DE102011118837A1 - Coolant circuit of an internal combustion engine and a specific for this coolant circuit expansion tank - Google Patents

Abstract

The invention relates to a coolant circuit (1) of an internal combustion engine with a surge tank (2) and a heat exchanger (4). Through a supply line (3), the coolant enters the heat exchanger (4). In an upper area of the heat exchanger (4) there is an outlet opening (6) for the coolant, with a branch through which a main volume flow is supplied to a low-temperature area and through which a secondary volume flow through a vent line (7) in the expansion tank (2 ) is returned. Due to the high flow velocities in the vent line (7), the air present in the heat exchanger (4) is supplied to the lower-positioned expansion tank (2). The vent line (7) is continued in the interior of the expansion tank (2) as a vertical, hollow cylindrical pipe section (10), thus at least partially below a water level (11) of the compensating volume (8) of the coolant in the expansion tank (2). According to the invention an arrangement of the surge tank (2) is achieved, in which the level height (11) in the surge tank (2) during operation below the heat exchanger (4). By the vent line (7) is partially below the level height (11), a pressure equalization between the heat exchanger (4) and the surge tank (2) is prevented. The negative pressure generated by the extraction of the air present in the heat exchanger (4) is thus retained, so that despite the existing gradient within the coolant circuit (1), the coolant volume present in the heat exchanger (4) does not penetrate into the lower regions of the coolant circuit (1). flows.

Description

The invention relates to a coolant circuit of an internal combustion engine, which has a surge tank, which is connected by means of a feed line with a heat engine of the coolant circuit associated with an internal combustion engine or a unit to be cooled of the internal combustion engine, wherein the coolant circuit further comprises a vent line through which the heat exchanger with the surge tank is connected and which opens into the expansion tank with an outlet opening, and wherein the vent line of the expansion tank is disposed at least partially below the minimum fill level provided in the operation in the expansion tank. Furthermore, the invention relates to a surge tank for a coolant circuit of an internal combustion engine.

Such a coolant circuit and a dedicated reservoir are for example by the DE 29 44 865 A1 known, which relates to an arrangement for the compensation of the amount of coolant in cooling systems of internal combustion engines. A main cooling circuit comprises at least one engine cooling chamber, a radiator and a coolant pump. The main cooling circuit is connected by at least two steadily rising lines with a arranged above him gas separation vessel. A gas separation container has a closable filler neck. Above or below the main cooling circuit, a second container is provided, the bottom of which is connected by at least one line to the upper part of the gas separation vessel. The gas separation tank is completely or almost completely filled with coolant. The second container is filled partly with cooling liquid, partly with reserve cooling liquid and partly with gas or vapor bubbles separated out of the main cooling circuit, and with any volume changes of the cooling liquid compensating the air. From the main cooling circuit, two lines lead steadily upwards and open into a gas separation vessel arranged above it, which at the highest point has a filler neck closed with a lid. From the upper part of the gas separation vessel leads from another line to a lower lying second container and opens into the bottom.

One of the lines serves as an inlet and the other as a drain. If gas bubbles or vapor bubbles form in the main cooling circuit, they rise through one of the lines into the gas separation vessel and into the line. As the coolant expands as a result of a change in temperature, it forces the gas or vapor bubbles through the line into the second vessel, where they accumulate and are unable to return to the system. The prerequisite is that the minimum liquid level in the tank is so high that the air can not enter the pipe at the maximum angle of the arrangement.

Furthermore, the describes DE 41 39 767 A1 an evaporative cooling system for an internal combustion engine associated with an oil cooler, wherein a refrigerant line extends between the refrigerant vapor line connecting the machine to a condenser and a condensate line exiting from the condenser leaving therefrom on the pressure side of a condensate pump.

An evaporation cooling is also from the DE 33 39 717 C2 known, wherein the coolant line of the lubricating oil cooler of the internal combustion engine from a arranged in the steam line mist eliminator and opens into a conduit for entrained by the refrigerant vapor liquid coolant.

