EP1480842A1 - Method for compensating temperature in a tyre pressure monitoring system - Google Patents

Abstract

Disclosed is a method for compensating temperature in a tyre pressure monitoring system wherein tyre pressure and/or a loss of tyre pressure is detected. The method is especially characterised in that the temperature is compensated by determining the gas temperature in the tyre by means of at least two items of temperature information and by taking the determined gas temperature as a basis for said tyre monitoring . One significant advantage of the inventive method is that externally active temperature changes, such as a heat-emitting brake disk, whereby the wheel rim of the tyre and a temperature sensor arranged therein is heated more intensely than the gas in the tyre, do not lead to an indication error with respect to the tyre pressure (or a warning error).

Description

Method for temperature compensation in a tire pressure monitoring system

The invention relates to a method for temperature compensation in a system for monitoring tire pressure, which is carried out in particular by detecting a tire pressure and / or by detecting a loss of tire pressure.

Systems for tire pressure detection are already known, in which the tire pressure is determined on the basis of tire pressure measurement modules that measure the tire pressure and send a corresponding measured value to a receiver installed in the vehicle (also called TPMS, that is to say "tire pressure monitoring system"). Such a module can be mounted in the rim near the valve, for example, or can be structurally combined with the valve. A known system based on the pressure measurement uses a rotating wheel module in each wheel, which is integrated in the valve and measures the tire pressure and the tire temperature by means of appropriate sensors. This data is transmitted wirelessly to a receiver installed in the vehicle and processed in an electronic evaluation device. The received and processed measured values are used either to display a pressure value or to generate warning signals when the tire pressure threshold values fall below a predetermined value, i. H. used when a tire pressure loss is detected.

When using a direct measuring system such as TPMS, there is a need to display a tire pressure value that is independent of the ambient conditions, in particular the temperature. It is generally perceived as unpleasant if a pressure value displayed in the dashboard fluctuates excessively, although z. B. only changed the driving condition or the outside temperature. A method for detecting, evaluating and displaying the value of a tire pressure is known from US Pat. No. 4,909,074, an information signal representing a detected pressure being compared with a plurality of specifically selectable, desired value curves. These value curves represent pressure ranges for specific values of the ambient temperature and the inner tire temperatures (as well as of the ambient pressure, if applicable) with respective dependent tolerance ranges. If the comparison shows that the actual tire air pressure lies outside the tolerance range, a corresponding signal is sent generated. Furthermore, the information signal can be compared with a desired tire air pressure, which is assigned to a predetermined maximum speed. A maximum safe speed can then be output depending on the result of the comparison.

With this method, the ambient temperature is thus taken into account when recording, evaluating and displaying a tire pressure or its permissible value. However, with this method as well as with the TPMS method mentioned at the outset, there is still the problem that the temperature, which is known in a manner known per se, for B. is measured in the valve, is essentially the rim temperature and not (necessarily) the actual temperature of the gas in the tire.

The rim temperature does not correspond to the temperature of the gas in the tire, especially in the case of relatively rapid temperature fluctuations. For example, it may be that the brake disc of the motor vehicle and, as a result, the rim heats up relatively quickly, which results in a temperature gradient between the tire and the rim and the gas temperature is initially substantially lower than is indicated by the sensor signal.

Furthermore, it can happen that the outside temperature changes suddenly and strongly (motor vehicle is driven out of a garage, for example). This change can also lead to the said undesirable temperature gradients or incorrect measurements of the gas temperature due to different heat conduction and different specific heat of the materials and the associated much faster change in the temperature of the rim compared to the mounted tires.

Furthermore, methods for tire pressure loss detection are known which work without pressure sensors, such as. B. the system DDS (Deflation Detection System), from Continental Teves, Frankfurt am Main. In these systems, a change in the rolling circumference of the tire caused by a change in pressure is recorded and evaluated. As with the systems mentioned above, there may also be a desire in these or other systems to display a pressure value that is independent of the gas temperature in the tire, on the one hand, and on the other hand there may be the problem that a sensor used to detect and compensate this temperature due to external influences such as a hot brake disc, does not indicate the actual gas temperature in the tire, but rather a higher (or under other influences possibly also a lower) temperature, so that the temperature compensation is carried out incorrectly.

