WO2009024392A1 - Method and corresponding device for cooling a control unit of a vehicle - Google Patents

Abstract

The invention relates to a method for cooling a a control unit (28) of a vehicle having an internal combustion engine (4) and a cooling device (10) which cools the internal combustion engine (4) and which has a fan (22). There is provision for the fan (22) to cool the control unit (28) as a function of a detected control unit temperature (T) by means of at least one partial air flow. Furthermore, the invention relates to a corresponding device (44).

Description

 description

Title method and corresponding device for cooling a

Control unit of a vehicle

The invention relates to a method for cooling a control unit of a vehicle having an internal combustion engine and a cooling device cooling the internal combustion engine, which has a fan.

State of the art

A method for cooling a control unit of a vehicle with an internal combustion engine is known. The controller is for example the

Control unit of the internal combustion engine itself, which is arranged for example together with the internal combustion engine and the engine cooling the cooling device in an engine compartment of the vehicle. Alternatively, the control unit is a control unit of another component of the vehicle, such as a control unit of the transmission or a control unit of the brake system. Since modern control units have sensitive electronics, they are encapsulated in a control unit housing against external influences. By encapsulation, however, the heat dissipation of the electronics of the control unit is severely limited. When the controller is in an environment which in turn has high temperature heat sources, such as the engine in the engine compartment of the vehicle, the controller heats up due to the power dissipation of its electronics and further to heat introduced from the environment. The temperature of the internal combustion engine is reduced during operation by means of a cooling device cooling the internal combustion engine. The cooling device is designed in particular as liquid cooling, preferably as water cooling, in which a liquid coolant is transported by a cooling circuit from the internal combustion engine to a cooler in which it is cooled by means of an air flow flowing around the surface of the cooler. The air flow is generated by a dynamic pressure of the moving vehicle and / or the fan. The cooled coolant is then returned to the engine via an inlet of the coolant circuit. The fan of the cooling device is controlled as a function of a coolant temperature, so that the cooling device can provide a sufficiently high cooling capacity even at a low vehicle speed.

If the temperature input from the internal combustion engine and / or the waste heat of the electronics of the control unit is so high that the temperature in the housing of the control unit reaches a critical temperature threshold, individual functions of the control unit are limited by a thermal management electronics implemented in the control unit. Such a limitation is, for example, the limitation of the number of injections per unit time in the internal combustion engine and / or a limitation of operating parameters for reducing the power of the internal combustion engine. These limitations reduce both the power consumption of the controller and the heat input from the environment. However, the operating range of the internal combustion engine is severely restricted by this intervention of the thermal management electronics.

Disclosure of the invention

For functional restriction-free cooling of the control unit it is provided that the fan cools the control unit as a function of a determined control unit temperature with at least one partial air flow. The determined controller temperature is a determined temperature that corresponds to the temperature in a housing of the controller. The determination of the controller temperature may, for example, be a direct measurement of the temperature in a housing of the controller or the detection of a quantity from which the temperature of the controller can be deduced. The controller is in an environment that in turn has heat sources, such as an internal combustion engine in the engine compartment of a vehicle, so the controller is heated on the one hand by the power loss of its own electronics and further by the introduced from the environment heat. The temperature of the internal combustion engine is in operation by means of a cooling device cooling the engine reduced. The cooling device is designed in particular as liquid cooling, preferably as water cooling, in which a cooling liquid is transported through a cooling circuit from the internal combustion engine to a cooler in which it is cooled by means of an air flow flowing around the surface of the cooler, for example by the fan of the cooling device is produced. The cooled coolant is then returned to the internal combustion engine via a supply line of the coolant circuit. The fan is controlled as a function of a temperature of the heated coolant from the engine. For cooling the control unit by means of an air flow or at least a partial air flow of the fan fan and control unit are arranged so that the control unit is cooled by the air flow of the radiator or the partial air flow of the radiator, in particular cooled by a recirculation. The flow around the controller for cooling takes place in dependence on the determined controller temperature. In this case, the control unit temperature controls, for example, the orientation of an air guide element with which the partial air flow is directed more or less in the direction of the control unit.

In an advantageous embodiment of the invention, it is provided that the fan for cooling the control unit in dependence on the determined

Control unit temperature is controlled. If the control unit is arranged so that it is in the air flow or at least a partial air flow during operation of the fan, then a control / regulation of the speed of the fan takes place in dependence on the determined control unit temperature. The control is, for example, a two-point control, in which the fan is turned on reaching an upper threshold and - if it is not needed for cooling the coolant - is switched off when a lower lower threshold is reached.

According to a development of the invention, it is provided that the determination of the control unit temperature is a detection of the control unit temperature in the control unit. The detection of the controller temperature is preferably carried out by means disposed in the housing of the controller temperature sensor. It is advantageously provided that the fan is continuously operated at a determined control device temperature above a first critical temperature limit regardless of its operating function in the cooling device. Due to the continuous operation of the fan, the control unit is cooled until the control unit temperature has fallen to a value below the first critical temperature limit. In particular, it is provided that the rotational speed of the fan is controlled as a function of a temperature difference between the control unit temperature and the temperature limit.

