EP2225465A1

EP2225465A1 - Method, apparatus, and use of the apparatus for controlling a compressor

Info

Publication number: EP2225465A1
Application number: EP08868417A
Authority: EP
Inventors: Marek Engelhardt
Original assignee: Continental AG
Current assignee: Continental Teves AG and Co OHG
Priority date: 2007-12-21
Filing date: 2008-10-20
Publication date: 2010-09-08
Also published as: DE102007062313B4; JP5443382B2; JP2011506836A; US20100303637A1; DE102007062313A1; WO2009083286A1

Abstract

Method for controlling a compressor for delivering a pressure medium into a pressure medium system, for example an air suspension system in a motor vehicle, in which method the delivery of the pressure medium can be switched on and off as a function of a temperature signal by the compressor temperature being measured by means of a temperature sensor which is arranged on the compressor and the switching on and off of the compressor being controlled by an electronic control unit, wherein the switching-on time duration and/or the switching-off time duration or the switching-off and/or the switching-on temperature are/is determined from the rise of the compressor temperature which is measured at short time intervals.

Description

description

Method, device and use of the device for controlling a compressor

The invention relates to a method for controlling a compressor for conveying a pressure medium in a pressure medium system, in which the delivery of the pressure medium in response to a temperature signal on and off by the compressor temperature is measured by means of a compressor arranged on the temperature sensor, a pressure medium system with a Compressor and an electronic control unit that controls the on and / or off time or the switch-off and / or the switch-on of the compressor, and the use of an electronic control unit for a pressure medium system with a compressor for controlling the switch-on and / or the switch-off or the switch-off and / or the switch-on temperature of the compressor.

A method and a device of this kind are described in EP 1 253 321 A2.

This method for controlling a compressor, which is suitable for conveying pressure medium in a pressure medium system, serves to turn on and off the delivery of the pressure medium into the pressure medium system as a function of the temperature signal of a temperature sensor. It is to achieve a good utilization of the compressor by avoiding too frequent on and off operations. This is achieved in that the pressure medium delivery is switched off when the temperature signal exceeds a temperature limit, wherein the temperature limit value can be fixed in dependence on the backpressure caused by the pressure medium system. The temperature signal-dependent shutdown criteria for the compressor can still be subordinated time criteria by the compressor when reaching a Time limit is switched off. Likewise, a restart of the compressor after a switch-off and after cooling to a predetermined restart temperature and / or after a predetermined cooling time can take place.

According to this document, the superimposed control is preferably applied according to time criteria at low outside temperatures, that is, when the temperature at the cylinder head of the compressor due to a good heat dissipation to the environment with the compressor on slowly increases and quickly drops again when the compressor is off. In this case, the controller is to assist in terms of reducing the startup frequency of the compressor without reducing the availability according to time criteria. The time criteria for switching off and restarting the electronic control unit in this case should take into account primarily to the temperature limit and the restarting temperature.

This means - according to this document - that after the expiration of the time limit, the compressor is switched off, even if the temperature limit has not yet been reached. A restart of the compressor should then take place only after the expiry of the pre-defined cooling time, even if the reclosure temperature is not reached. In the case of pure temperature criteria, the compressor would be switched back on reaching the restarting temperature, ie already after a relatively short cooling time. However, restarting should also take place according to a time criterion, namely when a predefined cooling time has been reached. Only at this time the compressor is switched on again.

By this subsequent restart of the compressor, a cooling to a lying below the reconnection temperature level should be achieved, which extends the subsequent allowable running time of the compressor accordingly. By placing the time criteria under the temperature signal-dependent shutdown criteria for the compressor with cold compressor to ensure that the internal parts of the compressor, which reach the allowable temperature faster than the area of the compressor, where the Temperature sensor is arranged, which do not exceed critical temperature and will be better protected against temperature damage.

