respective inlet conduit (19) are arranged. Internal combustion engine according to one of claims 1 or 2,
characterized in that
the first cooling zone (3) within the second cylinder head (1) is separated from the second cooling zone (4), the control elements (8, 9) each on an outlet side (13) of the respective cooling zone (3, 4) in a respective outlet conduit (21) are arranged. Internal combustion engine according to one of the preceding claims,
characterized in that
the control element (8) is a continuously adjustable valve, preferably a thermostat. Internal combustion engine according to one of the preceding claims,
characterized in that
the control element (9) is preferably a flap valve which allows only one arrival or exhibition. Internal combustion engine according to one of claims 1 or 2 and 7 or 8,
characterized in that
the first cooling zone (3) within the cylinder head being separated from the second cooling zone (4), an outlet conduit (23) of the second cooling zone (4) terminating in an outlet conduit (24) of the first cooling zone (3), and one of the two cooling zones (3,4) commonly assigned inlet line (22) is associated with a continuously adjustable control element (8), and wherein the second cooling area (4) in its outlet conduit (23) is associated with a further control element (9). Internal combustion engine according to one of claims 1 or 2 and 7 or 8,
characterized in that
the first cooling zone (3) within the cylinder head is separated from the second cooling zone (4), an outlet conduit (23) of the second cooling zone (4) discharging in an outlet conduit (24) of the first cooling zone (3), and the outlet conduit (3) 23) of the second cooling area (4) is assigned a control element (9) and the outlet line (24) of the first cooling area (3) is a continuously adjustable control element (8), and wherein both cooling areas (3, 4) are connected via a common inlet line (22 ) are supplied with the coolant.

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