EP3097285A1

EP3097285A1 - Method and device for ventilating a heat management system of an internal combustion engine

Info

Publication number: EP3097285A1
Application number: EP15700319.5A
Authority: EP
Inventors: Rainer Richter; Wolfram Enke; Wolfgang Hofmann
Original assignee: Bayerische Motoren Werke AG
Current assignee: Bayerische Motoren Werke AG
Priority date: 2014-01-23
Filing date: 2015-01-15
Publication date: 2016-11-30
Anticipated expiration: 2035-01-15
Also published as: US20170030252A1; WO2015110344A1; US11085357B2; CN105745412A; EP3097285B1; CN105745412B; DE102014201170A1

Abstract

To ventilate a heat management system (10) of an internal combustion engine (12), in which coolants circulate in several coolant circuits (36, 46, 50), connected inlets (42, 48, 52) of a rotary valve (20) are opened and closed in a predetermined sequence, in order to ventilate one or more of the coolant circuits (36, 46, 50) in the direction of the compensation tank (22), by means of at least one ventilation circuit (72, 74) which is in fluid connection with a coolant compensation tank (22). Said rotary valve (20) is controlled by means of a control unit (54), wherein a non-connected inlet (60) of the rotary valve (20) is in fluid connection with the coolant compensation tank (22).

Description

Method and device for venting

a thermal management system of an internal combustion engine

The invention relates to a method and a device for venting a thermal management system of an internal combustion engine. Thermal management systems of modern internal combustion engines consist of many different sub-circuits in which circulates coolant. When refilling coolant or as a result of repair, air may enter the system and coolant lines. For proper operation of the system, the air must be evacuated. The invention has for its object to provide a simple way to vent a thermal management system.

According to the invention, this is achieved with a method for venting a thermal management system of an internal combustion engine in which coolant circulates in a plurality of coolant circuits, in which switched inputs of a rotary valve are opened and closed in a predetermined order to one or more of the coolant circuits via at least one with a coolant -Alüftungsbehälter in vented vent line in the direction of the expansion tank to vent.

As is known, the coolant surge tank is in contact with the environment of the internal combustion engine so that the air can escape from the system. By the targeted switching of the rotary valve and thus the targeted opening and closing of individual coolant circuits Teilten the trapped in the coolant lines air with the coolant flow is selectively transported in the direction of the or the vent lines and pushed over this in the expansion tank. The sequence of opening and closing the inputs and outputs of the rotary valve is tunable to the conditions of the thermal management system and is independent of the operating positions of the rotary valve in the other operation of the internal combustion engine.

The internal combustion engine is preferably idling during the bleeding process, so that the heat management system can be vented even when using a mechanically driven coolant pump without the connection of an additional pump. It is also possible to operate the internal combustion engine at short intervals at increased speed. Another option is to increase the idling speed for the duration of the bleeding program. In the swept sequence of opening and closing the inputs of the rotary valve, for example, the individual inputs of the rotary valve can be opened briefly, so that a pulsed coolant flow can occur in certain coolant lines of the system.

It is also possible to selectively open only a single of the coolant circuits and to vent these.

The control sequence for switching the rotary valve is preferably stored in the control unit. It is of course possible to provide several control sequences that are used for venting certain coolant circuits and / or in certain situations. The venting method is preferably carried out only during maintenance, for example as part of a workshop visit and in a special venting mode of the control unit. However, it is also possible to carry out the venting process when needed also in vehicle operation to keep subcircuits permanently free of air. An inventive apparatus for venting a thermal management system of an internal combustion engine comprises a coolant surge tank, a control unit which controls a rotary valve having switched inputs, which are connected to an engine cooling circuit and a main radiator circuit, wherein at least one of the refrigerant circuits via a vent line with the coolant reservoir is connected. The coolant surge tank is preferably connected to an unswitched input of the rotary valve. On This way, by connecting the Kühlmittei Ausgleichsbehäiters directly with the rotary valve and the vent line by selectively specifying a sequence of switching positions of the rotary valve in the coolant lines of the cooling circuits existing air are selectively moved in the direction of the coolant expansion tank.

Also, a heating circuit and / or a bearing block cooling an exhaust gas turbocharger may be fluidly connected to the venting device.

Preferably, the rotary valve can also occupy intermediate positions in which a plurality of partial circuits are simultaneously opened completely or partially.