The invention is therefore based on the object of providing a method for temperature compensation in a system for tire pressure monitoring of the type mentioned at the outset, with which a temperature-compensated gas pressure in a tire is determined in a relatively simple manner with relatively high accuracy even in the event of external temperature fluctuations and, if appropriate, additionally can be displayed according to the temperature-adjusted value for the tire pressure.

This object is achieved according to claim 1 with a method mentioned at the outset, which is characterized in that the temperature compensation takes place by determining the gas temperature in the tire on the basis of at least two temperature information items and the determined gas temperature is used as the basis for monitoring the tire pressure.

An advantage of this solution is that the risk of a false alarm due to a tire pressure that is too high or too low or tire damage can be at least substantially reduced.

Another advantage of this solution is that the temperature information can also be determined on the basis of a calculated temperature model, so that no temperature sensors are required.

The subclaims contain advantageous developments of the method. As is known, the measured pressure of a real gas is according to the Bolzmann equation

P * V = n * k * T, (1)

with P = pressure, V = volume, n = number of particles, k = Bolzmann constant and T = temperature, also dependent on the temperature at which the pressure was measured. Corresponding equations can be set up for real gases, such as air.

A gas according to the conceptual definition according to the invention is understood to include air.

Resolved after printing, the following equation results:

P = (n * k * T) / V. (2)

Assuming that n and V are constant, the pressure P is proportional to the temperature T.

The temperature is determined directly by means of physically available temperature sensors and / or via temperature variables which are derived from other parameters present in the motor vehicle. These parameters are preferably variables which describe the driving state and which are particularly preferably available anyway in an electronic brake control unit with ABS and / or ESP. The tire condition, which provides information about the temperature of the tire, can then be determined from the driving condition variables. The driving state variables are preferably determined partially or entirely from sensor information (e.g. wheel speed, yaw rate, lateral acceleration, brake actuation, etc.).

The following sensor-specific temperature information can preferably be evaluated individually or in combination with one another. It is also possible to determine two or more temperature information by repeating the same temperature information at intervals or multiple times:

Temperature sensors of tire pressure sensors, which are mounted on the rim, for example, outside temperature sensor (s)

Temperature sensor / s of an electronic control unit, in particular a brake control unit and brake disc temperature sensor / s.

In addition to the physical temperature sensors mentioned above, temperature information to be calculated can also be used. As described above, this temperature information can be derived from vehicle dynamics variables and is referred to below as "virtual temperature".

According to the invention, the following virtual temperatures can in turn preferably be used individually or in combination with one another:

- virtual temperature of the brake disc and

- virtual temperature of the tire. The gas temperature determined or estimated in this way is preferably used in a method according to the invention.

The following formula is used as a basis for calculating the pressure of the pressure, for example, for a dashboard arranged in the pressure display (display), or to detect the falling below a critical limit ^¬:

ΔP = ΔP _T0 + ΔP _k , (3)

with ΔP _T0 = n * k * ((T _mess - T ₀ ) / V (4) and ΔP _k = n * k * ΔT _k / V. (5)

where ΔT _{k is} a correction temperature to be determined in the manner described below, with which the current temperature T _meSs , in particular determined via the tire pressure _sensor , must be corrected.

A: Determine the constant proportions of the calculation formula

In order to be able to carry out the above-mentioned conversion of the determined pressure into a pressure to be displayed, the constant C = n * k / V is first determined by interpolation of the curve P _mess (Tm _e ss) according to the method of the invention.

The interpolation is particularly preferably carried out by measuring two or more pressure and temperature value pairs P _x , Ti, which are approximated according to the linear regression method by a straight line P _mess = C * T _meS s. The value of the constant C is very particularly preferably permanently stored in a memory of an electronic control unit, so that it is available even after the ignition is restarted. In particular, the accuracy of the interpolation is gradually increased by constantly adding new P _m ess,: T _meS s, i ~ value pairs. As a result, the accuracy of the interpolation can advantageously be continuously increased over time.

B: Compensation of the determined tire temperature

It is z. B. in the dashboard using the determined gas temperature to a reference temperature T ₀ (z. B. room temperature, 20 ° C) and this converted value is displayed as the current tire pressure value based on the temperature To. Alternatively, of course, a correction pressure ΔP _T0 can also be calculated.