The DE 10 2006 002 459 A1 refers to a coolant circulation system. When the temperature of the coolant rises and the thermostat is open, the coolant circulating through the engine flows into the upper radiator tank and then circulates within the radiator where it generates bubbles. The coolant is then returned to the engine. The bubbles generated in the radiator flow with the coolant through the radiator branch line into the expansion tank. In the surge tank, the air in the coolant is pressurized because the level of the coolant increases due to expansion of the coolant caused by heating. When the pressure of the air reaches a predetermined limit pressure at the pressure cap, the pressurized air is discharged from the surge tank until the refrigerant no longer contains air. A lower part of the expansion tank is filled with the coolant, an upper part is filled with air. The radiator branch line is connected to the lower part of the expansion tank. Therefore, a check valve is provided in the radiator branch line to prevent backflow of the coolant and the air from the surge tank into the radiator.

The DE 1 206 211 B shows a cooling system with a primary coolant circuit, which is used for cooling the internal combustion engine of a motor vehicle. The cooling system also has a secondary coolant circuit which serves to cool a fluid or an aggregate of the motor vehicle, for example the charge air of the internal combustion engine. For both coolant circuits, a common expansion tank is provided which serves to compensate for coolant volume fluctuations in the coolant circuits and preferably also for venting the coolant circuits.

The generic DE 199 12 138 A1 relates to a cooling system for an internal combustion engine of a motor vehicle. In this case, the primary coolant circuit and the secondary coolant circuit are each connected separately to the surge tank, wherein the connection points are selected so that at a decreasing coolant level in the surge tank first the coolant flow from the surge tank is terminated in the secondary coolant circuit, while a coolant flow into the primary coolant circuit is still possible , In this way, the proper operation of the primary coolant circuit can be maintained longer in the event of coolant loss. In particular, a leak in the secondary coolant circuit can not lead to a malfunction of the primary coolant circuit. This idea is realized in that the mouth of the secondary coolant circuit is arranged in the expansion tank at a hydrostatically higher level than the mouth of the primary coolant circuit. In this case, the vent line of the expansion tank is arranged below the minimum level height in the expansion tank.

In principle, in known coolant circuits all functional elements to be cooled, in particular heat exchangers in which the coolant circulates, are arranged below the coolant level within the expansion tank. In this way, the coolant flows automatically into the lower-lying, connected functional elements and line areas, so that a sufficient degree of filling is ensured.

In practice, it has been found that the arrangement of individual functional elements above the surge tank is desirable in terms of space utilization, so as to improve the freedom of design in the arrangement of flow-through heat exchangers.

One could think of adjusting the volume flow in the coolant circuit such that a reliable flow and a sufficient degree of filling of the heat exchanger are ensured even if it is arranged above the surge tank. On the basis of this dynamic operating state, however, it proves to be a hindrance that the coolant flows into the lower regions of the coolant circuit in the absence of flow, that is to say when the coolant pump is at a standstill.

Considerations have also been made to prevent the undesired backflow of the coolant through check valves or controllable valves. With the realization of such a proposed solution, however, an additional manufacturing effort is required.

Against this background, the invention is based on the object to increase the freedom of design with regard to the arrangement of the expansion tank on the one hand and the flow-through heat exchanger on the other hand. In particular, according to the invention, a relative position of the heat exchanger above the fill level should be realized with a low design effort and low production costs.

This object is achieved with a coolant circuit according to the features of claim 1. The dependent claims relate to particularly expedient developments of the invention.

According to the invention, therefore, a coolant circuit is proposed in which the heat exchanger is arranged at least in sections above the minimum fill level in the expansion tank provided in operation, ie at a relative vertical distance in the effective direction of gravity, so that, for example, an inlet opening for the supply line to the surge tank below the Entry opening of the supply line is located on the heat exchanger. At the same time, the cross-sectional area of the vent line is dimensioned such that the volume flow which can be generated during operation is suitable for extracting air from the heat exchanger and a coolant volume is collected even in the absence of flow in a line section of the vent line which fills the cross-sectional area and closes the line section in a substantially gas-tight manner. The fact that both the surge tank and the vent line are at least partially disposed below the heat exchanger, the achieved by the dynamic process during operation of the coolant circuit and by the air extraction by means of the vent line filling level of the heat exchanger is maintained even if this dynamic flow of the Coolant is interrupted. For while in the arrangements known from the prior art, the vent line opens into the expansion tank with its outlet opening above the level height, so that it to a pressure equalization between the heat exchanger and the surge tank and subsequently to a backflow of the coolant from the heat exchanger through the supply line comes into the expansion tank, this unwanted discharge process of the heat exchanger is excluded according to the invention. The reflux from the heat exchanger into the expansion tank is rather prevented in a surprisingly simple manner that the vent line, preferably in the region of the outlet opening, both in the dynamic operation and in the static state is closed by the coolant volume in the expansion tank. The volume of coolant within the vent line thus closes the Vent line and prevents pressure equalization, so that in the heat exchanger, a negative pressure is obtained, which reliably prevents the return flow of the coolant. In this case, additional valves, in particular check valves are unnecessary, so that the production cost is reduced. The relative arrangement of the heat exchanger relative to the expansion tank is thus almost arbitrary, so that the space utilization can be significantly improved without additional components. The ventilation required for this purpose can be achieved by the manufacturer by filling the coolant circuit under appropriate negative pressure conditions or in operation with a corresponding structural design of the vent line. This allows high flow velocities during operation, which in a manner known per se leads to entrainment of the air trapped in the heat exchanger together with the recirculating coolant and thus to an air extraction into deeper areas below the level in the expansion tank. In this case, the term "below" according to the invention to a relative vertical distance, ie in the effective direction of gravity, based.

