DE102004018675A1 - Cooling system of an internal combustion engine and internal combustion engine - Google Patents

Abstract

Known cooling systems for internal combustion engines have a plurality of parallel or in series arranged cooling circuits, which require a large number of lines, connections and a large installation space. DOLLAR A It is a cooling system (10, 10 ', 10' ') of an internal combustion engine, with a plurality of in the cooling system (10, 10', 10 '') circulating coolant (24, 24a) to be cooled assemblies or parts, the plurality of respective assemblies or the respective component associated cooling circuits (26, 26a, 26b, 26c, 26d) having areas (30) in which an energy transfer from the assembly or the component to the coolant (24, 24a) takes place , proposed, wherein at least two different modules or components associated areas (30) in a common unit (32) are arranged. In addition, an internal combustion engine with such a cooling system (10, 10 ', 10' ') is proposed.

Description

The The invention relates to a cooling system an internal combustion engine, with several through in the cooling system circulating coolant to be cooled assemblies or parts, the more of the respective modules or the respective Component associated cooling circuits with Has areas in which an energy transfer from the module or the component to the coolant takes place, as well as an internal combustion engine.

The DE-A-199 55 302 shows an internal combustion engine with a coolant circuit, in the flow direction behind a coolant pump an engine cooling circuit by the internal combustion engine having a crankcase and a cylinder head, an exhaust circuit with an exhaust manifold and an exhaust gas turbocharger and a heat exchange circuit with a charge air heat exchanger and a raw water heat exchanger which are arranged in parallel and which in front of the coolant pump merged again become.

The The problem underlying the invention is seen in that Such an internal combustion engine or a cooling system for such an internal combustion engine has many individual assemblies and therefore consuming in the Construction is or a big one Space required.

This Problem is inventively the teaching of the claims 1 or 10 solved, wherein in the further claims features are listed, the solution develop in an advantageous manner.

On This way will be a cooling system an internal combustion engine provided, which is particularly compact is because the areas in which an energy transfer from an assembly to be cooled the internal combustion engine to a circulating in the cooling system coolant takes place, are arranged in a common unit.

are at least two of the cooling circuits in parallel arranged so can she over have a common inlet or a common sequence and by only one coolant flow with coolant be supplied. Such an embodiment is particularly space-saving and points over it In addition, a lower flow resistance as a different arrangement, whereby, for example, the risk of cavitation is lowered. The coolant must be promoted against a lower differential pressure, so that in total a lower drive power is required.

Become at least two of the cooling circuits independently with coolant supplied, so this can be a stronger or different cooling of Assemblies are achieved.

The common unit can be, for example, by an arrangement in one common housing will be realized. Preferably, however, the areas form as such a unit or are formed in the manner of a housing. The unit can to the internal combustion engine or a cylinder head or a Engine block of the internal combustion engine to be arranged adjacent or but a component of the internal combustion engine, the cylinder head or of the engine block.

at the assembly or the component may be, for example, the Cylinder head and / or the engine block of the internal combustion engine and / or also around a turbocharger, an exhaust gas energy recovery unit, a Exhaust outlet or elbow and / or any other component or any other assembly of the internal combustion engine or any other component (s) associated with the internal combustion engine act.

is at least one of the areas arranged such that an energy transition to the coolant can be done in this range of two modules / parts, so wear this continue to a compact design at.

The Assemblies / parts can For this purpose be provided adjacent to each other in such a way that the area arranged between them, so that he can connect both to the one assembly or the one component and the other module or the other component adjoins, leaving an energy transition can take place.

The cooling system preferably has at least one coolant pump on or is connected with such to the coolant in the cooling system or the cooling circuits in Circulation to the energy-containing or heated coolant from carry away the area and by means of coolant lower energy potential or colder coolant to replace. The coolant can after removal a heat exchanger, for example be supplied in the manner of an air or otherwise cooled cooling device, to get it ready for use again and return it to the area.