C: Temperature correction

If the temperature of the temperature sensor used to determine the pressure (e.g. temperature sensor of the TPMS wheel module) does not match the gas temperature, this must be corrected.

Cl: Correction of the tire pressure temperature measurement value on the basis of the detection of a dynamic in the temperature measurement value The temporal behavior of the temperature information of a sensor and / or one or more of the above-mentioned virtual temperatures is therefore preferably considered. If a change in the temperature information obtained in this way is determined, the expected end temperature is preferably estimated by considering the change over time in the course of the temperature. This estimation can be carried out particularly preferably by interpolation using an exponential function. In this way, for example, an expected final temperature value ΔT ₀ can be calculated. For example, if only two temperature values are known, an exponential function can already be determined.

The correction to be made then results in:

ΔT _k = ΔT ₀ * exp (-a * t). (6)

The correction value is expediently reduced as a function of time according to this formula, so that the measured pressure value approaches the displayed pressure value more and more.

C2: Correction of the temperature measurements using additional temperature information

The temporal behavior of the temperature information can be determined in particular by a tire pressure sensor, an outside temperature sensor or a virtual sensor. With a tire pressure sensor and an outside temperature sensor, the measured temperature values can be used directly to determine the exponential function.

C2.1: Correction of the tire temperature value using the brake disc temperature

If the information from a brake disc temperature sensor is evaluated, information is obtained about the heating of the tire air, which is caused by the radiation from the brake disc. The quantity of heat transferred from the brake disc to the tire is preferably estimated from the difference between the brake disc temperature and the tire temperature with the aid of a proportionality constant that can be determined experimentally, for example. The compensation temperature T _k determined in this way is assumed to be the difference between the old temperature and the new temperature. The time course of this is determined using an exponential function to be determined, as shown in FIG. 2. In this way, a time-dependent course of T is obtained. In the course of the function over time, the correction temperature approaches a constant value ΔT ₀ . The value of

ΔT _k0 can be determined experimentally and stored in the system.

C2.2 Correction of the tire temperature value by calculating the temperature of the tire from dynamic parameters (virtual temperature)

The virtual tire temperature is preferably calculated by using driving state variables which are shown in a control unit of an electronic braking system are available anyway, such as. B. wheel torque M, longitudinal acceleration aι _angS , or lateral acceleration a _que r- The current tire condition is particularly preferably determined from the driving condition. The calculation can be expressed using the following formula:

T _R eι _f en, ι = f (driving dynamics), (7)

where f is a mathematical function and i specifies one of the tire positions in the vehicle.

The tire temperature is viewed in particular as the sum of individual temperature elements which have an influence on the tire temperature. These individual "tire temperature components" are summed up over time as follows:

- Reιfen, ι = Σ Be t

Δ Ti tires (8)

The calculation is preferably carried out separately for each tire. An example of a calculation formula is given below:

ΔT _Rei f _e n = α * M * Δt + (9) ß * a _slow * Δt + γ * a _transverse * Δt -

Ö (egg ~ ~ tumor) ^ -1 Δt,

in which ki is the heat transfer coefficient between the tire and the environment,

Δt is a time interval, e.g. B. is the loop duration of the electronic brake controller,

Tu _{MGE ung} the temperature measured by an outside temperature sensor ^¬, and α, ß, γ, δ are proportionality factors, which can be determined experimentally, for example, and reflect the respective influence of the physical quantity on the tire temperature.

The experimentally ascertainable quantities can then be regarded as tire-independent if the temperature or pressure correction to be carried out according to the invention is to be regarded as sufficient, with a certain inaccuracy. If a particularly high correspondence between the estimated tire air temperature and the actual tire air temperature is desired, it can be expedient and expedient to vary the above-mentioned proportionality constants depending on the type of tire.

Time-dependent considerations

If the constant C and the correction temperature ΔT _{k have been} determined in accordance with the above method, the measured tire pressure value is corrected.

The differential pressure 1 ΔP | is in each case around the part | ΔP _k | which increases due to an assumed temperature error (measured temperature to tire air temperature) could be caused.

