EP1214206A1 - Device for monitoring and wirelessly signalising the pressure in tyres on vehicles - Google Patents

Abstract

Die Einrichtung zum Uberwachen und drahtlosen Signalisieren eines Drucks oder einer Druckänderung in Luftreifen von Rädern (1) an Fahrzeugen (2) besteht aus einem im oder am Fahrzeug (1) vorgesehenen Empfangsgerät (9), zu welchem wenigstens eine Antenne (6, 7) gehört, und aus einem in dem Luftreifen angeordneten Gerät (3) zum Messen, Auswerten und Senden von Reifendrucksignalen, nachfolgend als 'Radelektronik' bezeichnet, welches eine Batterie (24) als Stromquelle; einen Drucksensor, welcher den im Luftreifen herrschenden Druck aufnimmt; eine Auswerteschaltung, welche die vom Drucksensor gelieferten Druckmesssignale auswertet; und einen Sender (21) enthält, welcher von der Auswerteschaltung gesteuert wird und Signale, welche eine Information über den Druck im Reifen und/oder über den Zustand der Radelektronik (3) enthalten, an das Empfangsgerät (9) übermittelt; wobei Radelektronik (3) in zeitlichen Abständen (T0) für eine Zeitspanne (T1), die kürzer ist als diese zeitlichen Abstände (T0), aktiviert wird und sonst in einem stromsparenden Zustand verharrt.

Description

 Device for monitoring and wireless signaling of the pressure in pneumatic tires on vehicles

Description:

The invention relates to a device with the features arranged in the preamble of claim 1. Such a device is known from WO 93/08035. This device has a wheel electronics arranged on the valve base, which is located inside the pneumatic tire and is exposed to the pressure in the pneumatic tire. The wheel electronics have a battery as a power source, a pressure sensor which measures the pressure prevailing in the pneumatic tire, an electronic evaluation circuit which evaluates the pressure measurement signals supplied by the pressure sensor, and a transmitter which is controlled by the evaluation circuit and signals which are obtained from the measurement Information about the pressure in the tire contained, transmitted to a receiving device. The pressure sensor is an absolute pressure sensor based on semiconductors and delivers an electrical output signal corresponding to the current tire pressure. The receiving device is a loose remote control device, which contains an interrogation transmitter, with which the wheel electronics can be returned to their normal operating state from an energy-saving state, in which a receiving device and an activation device present in the wheel electronics are kept in standby mode. The wheel electronics then measure the pressure and send a signal, which contains information about the absolute pressure, to the remote control device, which has a liquid crystal display on which the measured value can be read. A sequence control ensures a short-term transmission of the pressure signal. The wheel electronics are then restored to their energy-saving state, in which they consume a few microamps of electricity. In this way, with a lithium battery with the dimensions of a button cell, which has a nominal voltage of approximately 3 V and a capacity of approximately 50 mAh, only approximately 200 transmissions of the current tire pressure can be carried out. If you want to achieve a service life of five years, you can only query the pressure once a week. Measured against the demands of automobile manufacturers, this is far too little. On the one hand, the battery should have a lifetime that is as close as possible to the life of the vehicle, since the battery electronics cannot be replaced or only at great cost. On the other hand, an effective tire pressure check is not possible with a polling frequency of only once a week. A dangerous situation for the driver is the occurrence of a sudden loss of pressure, which can only be recognized if the tire pressure is measured at intervals of only a few seconds. In order to be able to accomplish this, in advanced tire pressure monitoring systems the tire pressure is not sent every time it is measured, but only when a pressure deviation that affects driving safety becomes apparent, or when the wheel electronics function properly internally from time to time the wheel electronics are checked and reported to the receiving device. (DE 195 22486 C2; company lettering AMI DODUCO "Electronic tire pressure control system. More driving safety - more comfort"). This makes it necessary not only to measure the pressure in the wheel electronics, but also to evaluate why Wheel electronics contains an evaluation circuit which controls the transmitter of the tire pressure electronics and only causes it to transmit when it is necessary, namely when there is a relevant pressure deviation or when the functionality of the wheel electronics is to be reported. For example, AMI DODUCO GmbH has succeeded in consistently optimizing the operation of battery-operated wheel electronics, reducing its power consumption to such an extent that the battery life with a charging capacity of 300 mAh is now at least seven years, although the wheel electronics measure every 3 s and all 54 s sends. Nevertheless, the limited service life of the battery has remained a fundamental handicap of this tire pressure monitoring system.

There has been no lack of attempts to overcome the dependence of the tire pressure control on the life of a battery in the wheel electronics. There are suggestions for using mechanical-electrical or thermo-electrical converters in wheel electronics, which derive energy from the flexing work of the tire while driving or from the resulting warming, convert it into electrical current and thus an accumulator for the operation of the To feed wheel electronics. However, such solutions are too complex and do not have the required reliability and service life under the difficult operating conditions during driving.