In DE 103 54 491 Al a method for controlling a compressor for conveying pressure medium in a pressure medium system is described, which is intended for a closed level control system of a motor vehicle. In this method, the current compressor temperature is constantly determined at least during the compressor run and the compressor is switched off at the latest when reaching a limit temperature, taking into account for determining the current compressor temperature of the form and the back pressure of the compressor in a closed system.

Preferably, during the compressor run after each past time unit, the current compressor temperature is adjusted by a correction value that depends on the difference between the back pressure and the pre-pressure.

The invention has for its object to provide a method for controlling a compressor, a pressure medium system with a compressor and an electronic control unit and a use of the electronic control unit for the pressure medium system with a compressor, which improve the utilization of the compressor and the avoidance of frequent Ein - and shutdown offers.

Based on this task, a method for controlling a compressor for conveying a pressure medium in a pressure medium system is proposed, in which the delivery of the pressure medium in response to a temperature signal on and off by the compressor temperature is measured by means of a compressor arranged on the temperature sensor and the Switching on and off the

Compressor is controlled by an electronic control unit. It is provided that the switch-on time and / or the switch-off or the switch-off and / or the switch-on of the compressor from the slope of the measured at short intervals compressor temperature is determined. The invention is based on the consideration that the internal temperature of the compressor and the components therein, in particular the pressure valve, heat up faster and reach a critical temperature than can be determined by the temperature sensor arranged on the compressor housing, which only monitors the wall temperature of the compressor. For example, the cylinder head, can measure. The faster the temperature rise measured by the temperature sensor, the greater the temperature deviation between the compressor interior and the temperature measured by the temperature sensor, that is, the internal temperature of the compressor increases even faster than the temperature measured by the temperature sensor on the compressor. If the compressor temperature is measured according to the invention at short time intervals, the slope of the temperature profile or the temperature rise per unit of time can be determined from this and from this a turn-off signal and / or a switch-on signal can be calculated. This switch-off or switch-on signal can be determined as a time signal, after which the compressor is switched off and / or switched on. It is also possible to determine the switching signal as a temperature signal by determining the switch-off temperature and / or the switch-on temperature of the compressor from the slope of the compressor temperature curve.

In order to achieve a continuous adjustment of the switch-on and / or switch-off time, the slope of the compressor temperature curve is determined continuously after each switch-on and / or switch-off.

According to the considerations underlying the invention, the turn-on and / or Ausschaltzeitdauer the shorter or the turn-off and / or the switch-on determines the lower, the steeper the slope of

Compressor temperature curve is. As a result, the even faster increase in the compressor internal temperature is taken into account and prevents internal components of the compressor from exceeding a critical temperature. In order to be able to carry out the ongoing control after each switch-on and / or switch-off operation, the slope of the compressor temperature curve is preferably determined by measuring the compressor temperature with a frequency of 2 Hz.

A further refinement of the control of the compressor can be achieved if the measured compressor temperature at the time of switching on and / or off in the sense of an additional shortening of the switch-on when determining the switch-on and / or the switch-off or the switch-off and / or the switch-on - And / or the off period or a reduction of the switch-off and / or the switch-on temperature are taken into account, the lower the measured compressor temperature at the time of switching on and / or off.

In order to obtain the smallest possible difference between the internal compressor temperature and the compressor temperature measured by the temperature sensor, the compressor temperature is preferably measured by means of a temperature sensor arranged on the cylinder head of the compressor part of the compressor.

A further improvement of the control can be achieved if, for determining the switch-on and / or switch-off duration or the switch-off and / or the switch-on temperature, the ambient temperature in the sense of shortening the switch-on and / or off-time or a reduction of the switch-off and / or the switch-on temperature at low ambient temperature and vice versa is taken into account.

In a manner analogous to this, a refinement of the method result can also be achieved if, for determining the switch-on and / or switch-off duration or the switch-off and / or switch-on temperature, the driving speed of a motor vehicle provided with an air suspension system that passes through the compressor with compressed air is supplied, in the sense of an extension of the switch-on and / or a shortening of the switch-off or an increase the switch-off and / or the switch-on at high speed and vice versa is taken into account.