In an advantageous embodiment of the invention, it is provided that the fan is operated at a determined controller temperature below a release temperature only in dependence on its operating function in the cooling device. Thus, the fan is operated at a determined controller temperature below the release temperature, for example, only in dependence on the temperature of the coolant (coolant temperature) of the cooling device.

In a preferred embodiment of the invention, it is provided that the control unit is an engine control unit for controlling the internal combustion engine. If the engine control unit is arranged in the vicinity of the internal combustion engine, then it is particularly exposed to the strong heat input of the internal combustion engine itself. However, in this arrangement in an engine compartment of the vehicle, the engine controller may be arranged to be at least in a partial airflow of the fan of the cooling device.

It is preferably provided that the operation of the control unit is limited at a determined control unit temperature above a second critical temperature limit lying above the first critical temperature limit. Such a restriction is in an engine control unit in particular a limitation of the performance of

Internal combustion engine and / or the number of Einspitzungen per unit time in the internal combustion engine. By these measures, on the one hand reduces the heat loss of the power electronics in the control unit and at the same time limits the heat introduced from outside - in this case by the internal combustion engine as the largest heat source of the vehicle. Such a restriction on the operation of the Internal combustion engine takes place in particular by regulating a thermal management electronics. This is preferably arranged in the control unit of the internal combustion engine.

The invention further relates to an apparatus for carrying out the method mentioned above. It is envisaged that the control unit is located in at least a partial airflow of the fan. By this arrangement, the control unit is cooled by the air flow or partial air flow of the fan by flowing around. The control unit is in particular the engine control unit of the internal combustion engine.

Preferably, it is provided that the device has a device for determining the control device temperature and a drive device for driving the fan in dependence on the determined controller temperature. The device for determining the controller temperature is preferably a temperature sensor or has at least one temperature sensor. The temperature sensor is preferably arranged in the interior of the housing of the control device. The drive device is preferably an existing control device for driving the fan as a function of its operating function in the cooling device.

Additionally or alternatively, it is advantageously provided that the device for determining the control unit temperature and / or the control device for controlling the fan in the control unit are formed.

Brief description of the drawings

In the following, the invention will be explained in more detail with reference to drawings. To show:

1 shows an engine compartment of a vehicle, with an internal combustion engine, an engine control unit of the internal combustion engine and a cooling device for cooling the internal combustion engine and Figure 2 shows three diagrams in which a controller temperature, a

Fan activity and thermal management activity are plotted over time.

Embodiment (s) of the invention

1 shows a schematic representation of an engine compartment 2 of a vehicle with an internal combustion engine 4 arranged in the engine compartment 2. In a front region 6 of the engine compartment 2, which is also the front of the vehicle, is a cooler 8 of a cooling device 10 for cooling the

Internal combustion engine 4 is arranged. The radiator 8 is part of a cooling circuit of the radiator 10 in which a cooling liquid (cooling water) is exchanged between the radiator 8 and the engine 4. For this purpose, the cooling device 10 has a connecting line 12 connecting the radiator 8 with the internal combustion engine 4 and a return line 14 connecting the internal combustion engine 4 with the radiator 8. In the return line 14, a thermostat 16 for measuring the heated by the engine 4 cooling liquid is arranged. In the feed line 12 a pumping the coolant through the cooling circuit pump 18 is arranged. The radiator 8 is formed by a tube and fin system with tubes and punched ribs placed over it (not shown). At sufficiently high vehicle speed, a back pressure develops, so that the tubes of the radiator 8 are surrounded by fresh air, which cools the liquid coolant (the cooling liquid) in the tubes. In order to ensure a corresponding cooling capacity of the radiator 8 even at low speeds, the cooling device 10 has a fan 22 on a side of the radiator 8 facing the combustion engine 4. This fan 22 is operated by a control device of the cooling device 10 for cooling the internal combustion engine 4 in response to the measured from the thermostat 16 return temperature of the cooling liquid. This is the operating function of the fan 22 in the cooling device 10.

To control the internal combustion engine 4, a control unit 28 embodied as a motor control unit 26 is arranged in a construction space 24 of the engine compartment 2 between the fan 22 and the internal combustion engine 4 such that it is arranged in a partial airflow (arrows 30) of the fan 22. The control unit 28 has an enclosed by a housing 32 control electronics 34 for controlling the engine 4. Within the housing 32, the control unit 28 further comprises a temperature sensor 36 designed as means 38 for determining the controller temperature T, with the controller temperature T is determined in the interior of the housing 32 by the detection of the temperature T. A part of the control electronics 34 is designed as a thermal management electronics 40, the functions of the internal combustion engine 4 at a detected control unit temperature T above a second critical temperature limit T2 shuts off. The (existing) control device for controlling the fan 22 as a function of the measured temperature of the coolant by the thermostat is also used as a drive means 42 for controlling the fan 22 in response to the detected by the temperature sensor 36 in the housing 32 control unit temperature T. For this purpose, the control device 42 receives a signal from the device 38. Fan 22, device 38 and control device 42 are part of a device 44 for cooling the control device 28.

