DE102012220447A1 - Engine block structure for internal combustion engine, has lockable input and output units that are connected with coolant spacers of refrigerant circuit, and mixing chamber which is provided in cavity - Google Patents

Abstract

The engine block structure (12) has a refrigerant circuit (10) that is provided with coolant spacers (18,20,22,24,26). A mixing chamber (28) is provided in a cavity (38). The mixing chamber is provided with a separate lockable input unit (30) and separate lockable output units (32,34). The lockable input and output units are connected with the coolant spacers. An independent claim is included for a refrigerant circuit for combustion engine.

Description

The invention relates to an engine block and a coolant circuit for an internal combustion engine.

Engine blocks for internal combustion engines have at least one coolant circuit for cooling the engine block. The coolant circuit is formed by a plurality of partially extending in the engine block coolant lines through which the coolant can flow, and a coolant pump, which pumps the coolant through the coolant circuit and a heat exchanger for dissipating the heat absorbed by the coolant.

More complex coolant circuits have a plurality of coolant lines, which can be supplied separately with coolant, so that a targeted cooling of individual areas of the engine block is possible. Improved temperature control is possible, for example, by mixing coolant at different temperatures and supplying it to the engine block. For this purpose, such a coolant circuit has a mixing chamber in which different coolant flows are mixed, and via which the coolant is supplied to the various coolant lines. However, such mixing chambers require additional space.

The object of the invention is to provide a coolant circuit or an engine block, which has a mixing chamber for a coolant circuit, and has a smaller footprint.

To achieve the object, an engine block for an internal combustion engine is provided, wherein the engine block has coolant lines of a coolant circuit. In the engine block, a mixing chamber is provided in a cavity which has at least one separately closable input and at least one separately closable output for a coolant circuit, wherein the at least one input and the at least one output are fluidly connected to the coolant lines. According to the mixing chamber is not a separate component, but provided in a cavity of the engine block. In particular, the mixing chamber may be formed integrally with the engine block. As a result, no additional component for the mixing chamber is required, whereby no fastening devices for this mixing chamber are required and the assembly costs for the mixing chamber and the coolant circuit is reduced. In addition, the space required for the mixing chamber and thus the coolant circuit is significantly reduced.

Preferably, a particular rigid valve element is provided which can shut off the inputs and the outputs individually and / or together. All inputs and outputs are thus shut off or opened by a common valve element, whereby the number of moving parts in the mixing chamber is reduced. The assembly and maintenance costs are reduced. In addition, the control effort is much lower, since only one drive for a valve element is required.

The valve element can be arranged, for example, in a linearly displaceable manner in the mixing chamber.

However, the valve element can also be arranged to be rotatable and / or pivotable in the mixing chamber.

Regardless of the direction of movement or the movement of the valve element, a drive for the valve element is preferably provided, which moves the valve element in a straight line and / or rotated or pivoted. The valve element may in particular be placed on a connection surface on the engine block, so that the drive closes the mixing chamber tight, so that no additional component for closing the mixing chamber is required. Between the drive and engine block or mixing chamber, an additional sealing element may be provided.

In such an embodiment, the mixing chamber is preferably open to the connection surface, so that, for example, the valve element can be inserted during assembly into the mixing chamber. Subsequently, the mixing chamber can be closed by the drive. It is also conceivable that the valve element is firmly connected to the drive and is mounted together with this.

The cooling lines can for example also be led out of the engine block, so that the connection of an external heat exchanger or a coolant pump is possible. These components are preferably arranged outside the engine block so that they are easy to reach for maintenance or repair work. To solve the problem, a coolant circuit is further provided for an internal combustion engine, with an engine block to be cooled, a coolant pump, a heat exchanger, at least one coolant line and a mixing chamber, the at least one separately closable input and at least one separately closable output and a particular rigid, movably arranged in the mixing chamber valve element for the separate and / or common closing or opening of the inputs and outputs, and having a drive for the valve element, wherein the Mixing chamber according to the invention is arranged in a cavity of the engine block.

Preferably, the coolant lines run at least partially in the engine block, so that no additional external lines are required.

On the engine block, a connection surface can be provided for the coolant pump, at which the coolant line can be led out of the engine block. The number of coolant lines can be additionally reduced. In addition, no separate fastening device for the coolant pump is required.

The coolant pump is arranged, for example, fluidically after the mixing chamber. As a result, the coolant pump is fluidly arranged in front of the engine block, so that the coolant is pressed with low pressure losses from the coolant pump in the engine block.