The above object is further achieved by a pressure medium system with a compressor and an electronic control unit, which controls the switch-on and / or the switch-off or the switch-off and / or the switch-on of the compressor with the method according to the features indicated above. Furthermore, the above object is also achieved by the use of an electronic control device for a pressure medium system with a compressor for controlling the switch-on and / or the Ausschaltzeitdauer or the switch-off and / or the switch-on of the compressor according to the above-mentioned method features.

The invention will be explained below on the basis of temperature curves for the switch-on phase and for the switch-off phase of the closer one. In the drawing shows

1 shows different temperature curves during a switch-on phase, FIG. 2 shows different temperature curves during a switch-off phase.

The curves T ¹ Zk ₁ and T Va and T ² Zk ₁ and T ² _z ka show idealized temperature profiles of the cylinder head inner temperature T _z kϊ and the cylinder head outside T _z ka over time, if they develop slowly and in parallel, so that the respective maximum temperatures T _max are achieved substantially simultaneously, the curves T ¹ ZkI and T Va apply to a new compressor, while the curves T ² Zk ₁ and T ² _z ka apply to a compressor towards the end of the compressor life. Accordingly, towards the end of the compressor life, a compressor has a runtime gain (FIG. 1) as well as a difference in the respective cooling times (FIG. 2) with respect to a new compressor.

In actual operation, these curves do not run like the illustrated ideal curves T ¹ ZkI and T Va and T ² Zk ₁ and T ² _z ka, since various influences such as Cooling conditions of the cylinder head outside, for example, depending on the driving speed and the outside temperature, which can change constantly noticeable.

The dot-dashed temperature curve T ³ _z k _a corresponds to a temperature profile with reduced cooling of the cylinder head outside. The temperature rise is steeper and the maximum is reached earlier. The corresponding temperature profile of the cylinder head temperature T ³ _Zk1 , however, is significantly steeper because of the given, limited thermal conductivity of the cylinder head material, and the maximum of the cylinder head temperature is reached much earlier than the maximum temperature of the cylinder head outside. Accordingly, the compressor must be switched off earlier, in order not to exceed the critical temperature for the cylinder head interior or not to let act too long. This earlier shutdown is considered according to the invention in such a way that an electronic control unit for the compressor is programmed so that it determines the shutdown time or the shutdown temperature in dependence on the slope of the temperature profile of the cylinder head outside. The steeper the temperature profile of the cylinder head outer side, the more the switch-off time is brought forward or the switch-off temperature is lowered.

The temperature profile of the cylinder head outside is measured by means of a temperature sensor arranged at the cylinder head of the compressor with a frequency of 2 Hz, and from the temperature difference .DELTA.T measured at each measuring step and the time interval .DELTA.t the slope is determined. From this, the control unit, as already explained, calculates the switch-off time or the switch-off temperature. The slope of the

Cylinder head outside temperature history is determined during each turn-on and / or turn-off operation to account for rapid changes in turn-on and turn-off parameters.

From the illustrated temperature curves of the Cylinder Head Mnentemperatur and the cylinder head outside for a compressor towards the end of its life apply the Considerations analog, but with a shift towards a longer running time of the compressor during the switch-on.

If the initial temperature To ^Start at the beginning of a switch-on phase is lower than shown in FIG. 1, then the temperature of the cylinder-head outer side increases more slowly, that is, with a lower slope, while the cylinder-head temperature rises faster in proportion, since the heat dissipation to the outside through the Thermal conductivity of the cylinder head material is limited. Accordingly, the start temperature of each switch-on phase by the control unit can be taken into account in such a way that the switch-off time is advanced at low initial temperatures To ^Start or the switch-off temperature is lowered.