It is possible to open the connecting line to the coolant expansion tank in the same input of the rotary valve as a return of an exhaust gas turbocharger cooling circuit or a transmission oil cooling circuit, which is preferably not connected. In this way, no separate input for the coolant Ausgieichsbehälter must be provided on the rotary valve, which reduces its production and reduces its space.

The invention is described in more detail below with reference to two exemplary embodiments and with reference to the attached drawings, in which: FIG. 1 shows a schematic view of a thermal management system in a first variant, with an apparatus for carrying out a venting method according to the invention; and

FIG. 2 shows a schematic view of a thermal management system in a second variant, with a device for carrying out a venting method according to the invention.

FIG. 1 shows a thermal management system 10 for an internal combustion engine 12 (here a series four-cylinder gasoline engine).

Among other things, coolant flows through an engine block of the internal combustion engine 12, an air-cooled main cooler 14 and a heating heat exchanger 16 in a plurality of coolant circuits. The coolant is moved mainly by a coolant pump 18 which is mechanically driven here. The coolant streams are controlled via a rotary valve 20 whose inputs are connected to the recirculations of the coolant circuits and whose output is in direct flow communication with the coolant pump 18, as will be described in detail later. In addition, a coolant expansion tank 22, a transmission oil heat exchanger 24, an engine oil heat exchanger 26 and an additional, electrically operated coolant pump 28 are provided, the latter being in fluid communication with a heat exchanger (housing cooling) of an exhaust gas turbocharger 30. The electrically driven additional coolant pump 28 in this example has a power of about 20-150 W.

The main radiator 14 is supported by a fan 32. In addition, an auxiliary cooler 34 is provided to support the main radiator, which may be formed for example as Radhauskühler.

In an engine cooling circuit 36 (also referred to as "small cooling circuit"), cold coolant is transported from the coolant pump 8 to an engine block of the internal combustion engine 12, more specifically to cooling ducts in the cylinder head housing and crankcase where it absorbs waste heat before it is collected in a line 38 A short-circuit line 40 leads from the collecting line 38 to a first switched input 42 of the rotary valve 20. The short-circuit line 40 also forms the return of the engine cooling circuit 36.

The engine cooling circuit 36 can be interrupted here by an engine shut-off valve 43 in its coolant supply line downstream of the coolant pump 18.

A coolant line 44, which is part of a main cooler circuit 46 which leads back through the main cooler 14 and via a return 47 to a connected second input 48 of the rotary valve 20, passes from the collecting line 38.

From the line 44 branches off an inlet of a heating circuit 50, in which the heating heat exchanger 16 is arranged, which can deliver heat to a vehicle interior. The return 51 of the heating circuit 50 leads to a third switched input 52 of the rotary valve 20. A non-switched, single output 53 of the rotary valve 20 leads via a short line 55 to the coolant pump 18.

The position of or the rotary valve of the rotary valve 20 and thus the opening degree of the switched inputs 42, 48, 52 is predetermined by a control unit 54, which may form part of an engine electronics. In the control unit 54 data are stored, which allow a map control function of predetermined operating conditions of the internal combustion engine 12. In this example, the states of other components such as the heater core 16, the exhaust gas turbocharger 30, the engine oil heat exchanger 26 and data from temperature sensors 56 in the engine block or in the coolant line 44 to the main cooler 14 are taken into account. Depending on these parameters, the position of the switched inputs of the rotary valve 20 is determined.

The additional electric coolant pump 28 is located in an exhaust gas turbocharger cooling circuit 58 which cools the exhaust gas turbocharger 30 and which opens into a non-switched input 60 of the rotary valve 20. The exhaust gas turbocharger cooling circuit 58 is supplied by a branch from the engine cooling circuit 36 (not shown here in detail).

The engine oil heat exchanger 26 is connected directly to the manifold 38 of the engine cooling circuit 36. Cold coolant is supplied to the coolant pump 18 through a branch 62. A control is not provided in this example, but would be realized by an additional thermostat.

The coolant expansion tank 22 leads via a connecting line 70 to the return flow of the exhaust gas turbocharger cooling circuit 58, which opens into the non-switched input 60 of the rotary valve 20. Vent lines 72 and 74 connect the coolant surge tank 22 to the engine cooling circuit 36, more specifically the manifold 38 and the inlet to the main radiator 14 in the main radiator circuit 46. The transmission oil heat exchanger 24 is located in a rotary valve 20 independent transmission oil cooling circuit 76 and is by its own Thermostat valve 78 connected. This is a conventional wax thermostat which opens the transmission oil cooling circuit 76 at a predetermined temperature and closes it below this temperature. The transmission oil cooling circuit 76 leads through the engine block in a feed line 80, which opens into the coolant line 55. The orifice point is upstream of the coolant pump 18 but downstream of the outlet 53 of the rotary valve 20. From the engine cooling circuit 36, a line 82 branches between the coolant pump 18 and the engine shut-off valve 43, passing through the main radiator 14 and back to the transmission oil heat exchanger 24 (low temperature loop ) leads. This is only necessary for vehicles with transmission cooling.