The line section of the vent line, which extends within the surge tank below the level in the surge tank, could be formed by an example S-shaped pipe bend similar to a siphon, the lower bend is always filled with coolant and thus significantly reduces the passage of gas or almost excludes. On the other hand, a modification of the present invention is particularly advantageous, in which the venting line is arranged with its outlet opening below the filling level height, in particular in the region of a container bottom of the compensating container. In this case, the vent line enters laterally or from above into the expansion tank, wherein the outlet opening is always below the level height. A backflow of the coolant through the supply line is thereby effectively prevented even when it comes to a dynamic or static flow of coolant within the surge tank, because the outlet opening is disposed adjacent to the container bottom and therefore even a low level still a reliable seal ensures an undesirable air ingress into the vent line.

In another, also particularly promising modification of the invention, the vent line is equipped in the area within the surge tank with a pipe section with a substantial cross-sectional widening. As a result, a significant delay in the flow rate occurs in the area of this pipeline section, so that undesirable foaming can be avoided and a calming of the coolant with the air dispersed therein occurs. Thus, as the refrigerant flowing back through the vent line slowly rises within the tube section with a substantially vertical main extent and low flow velocities are generated at a constant volume flow, unnecessary turbulence of the total equalization volume can be prevented. The pipe section accordingly forms an overflow, through which the coolant rises and through which the outlet opening of the pipe section flows into the remaining coolant volume within the expansion tank. At the same time, the preferably vertical pipe section forms a surge pot, which has a sufficient filling volume even with strong dynamic influences. Due to the pipe section, the vent line initially remains free of coolant when first or re-filling the coolant circuit, as long as the water level in the surge tank is not higher than the outlet opening of the pipe section, thereby allowing static filling or vacuum filling. The upper edge of the pipe section can be arranged above or below the level height.

Furthermore, it has proven to be particularly promising if the vent line has a pipe socket which opens tangentially into the pipe section. Thus, as the coolant does not impinge on an inner wall surface of the pipe section as a baffle, but enters the vertical cylindrical pipe section substantially tangentially, a substantial portion of the kinetic energy of the flow is translated into a swirling flow which is reliably calmed due to the cross-sectional widening the coolant exits through the outlet opening at the upper edge of the pipe section. The tangential inlet also reduces the unwanted bursting of the air bubbles and the associated formation of smaller air bubbles in the water. The small air bubbles rise much more slowly than large air bubbles in the water and are thus a hindrance to preventing foaming.

Another particularly promising embodiment of the invention is also achieved in that the vent line is arranged in the region of a position above the coolant level position on the heat exchanger. As a result, air pockets that can not otherwise be removed by the vent line, reliably avoided.

Preferably, the vent line is arranged in the highest area of the heat exchanger.

According to the invention, the function of the coolant circuit from the relative vertical position of the surge tank relative to the heat exchanger is largely independent, so that in a preferred arrangement of the surge tank, the level in the surge tank during operation is below an inlet opening of the supply line to the heat exchanger, with its outlet opening for a main coolant flow above the inlet opening is arranged. By the coolant flows through the heat exchanger from bottom to top, zones with a reduced coolant exchange are avoided. Through the outlet opening, a main coolant flow reaches downstream regions, for example a low-temperature region.