From Fig. 2, the cooling curves are visible at weak and stronger cooling of the compressor cylinder head and consequently the cooling curves of the cylinder head interior. Also in this case, the cooling rate of the

Cylinder head interior of the cooling rate of the cylinder head outside in such a way that the Zylinderkopfmnere a rapid cooling of the cylinder head outside to a sufficiently low for a restart of the compressor sufficiently low temperature (T _as the _g ut) can follow, so that in this case by the control unit an extension of the switch-off is set in dependence on the slope of the cooling curve. Here too, similar considerations apply analogously to the case of different ambient temperatures and cooling conditions dependent on the driving speed, which are recorded by the control unit and taken into account for the calculation of the switch-on times or switch-off temperature and / or the switch-off time duration or the switch-on temperature.

For example, the driving speed of the vehicle can either be taken into account continuously, or a change in the system parameters of the temperature model is made when a specified driving speed is exceeded. Laboratory measurements on the compressor, which also measure the temperature of the cylinder head interior and / or the critical elements, such as exhaust valves, allow the exact temperature history to be determined for different initial conditions and changes during operation. From this, detailed maps for cooling and compressor aging can be stored in the control unit, which then calculates the respective switch-on duration or switch-off temperature and / or the respective switch-off duration or switch-on temperature based on the parameters currently available and the measured temperature curve of the compressor cylinder head and the compressor accordingly controls.

In this way, a better utilization of the compressor running time can be achieved, and the control behavior of the system is improved.

Claims

claims

1. A method for controlling a compressor for conveying a pressure medium in a pressure medium system, wherein the promotion of the pressure medium in response to a temperature signal on and off by the compressor temperature is measured by means of a temperature sensor arranged on the compressor and the switching on and off of Compressor is controlled by an electronic control unit, characterized in that the Einschaltzeitdauer- and / or Ausschaltzeitdauer or the switch-off and / or the switch-on of the compressor from the slope of the measured at short intervals compressor temperature is determined.

2. The method according to claim 1, characterized in that the slope of the compressor temperature is determined after each switch-on and / or switch-off.

3. The method according to claim 1 or 2, characterized in that the switch-on and / or the Ausschaltzeitdauer the shorter or the switch-off and / or the switch-on be determined the lower, the steeper the slope of the measured compressor temperature curve.

4. The method according to any one of claims 1 to 3, characterized in that the

Slope of the compressor temperature curve is determined by measuring the compressor temperature with a frequency of 2 Hz.

5. The method according to any one of claims 1 to 4, characterized in that the determined compressor temperature at the time of switching on and / or off in the sense of an additional when determining the switch-on and / or the Ausschaltzeitdauer or the switch-off and / or the switch-on Shortening of the switch-on and / or the switch-off or a reduction in the switch-off and / or the switch-on, the lower the measured compressor temperature at the time of switching on and / or off.

6. The method according to any one of claims 1 to 5, characterized in that the compressor temperature is measured by means of a arranged on the cylinder head of the compressor part of the compressor temperature sensor.

7. The method according to any one of claims 1 to 6, characterized in that for determining the switch-on and / or the Ausschaltzeitdauer or off and / or the switch-on the ambient temperature in terms of shortening the switch-on and / or off or a reduction in the switch-off and / or the switch-on temperature at low ambient temperature and vice versa.

8. The method according to any one of claims 1 to 7 in connection with an air suspension system in a motor vehicle, characterized in that for determining the switch-on and / or the switch-off or off and / or the switch-on the driving speed in the sense of an extension of

Switch-on and / or a shortening of the switch-off or an increase of the switch-off and / or the switch-on at high speed and vice versa is considered.

9. pressure medium system with a compressor and an electronic control unit, which controls the switch-on and / or the Ausschaltzeitdauer or the switch-off and / or the switch-on of the compressor with the method according to one of claims 1 to 8.

10. Use of an electronic control device for a pressure medium system with a compressor for controlling the switch-on and / or the Ausschaltzeitdauer or the switch-off and / or the switch-on of the compressor with the method according to one of claims 1 to 8.