The coolant pump 18 is here integrated directly into the engine block of the internal combustion engine 12. The rotary valve 20 is in this embodiment form the front side of the engine block of the internal combustion engine 12 in the immediate vicinity of the coolant pump 18 attached.

If the input 48 of the rotary valve 20 is closed by the control unit 54, the flow of coolant through the main cooler 14 in the main cooler 46 is prevented. This condition is taken especially when starting the internal combustion engine 12 and in a partial load operation.

If the input 42 of the rotary valve 20 is open, then the coolant flows via the short-circuit line 40 from the hot side of the internal combustion engine 12 directly into the rotary valve 20 and is from there via the coolant pump 18 directly back to the cold side of the internal combustion engine 12.

In addition, when the inlet 52 of the rotary valve 20 is open, coolant flows through the heating circuit 50 via the heater core 6. The switching of the inputs 42 and 52 permits multiple operating conditions. When both the inlet 42 and the inlet 52 are open, the engine cooling circuit 36 and the heating circuit 50 are flowed through in parallel. The flow conditions are chosen so that a significantly larger volume flow through the engine cooling circuit 36 flows as through the heating circuit 50, as is known. In this operating state, for example, the internal combustion engine 12 can be heated to its operating temperature while the vehicle interior is heated at the same time. If the inlet 42 is fully or partially closed, the flow through the engine cooling circuit 36 reduces, so that the load on the coolant pump 18 is reduced. Through the open heating circuit 50, heat can be dissipated and a targeted circulation of the coolant can be maintained. Due to the higher flow resistance of the coolant flow rate is reduced by the internal combustion engine 12. This can be used for faster heating during a cold start.

If the input 52 is fully or partially closed, then the heating circuit 50 is disconnected and is not flowed through. This is the one case, if no heating function is desired, so the vehicle occupants have turned off the heater.

Another purpose is a driving situation in which the load of the internal combustion engine 12 suddenly increases, for example, when driving uphill or abruptly accelerating. In this case, closing the heating circuit 50 in combination with opening the input 42 of the engine cooling circuit 36 and optionally the input 48 of the main radiator circuit 46 results in the entire coolant flow being available for cooling the internal combustion engine 12 so that temperature peaks are avoided. In the warm-up phase of the internal combustion engine, the inputs 42, 48 and 52 are closed to at least substantially interrupt a flow of the coolant in the engine cooling circuit 36 and thus a faster heating. to reach. In order to prevent cavitation on the suction side of the coolant pump 18, the engine shut-off valve 43 is also closed here.

The main cooler circuit 46 is switched on and off by opening or closing the inlet 48 of the rotary valve 20. This can be done (within the scope of the design of the rotary valve 20) independently of the opening or closing of the engine cooling circuit 36 and of the heating circuit 50 and also be independent of temperature by specifications of the control unit 54. The flow through the engine can be controlled here, inter alia, in Warmiauf and in relevant consumption cycles for optimal heat distribution and friction optimization by controlling the rotary valve 20 and the Motorabsperrventils 43. These functions are also stored in the control unit 54.

The control unit 54 also has a stored ventilation program that ^'eihenfolge a Ansteuerr for different positions of the rotary valve 20 includes.

This program can be executed, for example, for maintenance purposes in a workshop equipped for this purpose. The internal combustion engine 12 is idling. If the normal idle speed is insufficient, the speed can be increased briefly or the idle speed can be raised to a much higher level for the duration of the bleeding program.

By deliberately opening and closing the individual coolant circuits, for example the engine cooling circuit 36, the main radiator circuit 46 and the heating circuit 50, air present in the lines can be transported via the vent lines 72, 74 to the reservoir 22, where the air is separated.

This control of the switchable inputs 42, 48, 52 of the rotary valve 20 is completely independent of the control of the rotary valve in other operating conditions and serves only the targeted direction of the coolant through the vent lines 72, 74, so entrained air is deposited in the surge tank 22 ,

It can be useful, for example, to close all inputs at short notice and at predetermined intervals in order to force the coolant into the vent line 72, 74. It is also conceivable to specifically collect air in components and then deposit by defined opening of the partial circuits in the expansion tank 22.