Preferably, a safety channel is provided, which bypasses the mixing chamber fluidically, so that in case of a defect or a lock of the mixing chamber, the coolant can flow past the mixing chamber and reliably prevents overpressure in one of the coolant lines or the coolant flow and thus the cooling of the engine block can be ensured , In particular, the safety channel may have a temperature-dependent safety valve which opens the safety channel when the temperature in the engine block rises, so that cooling of the engine is ensured. This safety valve is preferably arranged at a position at which the greatest heat in the engine block is to be expected, for example, directly to the cylinder heads.

Further advantages and features will become apparent from the following description taken in conjunction with the accompanying drawings. In these show:

1 a schematic representation of a refrigerant circuit according to the invention, and

2 A second embodiment of a coolant circuit according to the invention.

In 1 is an engine block 12 with a coolant circuit 10 for cooling the engine block 12 shown. The coolant circuit 10 has a coolant pump 14 , a heat exchanger 16 as well as several coolant lines 18 . 20 . 22 . 24 . 26 through which the coolant can flow. Furthermore, a mixing chamber 28 provided by the coolant temperature in the engine block 12 and the flow of coolant through the engine block 12 can be controlled.

The mixing chamber 28 has an entrance 30 on, the fluidic with the coolant line 26 coming from the engine block 12 goes out, is connected. The mixing chamber 28 is preferably arranged so that the coolant line 26 as short as possible. A first exit 32 is about the coolant line 20 fluidically directly with the coolant pump 14 connected. A second exit 34 is about the coolant line 18 with the heat exchanger 16 connected via the coolant line 22 with the coolant pump 14 connected is. The coolant pump 14 is about the coolant line 24 fluidically with the engine block 12 connected.

In the mixing chamber 28 is a valve element 36 provided through which the outputs 32 . 34 can be closed or opened separately or together.

The coolant pump 14 has a constant flow rate and is activated at the start of the engine, with no regulation for the coolant pump 14 is provided. The flow of coolant through the coolant circuit 10 is controlled exclusively via the mixing chamber. Depending on the desired cooling capacity for the engine block, the outputs 32 . 34 blocked and thus the coolant flow are controlled:
Is not cooling the engine block 12 desired, the second output 34 be closed, so that the coolant through the coolant pump 14 exclusively via the coolant lines 24 . 26 . 20 and not through the heat exchanger 16 directed and thus not cooled. This mode is desired, for example, at the start of the engine until it has reached a defined operating temperature.

In contrast, is a cooling of the engine block 12 desired, the first output 32 completely or partially closed and the second exit 34 open, allowing the coolant from the mixing chamber 28 through the coolant line 18 in the heat exchanger 16 directed and cooled by this. Subsequently, the cooled coolant through the coolant lines 22 . 24 in the engine block 12 be guided.

It is also conceivable that both outputs 32 . 34 be opened so that only part of the coolant through the heat exchanger 16 flows and is cooled by this.

As in 1 you can see, is the mixing chamber 28 in a cavity 38 of the engine block 12 arranged and not as a separate component mounted on this. In the embodiment shown here, the mixing chamber 28 integral with the engine block 12 educated.

The mixing chamber 28 is to a connection surface 40 formed open, the part of the surface of the engine block 12 is. At this connection surface 40 is a drive 42 provided with the valve element 36 is coupled and this can adjust so that the outputs 32 . 34 individually or jointly opened or closed.

As the valve assembly passing through the mixing chamber 28 , the valve element 36 and the drive 42 is formed, mainly in the engine block 12 is arranged, is such a coolant circuit 10 or an engine block 12 with such a coolant circuit 10 much more compact. In addition, the assembly is much easier, since only the valve element 36 and the drive 42 on the engine block 12 must be mounted.

As in 1 furthermore, the coolant lines run 18 . 20 . 24 . 26 at least partially in the engine block 12 , The coolant lines 18 . 20 . 24 . 26 are for example produced during the casting process of the engine block or subsequently milled into these. This eliminates the time-consuming laying of the coolant lines 18 . 20 . 24 . 26 or their connection and sealing to the mixing chamber 28 or the engine block 12 ,

The coolant pump 14 For example, it may be designed such that it is attached to a connection surface on the engine block 12 with the coolant lines 20 . 24 is connected, so these coolant lines 20 . 24 completely in the engine block 12 run.

The valve element 36 points for each exit 32 . 34 a sealing element 44 . 46 to close them separately. It is also conceivable that an additional sealing element for the entrance 30 is provided in order to close this too.

The valve element 36 can by the drive 42 be either linearly displaceable or twisted or pivoted by this.