If an internal combustion engine has such a cooling system, it can be made particularly compact and thus space-saving. In addition, due to the arrangement of the areas in a common unit, a reduced number of connections in the manner of lines, hoses or fittings and associated mounts, flanges, etc. necessary, whereby a cost-effective design favors and reduces the number of possible leakage points and thus the reliability is increased.

A Such internal combustion engine can be used in different fields of application, for example, on land as well as on water. Especially In marine applications, for example, it is due to safety-related Aspects important that exhaust gas outlet, or turbocharger or housing of Turbocharger turbines are sufficiently cooled, since in these areas at full load very high temperatures can be achieved. Marine applications point it over often out the peculiarity of using cooling by seawater.

A Such internal combustion engine can be at least substantially in one stationary Use, for example in a generator or power plant etc., or mobile, for example, in a vehicle or ship, etc., used become. In particular, such an internal combustion engine is cramped Operating conditions, such as those on ships, submarines or to construction or industrial machinery or to agricultural Machines, such as harvesters or farm tractors, due to Variety of additional aggregates and the additional required by the Space, occur, advantageous.

A inventive internal combustion engine can for example, with LPG or any other suitable fuel; especially But it is a diesel or gasoline engine.

In the drawing are three embodiments described in more detail below represented the invention. It shows:

1 a schematic representation of a cooling system with a cooling circuit,

2 a schematic representation of a second cooling system with separate cooling circuits and

3 another cooling system, adapted to cooling by raw water, for example in the form of seawater.

It will be up first 1 Reference is made, which is a schematic representation of a cooling system 10 an internal combustion engine, which is represented in the present illustration by its components, shows.

The internal combustion engine has an engine block according to the first embodiment 12 , a cylinder head 14 , an exhaust manifold and an exhaust outlet, respectively 16 , a turbocharger 18 , an exhaust gas recirculation 20 and a charge air supply 22 on. The internal combustion engine may moreover comprise additional components which, for reasons of simplification, are not addressed in the present application, but which are well known to the person skilled in the art, or individual or a plurality of said components may be dispensed with. For example, the internal combustion engine may also be an uncharged internal combustion engine which has no turbocharger.

The cooling system 10 at least serves to cool the engine block 12 , the cylinder head 14 , the exhaust outlet 16 , the turbocharger 18 , the exhaust gas recirculation 20 and the charge air supply 22 the internal combustion engine.

This is indicated by the cooling system 10 a coolant pump 23 which is a coolant 24 in a cooling circuit 26 which circulates the components, ie the engine block 12 , the cylinder head 14 , the exhaust outlet 16 , the turbocharger 18 , the exhaust gas recirculation 20 and the charge air supply 22 with the coolant 24 supplied to cool this, and the heated coolant 24 to a heat exchanger 28 in which passes through the coolant 24 removed from the components or excess heat or energy is removed or delivered to another medium or the environment. In addition, lines, pipes, connecting and / or fittings are provided, which are suitable, the coolant 24 from the coolant pump 22 to the components, on to the heat exchanger 28 and back to the coolant pump 23 to lead. The heat exchanger 28 According to the present embodiment is formed in the manner of a known air-cooled heat exchanger, as is well known and common for example on vehicles.

The coolant 24 is from the cooling circuit 26 so passed by or to the respective components, that an energy or heat transfer from these to the coolant 24 takes place to excess or dissipated heat / energy from the component by means of the coolant 24 evacuate. The components have one or more area (s) 30 in which an energy transfer from the assembly or the component to the coolant 24 can be done. This area 30 or these areas 30 can in a known manner, for example, by a wall of a cooling channel extending through the component / the assembly or on him / her ago when extending, or are formed by portions of such, a bore in a housing or otherwise, which is suitable, the coolant 24 through one component / assembly or through two or more components / assemblies or along one or more component (s) / assembly (s).