Also, the individual coolant circuits can be briefly opened and closed again in quick succession in order to transfer air from one circuit to the other and thus bring it to the expansion tank 22. It is equally possible to selectively operate only one of the circuits and to selectively open and close valves which may be present on the vent lines 72, 74.

The venting program or programs are stored in the control unit 54 and can be retrieved in a maintenance mode or an assembly mode, in which case the control sequence is automatically executed.

Figure 2 shows a second embodiment of a thermal management system 10 ', wherein for already introduced components, the already known reference numerals continue to be used. Changed but similar components are designated by the known reference numeral with a dash.

In contrast to the embodiment shown in Figure 1, the internal combustion engine 12 'here is a six-cylinder in-line engine, which leads to space reasons that the rotary valve 20 is not arranged end side, but along a longitudinal side of the engine block of the internal combustion engine 12.

Also for reasons of space, the return line 47 'of the main cooler circuit 46' leads piece by piece through the engine block of the internal combustion engine 12 'to the switched input 48' of the rotary valve 20.

In the physical arrangement in the rotary valve 20, the inlet 42 'in the second embodiment corresponds to the inlet 42 in the first embodiment and vice versa. However, the function of the rotary valve 20 is analogous to that in the first embodiment.

In this embodiment, the return of the exhaust turbocharger cooling circuit 58 'opens into the conduit 44 upstream of a branch of the shorting line 40' to the rotary valve 20.

The inlet of the exhaust gas turbocharger cooling circuit 58 'branches off downstream of an outlet from the engine block from a supply line 82 of the transmission oil cooling circuit 76' to the main cooler 14. As in the first example, the return of the transmission oil cooling circuit 76 'from the transmission oil heat exchanger 24 leads to the unswitched input 60 of the rotary valve 20. The connecting line 70 from the coolant expansion tank 22 opens here in the return of the gear oil cooling circuit 76 ', which leads to the non-switched input 60 of the rotary valve 20.

All features not described in connection with FIG. 2 are identical in construction and function to those described in FIG.

As the two embodiments described above show, the principle according to the invention of using a rotary slide valve with switched and unswitched inputs for targeted separation of a heating circuit and for switching the engine circuit and the main cooler circuit, but also the central connection of other cooling circuits such as the Getriebeöl- Cooling circuit and the exhaust gas turbocharger cooling circuit can be easily implemented for various internal combustion engines in a flexible manner. Accordingly, the person skilled in the design of heat management systems according to the invention is free, wherein all the features of the two embodiments can be combined with one another at will or exchanged for one another.

Claims

claims

1. A method for venting a thermal management system (10, 10 ') of an internal combustion engine (12, 12') in which coolant circulates in a plurality of coolant circuits (36, 46, 50, 36 ', 46'), characterized that

switched inputs (42, 48, 52, 42 ', 48', 52 ') of a rotary valve (20) are opened and closed in a predetermined order to form one or more of the refrigerant circuits (36, 46, 50, 36'; 46 ') via at least one with a coolant surge tank (22) in fluid communication vent line (72, 74) in the direction of the surge tank (22) to vent.

2. The method according to claim 1, characterized in that the internal combustion engine (12; 12 ') during the venting operation at idle and / or at short intervals with increased speed runs.

3. The method according to any one of the preceding claims, characterized in that the inputs (42, 48, 52, 42 ', 48') of the rotary valve (20) are each opened briefly.

4. The method according to any one of the preceding claims, characterized in that in each case only one of the coolant circuits (36, 46, 50, 36 ', 46') is open.

5. The method according to any one of the preceding claims, characterized in that at least one control sequence for switching the rotary valve (20) in a rotary valve (20) controlling the control unit (54) is stored.

6. An apparatus for venting a thermal management system (10) of an internal combustion engine (12; 12 ') with a coolant surge tank (22), a control unit (54) which controls a rotary valve (20), the switched inputs (42, 48, 52 42 ', 48') fluidly connected to an engine cooling circuit (36, 36 ') and a main radiator circuit (46, 46'), at least one of the coolant circuits (36, 46, 50, 36 ', 46 ') is connected via a vent line (72, 74) with the coolant expansion tank (22).

7. The device according to claim 6, characterized in that a non-switched input (60) of the rotary valve (20) is fluidly connected to the coolant surge tank (22).