A second embodiment of a coolant circuit according to the invention 10 is in 2 shown. The coolant circuit 10 is essentially the same as in 1 shown coolant circuit. In addition, there is only one security line 46 provided by the coolant line 26 behind the engine block 12 directly to the coolant line 18 in front of the heat exchanger 16 leads. This security line 46 thus bypasses the mixing chamber 28 Completely.

In the security line 46 is a safety valve 48 provided, for example, triggers when exceeding a defined temperature or a defined pressure and the safety line 46 opens. This safety valve 48 is preferably located at a position at the most heat in the engine block 12 is to be expected, for example, directly on the cylinder head.

This can, for example, in case of malfunction of the mixing chamber 28 or the drive 42 of the valve element 36 , a cooling of the engine block 12 be ensured.

When the defined temperature or the defined pressure is exceeded, the safety valve becomes 48 open, so that the coolant after the engine block 12 over the security line 46 can flow directly into the heat exchanger and is cooled by this, before passing through the coolant pump 14 back to the engine block 12 is pumped.

The safety valve 48 For example, there is a wax thermostat with a wax cartridge that melts and expands at a defined temperature, thereby actuating, for example, a spring and the safety line 46 is released. The safety valve 48 is preferably at a position in the engine block 12 provided, which heats up very quickly, for example, directly on the cylinder head.

Inside the engine block 12 can also be a temperature sensor for controlling the valve element 36 in the mixing chamber 28 be provided. The temperature sensor is preferably at a position in the engine block 12 provided, which heats up very quickly, for example, directly to the cylinder heads.

Claims (12)

Engine block ( 12 ) for an internal combustion engine, wherein the engine block ( 12 ) Coolant lines ( 18 . 20 . 24 . 26 ) of a coolant circuit ( 10 ), and wherein in a cavity ( 38 ) of the engine block ( 12 ) a mixing chamber ( 28 ) is provided which at least one separately closable input ( 30 ) and at least one separately closable outlet ( 32 . 34 ), the input ( 30 ) and the output ( 32 . 34 ) fluidically with the coolant lines ( 18 . 20 . 26 ) are connected. Engine block according to claim 1, characterized in that the input ( 30 ) and the output ( 32 . 34 ) individually and / or jointly by a common, in particular rigid valve element ( 36 ) are lockable. Engine block according to claim 2, characterized in that the valve element ( 36 ) in the mixing chamber ( 28 ) is arranged linearly displaceable. Engine block according to claim 2 or 3, characterized in that the valve element ( 36 ) in the mixing chamber ( 28 ) is arranged rotatable and / or pivotable. Engine block according to one of the preceding claims, characterized in that a drive ( 42 ) for the valve element ( 36 ) is provided, which in particular at a connection surface ( 40 ) to the engine block ( 12 ) is attached. Engine block according to claim 5, characterized in that the mixing chamber ( 28 ) on the connection surface ( 40 ) open and by the drive ( 42 ) is closed. Engine block according to one of the preceding claims, characterized in that the coolant lines ( 18 . 20 . 24 . 26 ) are led out of the engine block. Coolant circuit ( 10 ) for an internal combustion engine, with an engine block to be cooled ( 12 ), a coolant pump ( 14 ), a heat exchanger ( 16 ), at least one coolant line ( 18 . 20 . 22 . 24 . 26 ) and a mixing chamber ( 28 ) having at least one separately closable entrance ( 30 ) and at least one separately closable outlet ( 32 . 34 ), as well as with a particular rigid, movable in the mixing chamber ( 28 ) arranged valve element ( 36 ) for separately or jointly closing the inputs ( 30 ) and outputs ( 32 . 34 ), and a drive ( 42 ) for the valve element ( 36 ), wherein the mixing chamber ( 28 ) in a cavity ( 38 ) of the engine block ( 12 ) is arranged. Coolant circuit according to claim 8, characterized in that the coolant lines ( 18 . 20 . 22 . 24 . 26 ) at least partially in the engine block ( 12 ). Coolant circuit according to claim 8 or 9, characterized in that the engine block ( 12 ) a connection surface for the coolant pump ( 14 ), at which the coolant line ( 20 . 24 ) is led out of the engine block. Coolant circuit according to one of claims 8 to 10, characterized in that the coolant pump ( 14 ) fluidically after the mixing chamber ( 28 ) is arranged. Coolant circuit according to one of claims 8 to 11, characterized in that a safety line ( 46 ) with a particular temperature and / or pressure-dependent safety valve ( 48 ) is provided which the mixing chamber ( 28 ) bypasses fluidically.

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