According to the invention, at least two different areas of the named components or assemblies are assigned 30 in which an energy transfer from the assembly or the component to the coolant 24 can be done in a common unit 32 arranged. This unit 32 For example, it can be designed in the manner of a housing which, for example, adjoins the internal combustion engine or is also provided separately or independently or adjacent to the internal combustion engine. The unit 32 can be formed by a single or multi-part cast body or casting, in which / which the areas 30 and / or the components, also in sections, are integrated.

According to the in 1 illustrated embodiment, the exhaust outlet 16 , the turbocharger 18 and the charge air supply 22 assigned areas in a common unit 32 summarized. In addition, the exhaust outlet 16 and the turbocharger 18 arranged such that at least in one of the areas 32 an energy / heat transfer from both the exhaust outlet 16 as well as the turbocharger 18 to the coolant 24 can be done. For this purpose, the area can be designed, for example, in the manner of a common cooling channel or a cooling line adjoining both components.

Furthermore, it can be seen from the first exemplary embodiment that the exhaust gas outlet 12 , the turbocharger 18 and the exhaust gas recirculation or the areas 30 the same in the cooling circuit in contrast to the other components or their areas 30 which are in the cooling circuit 26 arranged in series, are arranged in parallel. For this purpose, the cooling circuit shares 26 in front of the exhaust outlet 16 / the turbocharger 18 in two parallel strands 34 which reunite after the coolant 24 the exhaust outlet 16 / the turbocharger 18 and the exhaust gas recirculation 20 has flowed through.

It will be up now 2 Reference is made in which a second embodiment of a cooling system according to the invention is shown. This second cooling system 10 ' is different from the one in 1 illustrated cooling system 10 in that there is a first cooling circuit 26a and a second cooling circuit 26b includes. The remaining components or assemblies correspond to the components / assemblies of in 1 shown first embodiment, which is why the reference numbers of the first embodiment are used accordingly.

Such a design of the cooling system 10 ' with independent cooling circuits 26a and 26b can be provided in particular if an increased cooling capacity is required for one or more of the components / assemblies.

According to the present embodiment takes place by means of the second coolant circuit 26b a cooling of the charge air supply 22 , However, it could also be any other component / assembly or two or more components / assemblies through the second coolant loop 26b be cooled. The two cooling circuits 26a and 26b could be arranged in parallel so that the coolant through a common coolant pump 23 in the cooling circuits 26a and 26b is circulated. In the 2 However, the embodiment shown has two coolant pumps 23a and 23b on, with the coolant pump 23a in the first cooling circuit 26a and the coolant pump 23b in the second coolant circuit 26b is arranged. A corresponding arrangement is also with respect to the heat exchanger 28 possible, according to the present embodiment in the first cooling circuit 26a a first heat exchanger 28a and in the second cooling circuit 26b a second heat exchanger 28b is provided. Both heat exchangers 28a and 28b are air-cooled in a conventional manner and can be arranged separately or combined, for example in a common housing or with a common fan etc.

It will be up now 3 Reference is made, which shows a further embodiment. As before, also in 3 corresponding reference numerals used in the two embodiments described above.

3 shows a cooling system 10 '' which as well as the cooling system 10 ' according to 2 two independent cooling circuits 26c and 26d having. The cooling system shown here 10 '' is also adapted to the second cooling circuit 26d suitable for that is its coolant 24a is formed by raw water or in particular by seawater or seawater and that the first cooling circuit 26c through the second cooling circuit 26d is cooled.

The second cooling circuit 26d has a coolant pump 23c on, which is therefore designed in the manner of a sea or seawater pump, which raw water, for example, seawater or seawater, as is customary in particular ships, directly from the environment sucks and in the second cooling circuit 26d circulated.

The first cooling circuit 26c has a heat exchanger 28c which is designed such that it has a heat or energy transfer from the first cooling circuit 26c or of one in the first cooling circuit 26c circulating coolant 24 to the second cooling circuit or its coolant 24a and a removal of excess energy or heat by the coolant 24a of the second cooling circuit 26d allows.