Furthermore, it proves to be particularly expedient if the expansion tank is arranged below the heat exchanger, so the inlet opening of the supply line of the heat exchanger is positioned above a container top of the expansion tank. As a result, the expansion tank can be arranged in low-lying areas within the motor vehicle, in particular within the engine compartment so as to be able to optimally use free spaces within the engine compartment and to optimize the weight distribution.

An essential function of the vent line is the reliable removal of the coolant and the volume of air dispersed therein due to the prevailing in the vent line in operation high flow velocities. For this purpose, the line cross section within the vent line is substantially smaller than the line cross section of the feed line. For example, the vent line in the region of the heat exchanger has an inner diameter of 3 to 8 mm, preferably about 6 mm.

Basically, the coolant circuit thus created is suitable for a variety of applications, for example, for fixed installations such as air conditioning. A particularly promising embodiment, however, is achieved in that the heat exchanger is designed as an internal combustion engine associated intercooler, so as to cool the combustion air accordingly.

The object is also achieved with a surge tank for a coolant circuit, wherein the surge tank is connected to a heat exchanger through a supply line for coolant and a vent line for returning a partial volume of the heat exchanger coolant supplied during operation and by the vent line enters the surge tank as a pipe socket and, for example, within the surge tank at least partially below the level in the surge tank and the heat exchanger is located above the level in the surge tank. At the same time, the cross-sectional area of the vent line is dimensioned such that the volume flow which can be generated during operation is suitable for extracting air from the heat exchanger, wherein the cross-sectional area of a line section of the vent line is hermetically sealed by the coolant even when the coolant circuit is at a standstill. Starting from a known, occurring during operation minimum level height, the outlet opening of the vent line is thus always below the level height, with the result that no pressure equalization between the heat exchanger and the expansion tank can be done by the vent line. The negative pressure created by the suction of the optionally present in the heat exchanger air to the surge tank is thus reliably maintained, so that despite the existing gradient within the coolant circuit existing in the heat exchanger coolant volume does not flow to the lowest place.

The invention allows numerous embodiments. To further clarify its basic principle, one of them is shown in the drawing and will be described below. This shows in each case in a schematic representation in

1 a coolant circuit with a heat exchanger and a surge tank in a side view;

2 an enlarged side view of the surge tank;

3 an enlarged plan view of the expansion tank.

An inventive coolant circuit 1 an internal combustion engine, not shown, and a in this coolant circuit 1 integrated reservoir 2 will be described below on the basis of 1 to 3 explained in more detail. The expansion tank 2 is through a supply line 3 for coolant with a heat exchanger 4 connected to a charge air cooler. Through the feed line 3 the coolant passes through an inlet opening 5 in the heat exchanger 4 , In an upper area of the heat exchanger 4 there is an outlet opening 6 for the coolant with a branch through which, on the one hand, a main volume flow is supplied to a low-temperature region, not shown, and through the other hand, a secondary volume flow through a vent line 7 in the expansion tank 2 is returned. This is the special nature of the vent line 7 conditioned in the high flow rates occurring therein through a small cross-sectional area in the vent line 7 which is suitable in the heat exchanger 4 carry existing gaseous fluids and the lower positioned compensating tank 2 supply, which is both a compensation volume 8th of the coolant as well as an air volume 9 contains. The vent line 7 is inside the expansion tank 2 as a vertical, hollow cylindrical tube section 10 continued, thus at least partially below a water level 11 the equalization volume 8th of the coolant in the surge tank 2 runs. The pipe section 10 is in its passage cross section opposite the vent line 7 significantly expanded and forms above the water level 11 in the expansion tank 2 one through a horizontal outlet opening 12 formed overflow. In the pipe section 10 There is a significant delay in the flow rate and thus to calm the recirculated coolant. The entrained air thus enters the expansion tank 2 out, without the compensation volume 8th froth. This calming effect is further supported by the fact that the vent line 7 tangential to the pipe section 10 is arranged and thereby a vortex flow 13 generated in the direction of the arrow. As can be seen according to the invention for the first time an arrangement of the expansion tank 2 reached, at which the level height 11 in the expansion tank 2 in operation below the inlet opening 5 the supply line 3 on the heat exchanger 4 and thus at the same time also below the outlet opening 6 on the heat exchanger 4 is arranged. By the vent line 7 below the filling level 11 is located, a pressure equalization between the heat exchanger 4 and the expansion tank 2 prevented. The through the suction of optionally in the heat exchanger 4 existing gaseous fluids produced negative pressure relative to the volume of air 9 in the expansion tank 2 is thus reliably maintained, so that despite the existing gradient within the coolant circuit 1 that in the heat exchanger 4 existing coolant volume not in the lower areas of the coolant circuit 1 flows.