The pressure difference ΔP _k is:

| ΔP _k | = C * | ΔT _k | * exp (-a * t). (10)

This value is reduced exponentially with time t.

A corresponding (additional) correction term is obtained by taking the temperature measured at the outside temperature sensor as follows:

ΔP is additionally increased by the part ΔP _k that was estimated via the signal from the outside temperature sensor:

ΔP _k | = C * | ΔT | (11)

Thereby | ΔT 1 estimated downwards to Δ (T _outside -tire-

I ΔT | is estimated upwards to MAXi (T _aU ßen, i - T _Re ifensen- so _r , i) * exp (-a * t), whereby i is counted over all tires of the vehicle.

The invention will be explained below with the ^aid of two case examples, which are shown in the figures. It shows: Fig. 1 is a schematic representation of the time course of the temperatures determined in the event of a sudden change in the outside temperature and

Fig. 2 is a schematic representation of the time course of the temperatures determined when the tire is heated by a heated brake disc.

In FIG. 1, curve 1 shows the course of the outside temperature, which was measured with a sensor. Curve 1 jumps from approx. + 15 ° C to a lower temperature of approx. - 20 ° C. Such a jump can occur, for example, when a motor vehicle is pulled out of the garage in winter. Curve 2 shows the course of the rim temperature (temperature signal from the pressure sensor). Curve 3, which shows the signal of a temperature sensor of an electronic brake system arranged in the engine compartment, has a flattened profile compared to curve 2. This temperature sensor is preferably arranged in the control device of an electronic braking device (e.g. ECU). The temperature of the tire, which is represented by curve 4, changes comparatively slowly compared to curves 1 to 3. All curves 2 to 4 have in common that they run approximately according to an exponential function.

The end value for the rim temperature can be estimated from the course of curve 2. The end value can then, provided that the tire's exp function constant is known, the time and the end temperature of the tire at which a full temperature compensation can be assumed, can be estimated.

In contrast to FIG. 1, FIG. 2 shows the temperature profile of sensor information when the tire temperature is increased due to heating by the brake disc. B. can occur during a long downhill or continuous braking intervention of a traction control system.

The brake disc temperature is shown by curve 5 and initially rises steadily. This can either be determined via a sensor or, according to the temperature model described above, can be determined arithmetically from the driving dynamics. The temperature recorded with a tire temperature sensor is shown in curve 4. This rises more slowly than the temperature of the brake disc. The tire air temperature finally shows curve 6. This in turn rises more slowly than the temperature detected by the tire temperature sensor 4 and thus even more slowly than the temperature of the brake disc.

It can also be seen in FIG. 2 that the correction temperature ΔT _k approaches a constant value ΔT ₀ after a period A after which the brake disc temperature no longer increases significantly. During this time period A, the calculation of the correction temperature or the compensation of the temperature is preferably suspended or interrupted.

Claims

claims

1. A method for temperature compensation in a system for tire pressure monitoring, in particular by detecting a tire pressure and / or by detecting a tire pressure loss, characterized in that the temperature compensation is carried out by determining the gas temperature in the tire on the basis of at least two temperature information items and the determined gas temperature is used as the basis for the tire pressure monitoring becomes.

2. The method according to claim 1, characterized in that at least one temperature information is based on a temperature sensor on or in the rim of the tire.

3. The method according to claim 1, characterized in that at least one temperature information is based on a temperature sensor on a brake disc.

4. The method according to claim 1, characterized in that at least one temperature information is based on a temperature sensor in the engine compartment of the vehicle.

5. The method according to claim 1, characterized in that at least one temperature information is a sensor for an outside or ambient temperature. tire is used as a basis.

6. The method according to claim 1, characterized in that at least one temperature information is based on a calculated temperature model.

7. The method according to claim 6, characterized in that the temperature model is a temperature model of the tire.

8. The method according to claim 6, characterized in that the temperature model is a temperature model of a brake disc on the tire.

9. The method according to at least one of claims 1 to 8, characterized in that a pressure value determined for the tire is corrected with the determined gas temperature.

10. The method according to claim 9, characterized in that the pressure value is determined by means of a pressure sensor arranged in the tire.

11. The method according to claim 9, characterized in that the pressure value is determined on the basis of the rolling circumference or a speed information of the tire.