These are in the first cooling circuit 26c areas 30 provided which an energy or heat transfer from the first cooling circuit 26c or its coolant 24 to the second cooling circuit 26d or its coolant 24a enable. These areas 30 For example, by a wall of the cooling circuit 26c are formed, wherein the wall, for example, the cooling circuits 26c and 26d is common or wherein a first wall of the cooling circuit 26c to a wall of the cooling circuit 26d so adjacent that an energy or heat transfer can take place.

The second cooling circuit 24d According to the present embodiment, it is designed such that it has two strands arranged in parallel 34a and 34b which both of the coolant pump 23c with coolant 24a be supplied and their coolant 24a used coolant 24a higher temperature or higher energy is dissipated together or is returned in the present case via a common output in the ambient water.

Only the first strand 34a leads the heat exchanger 28c coolant 24a for cooling or for energy removal from the first cooling circuit 26c to. The second strand 34b performs a charge air supply 22 coolant 24a to cool them or in appropriate areas 30 which, for example, by a wall of the cooling strand 30 can be formed, an energy or heat transfer from the charge air to the coolant 24a to enable.

According to the in 3 embodiment shown are both the exhaust outlet 16 , the turbocharger 18 , the exhaust gas recirculation 20 and the charge air supply 22 assigned areas 30 arranged in a common unit or they form such. In addition, also the heat exchanger 28c and thus the one energy transfer from the first cooling circuit 26c to the second cooling circuit 26d or their respective coolant 24 . 24c enabling areas 30 as well as the coolant pump 23c which the coolant 24c in the form of raw water or similar through the second cooling circuit 24c leads, into the unit 32 integrated.

Claims (13)

Cooling system ( 10 . 10 ' . 10 '' ) of an internal combustion engine, with several through in the cooling system ( 10 . 10 ' . 10 '' ) circulating coolant ( 24 . 24a ) to be cooled assemblies or parts, the more of the respective modules or the respective component associated areas ( 30 ), in which an energy transfer from the assembly or the component to the coolant ( 24 . 24a ), characterized in that at least two different assemblies or components assigned areas ( 30 ) in a common unit ( 32 ) are arranged. Cooling system according to claim 1, characterized in that at least two of the areas ( 30 ) are arranged parallel and / or in series. Cooling system according to claim 1 or 2, characterized in that at least two of the areas ( 30 ) independently with coolant ( 24 . 24a ) or in independent cooling circuits ( 26 . 26a . 26b . 26c . 26d ) are arranged. Cooling system according to claim 3, characterized in that at least one of the assemblies by one of the cooling circuits ( 26 . 26a . 26b . 26c . 26d ) is formed. Cooling system according to one or more of the preceding claims, characterized in that the unit ( 32 ) adjoins the internal combustion engine or forms part of the same. Cooling system according to one or more of the preceding claims, characterized in that it is in the assemblies or the component to a turbocharger ( 18 ) and / or exhaust gas recirculation ( 20 ) and / or a cylinder head ( 14 ) and / or an engine block ( 12 ) and / or an exhaust outlet ( 16 ) and / or a charge air supply ( 22 ). Cooling system according to one or more of the preceding claims, characterized in that at least one of the areas ( 30 ) is arranged such that an energy transfer of two assemblies / parts can take place. cooling system according to claim 7, characterized in that the assemblies / parts adjoin one another. Cooling system according to one or more of the preceding claims, characterized by at least one coolant pump ( 23 . 23a . 23b . 23c ), which coolant ( 24 . 24a ) in the cooling system ( 10 ) or one or more of the cooling circuits ( 26 . 26a . 26b . 26c . 26d ) circulates. Internal combustion engine with a cooling system ( 10 . 10 ' . 10 '' ) according to one or more of the preceding claims. Internal combustion engine according to claim 9, adapted to a use at least substantially on land or water. Internal combustion engine according to one or more of claims 9 to 11, characterized in that they are substantially stationary or mobile is provided for example in a vehicle or ship. Internal combustion engine according to one or more of claims 9 to 12, characterized in that it is in the internal combustion engine is a diesel, gas or gasoline engine.