LIST OF REFERENCE NUMBERS

1

Coolant circuit

2

surge tank

3

feed

4

heat exchangers

5

inlet opening

6

outlet opening

7

vent line

8th

compensating volume

9

air volume

10

pipe section

11

filling level

12

outlet

13

vortex flow

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• DE 2944865 A1 [0002]
• DE 4139767 A1 [0004]
• DE 3339717 C2 [0005]
• DE 102006002459 A1 [0006]
• DE 1206211 B [0007]
• DE 19912138 A1 [0008]

Claims (11)

Coolant circuit ( 1 ) an internal combustion engine with a surge tank ( 2 ), which by means of a supply line ( 3 ) with an internal combustion engine or a unit to be cooled of the internal combustion engine associated heat exchanger ( 4 ) of the coolant circuit ( 1 ), wherein the coolant circuit ( 1 ) further a vent line ( 7 ), through which the heat exchanger ( 4 ) with the expansion tank ( 2 ), and at least in sections below the minimum fill level ( 11 ) in the expansion tank ( 2 ), characterized in that the heat exchanger ( 2 ) at least in sections above the minimum level height ( 11 ) in the expansion tank ( 2 ) is arranged such that the cross-sectional area of the vent line ( 7 ) is dimensioned such that the volume flow which can be generated during operation for extracting air from the heat exchanger ( 4 ) is suitable, and that the cross-sectional area of a line section of the vent line ( 7 ) is closed by the coolant. Coolant circuit ( 1 ) according to claim 1, characterized in that the vent line ( 7 ) with its outlet opening ( 12 ) below the fill level ( 11 ), in particular in the region of a container bottom of the expansion tank ( 2 ) is arranged. Coolant circuit ( 1 ) according to claims 1 or 2, characterized in that the vent line ( 7 ) in the area inside the expansion tank ( 2 ) a pipe section ( 10 ) having a substantially increased cross-sectional area. Coolant circuit ( 1 ) according to claim 3, characterized in that the particular cylindrical pipe section ( 10 ) has a substantially vertical orientation. Coolant circuit ( 1 ) according to claim 3 or 4, characterized in that the vent line ( 7 ) tangentially in the pipe section ( 10 ). Coolant circuit ( 1 ) according to at least one of the preceding claims, characterized in that an outlet opening ( 12 ) of the vent line ( 7 ) in an upper region with respect to the container bottom above the filling level ( 11 ) in the expansion tank ( 2 ) is arranged. Coolant circuit ( 1 ) according to at least one of the preceding claims, characterized in that the vent line ( 7 ) in the area above the filling level ( 11 ) arranged position on the heat exchanger ( 4 ) is arranged. Coolant circuit ( 1 ) according to at least one of the preceding claims, characterized in that the expansion tank ( 2 ) is arranged such that the fill level ( 11 ) in the expansion tank ( 2 ) in operation below an inlet opening ( 5 ) of the supply line ( 3 ) on the heat exchanger ( 4 ), which has an outlet opening ( 6 ) for a main coolant flow above the inlet opening ( 5 ) having. Coolant circuit ( 1 ) according to at least one of the preceding claims, characterized in that the expansion tank ( 2 ) below the heat exchanger ( 4 ) is arranged. Coolant circuit ( 1 ) according to at least one of the preceding claims, characterized in that the line cross-section within the vent line ( 7 ) smaller than the line cross-section of the supply line ( 3 ) is dimensioned. Surge tank ( 2 ) for a coolant circuit ( 1 ), the expansion tank ( 2 ) with a heat exchanger ( 4 ) by a supply line ( 3 ) for coolant and by a vent line ( 7 ) for returning a partial volume of the heat exchanger ( 4 ) is connected in operation, wherein the vent line ( 7 ) at least in sections below the fill level ( 11 ) in the expansion tank ( 2 ), characterized in that the heat exchanger ( 2 ) at least in sections above the minimum level height ( 11 ) in the expansion tank ( 2 ) is arranged and the cross-sectional area of the vent line ( 7 ) is dimensioned such that the volume flow which can be generated during operation for extracting air from the heat exchanger ( 4 ), wherein the cross-sectional area of a line section of the vent line ( 7 ) is closed by the coolant.

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