This results in the following function of the device 44: At a control device temperature T below a first critical temperature limit T1, the fan 22 is operated only as a function of its operating function in the cooling device 10, ie in dependence on the temperature of the cooling fluid measured by the thermostat 16 , Increases the controller temperature T to a temperature above a first critical temperature limit T1, the fan 22 is operated independently of its operating function in the cooling device 10 permanently. Since the controller 28 is in the partial air flow (arrow 30) of the fan 22, this is cooled by the permanent operation of the fan 22 until the controller temperature T falls to a value below a release temperature at which the fan 22 is operated only in dependence on its operating function in the cooling device 10. This is preferably equal to the first critical temperature T1. If the controller 28 can not be cooled down to the release temperature by the cooling, it remains with a continuous operation of the fan 22. Increases the controller temperature T despite cooling by the partial air flow (arrow 30) of the fan 22 and reaches a second critical temperature limit T2, which is above the first critical temperature limit T1, the operation of the Control unit 28 is limited by the thermal management electronics 40 of the control unit 28. With this additional measure, the power consumption of the control electronics 34 of the control unit 28 is reduced. In the control unit 28 designed as an engine control unit 26, the restriction is at the same time a limitation of the operating range of the internal combustion engine 4, so that its heat input into the engine compartment 2 and thus into the control unit 28 is reduced ,

FIG. 2 shows, in three diagrams, the relationship between a fan activity AL of the fan 22 and a thermal management activity ATder

Thermal management electronics 40 of the controller 28 and a history of the controller temperature T. The upper diagram shows the course of the controller temperature T, the diagram below the activity AL of the fan 22 (fan in operation: 1 / fan off: 0) and the lower diagram shows the thermal management activity AT (thermal management active: 1 /

Thermal management inactive: 0) over a time t. In the time profile shown, the controller temperature T increases in a first time window t1 to the first critical temperature T1. Then the fan 22 is set by the control electronics in operation. In a subsequent second time window t2, the controller temperature T is above the first critical temperature T1, so that the fan 22 is operated continuously. At the end of the second time window t2, the partial airflow of the fan 22 has cooled the control unit 28 to such an extent that the control unit temperature T is again below the first critical temperature T1 in a subsequent third time window t3. Since in this case the first critical temperature T1 is also a release temperature, below which the fan 22 is operated only in dependence on its operating function in the cooling device 10, the fan 22 is inactive in the third time window t3. At the end of the third time window t3, the control unit temperature T has risen again to the first critical temperature limit T1. The fan 22 is set again by the drive means 42 in operation. In a fourth time window t4, the controller temperature T rises despite the permanently operated fan 22 from the first critical temperature limit T1 to a second critical temperature limit T2, which is above the first critical temperature limit T1. Upon reaching the second critical temperature limit T2, the thermal management electronics 40 limits the Operation of the controller 28, so that the controller temperature T in a subsequent fifth time window t5 shows a decreasing curve 46. Without the intervention of the thermal management electronics 40 results in a further increasing profile 48 of the controller temperature T. The second diagram shows the corresponding fan activity AL in the five time windows t1 to t5 and the third diagram shows the corresponding activity AT of the thermal management electronics 40th in the same five time windows t1 to t5.

Advantage of the inventive method for cooling the controller 28 is the additional cooling of the controller 28 by means of the partial air flow (arrows 30) in the time window t2, without the controller temperature T of the controller 28 at a much earlier date, the second critical temperature limit T2 would have reached, whereby the thermal management electronics 40 would have already much earlier limited the operation of the controller 28 and thus the internal combustion engine 4.

Claims

claims

A method of cooling a control unit of a vehicle having an internal combustion engine and a cooling device cooling the internal combustion engine, which has a fan, characterized in that the fan cools the control unit as a function of a determined control unit temperature with at least a partial air flow.

2. The method according to claim 1, characterized in that the fan for cooling de control unit in dependence on the determined

Control unit temperature is controlled.

3. The method according to any one of the preceding claims, characterized in that the determination of the controller temperature is a detection of the controller temperature in the control unit.

4. The method according to any one of the preceding claims, characterized in that the fan is operated at a determined controller temperature above a first critical temperature limit regardless of its operating function in the cooling device continuously.

5. The method according to any one of the preceding claims, characterized in that the fan is operated at a determined controller temperature below a release temperature as a function of its operating function in the cooling device.

6. The method according to any one of the preceding claims, characterized in that the control device is an engine control unit of the internal combustion engine.

7. The method according to any one of the preceding claims, characterized in that the operation of the control unit at a detected control unit temperature above one above the first critical Temperature limit lying second critical temperature limit is restricted.

8. Apparatus for carrying out the method according to at least one of the preceding claims, characterized in that the

Control unit (28) in at least a partial air flow of the fan (22).

9. Apparatus according to claim 8, characterized by means (38) for determining the controller temperature (T) and a drive means (42) for driving the fan (22) in dependence on the determined controller temperature (T).

10.Vorrichtung according to any one of claims 8 or 9, characterized in that the means (38) for determining the controller temperature (T) and / or the drive means (42) in

Control unit (28) are formed.