Another suggestion is to supply the wheel electronics with the necessary energy from the outside by means of a transponder. The power consumption of the wheel electronics is largely not due to measurement and transmission processes, but in the breaks between the measurement processes, in which the wheel electronics must be kept on standby and an internal clock is running. Such a tire pressure monitoring system is described on the Internet by SSI; the

The website can be accessed at http: //www/SSITECHNOLOGIES.com/indexhtml. A transponder or responder is a radio device that does not have its own power supply, transmits response signals to received query signals and the energy required for this from the query signals themselves refers. For this purpose, in the tire pressure control system there is an interrogator in the vehicle, which transmits the interrogation signals, and a response receiver, which receives the response signals emitted by the transponder. In the tire pressure control system from SSI, the interrogator and the response receiver are combined in a transceiver, which is connected to a vehicle with four wheels with four antennas which are arranged in the wheel arches of the body close to the wheels. At regular intervals, the interrogator sends an interrogation signal to an answer transmitter (transponder) present in the wheel electronics, which activates the wheel electronics, which has neither a battery nor an accumulator, and at the same time transmits to it the electrical energy required to carry out a measurement process carry out and send the measurement result back to the responder. The disadvantage here is that the wheel electronics with the transponder is well shielded inside the wheel. The wheel rim, a steel mesh in the tire and fillers in the tire rubber dampen the signals emitted by the interrogation transmitter and the transponder so strongly that the antennas of the interrogation transmitter and of the response receiver must be arranged at a short distance from each individual wheel and the interrogation transmitter must have a high performance, in order to activate the wheel electronics and also to be able to provide enough transmission power for sending back a tire pressure signal. This makes this solution so complex that it has not yet been put into practice.

The present invention has for its object to show a way how the life of the battery in a battery-operated wheel electronics of a tire pressure control system can be increased further without having to lower the measurement rate for the tire pressure.

This object is achieved by a device with the features specified in claim 1. Advantageous developments of the invention are the subject of the dependent claims. The invention connects in a non-obvious way a generic device that depends on a battery, with elements of the device that works without a battery but instead with a transponder, and thereby achieves a result that takes advantage of these two opposing technical concepts does without accepting their disadvantages. The receiver assigned to the wheel electronics, which is sensitive to the signals emitted by the interrogator and is preferably designed as a separate chip module, does not represent a complete transponder, but essentially only uses its receiving part; Instead of the radio transmitter provided with a transponder and operated with the interrogation signals, the receiver only uses a trigger circuit which triggers and thereby activates the battery-operated wheel electronics. The receiver receives the energy necessary for its operation from the high-frequency interrogation signal, but, in contrast to the known transponder solution, does not supply the rest of the radio electronics with electricity, but only generates trigger signals which activate the wheel electronics so that it carries out one or more measurements and evaluations and, if it should be indicated after the result of the measurement, sends a signal to the receiving device, the energy for the measurement, evaluation and spark being drawn from the battery. After a period of time that can be predetermined by programming the wheel electronics, the wheel electronics switches off again, unless it carries out further measurements depending on the result of the evaluation of the pressure measurement in order to verify an observed pressure drop and / or to observe its further development; Such further measurements can be carried out according to criteria and in such a manner as is disclosed in DE 19522486 C2 and in the AMI DODUCO company publication.

In contrast to a complete transponder solution, the receiver is only used to generate a trigger signal for the activation of the battery-operated wheel electronics. The energy associated with the interrogation signal transmitted, can therefore be very much less than the energy that must be supplied to the transponder in the state of the art known from SSI in order to operate the entire wheel electronics and also to transmit the response signal with the pressure information contained therein to the receiving device. This unusual, limited use of elements of a battery-free transponder in combination with battery-operated wheel electronics results in significant advantages for this special application in a tire pressure control system:

♦ The power consumption of the wheel electronics in the energy-saving state could be reduced to less than 1 μA.

♦ A separate antenna in the wheel arch is no longer required for each wheel to transmit the query signals. This saves considerable costs for antennas and their installation. Since you no longer need your own antenna in each wheel arch, you no longer have to run a high-frequency line in each wheel arch. Instead, one or two antennas can be used, which can be arranged in the center of the vehicle.

♦ The interrogator can be designed for a much lower output than with a complete transponder solution (SSI) and is therefore considerably cheaper.

♦ Since the receiver, which is assigned to the respective wheel electronics, is only intended to receive the query signal and convert it into a trigger signal, but does not have to provide any power for the operation of the wheel electronics and their transmitters, it can be designed with less power than with Use in a full

Transponder, which is why it can be inexpensive. Inexpensive transponders can be found today in large numbers in identification systems (access control), in which identity cards are used, in which a transponder in the form of a chip module with an attached antenna is sealed and checked contactlessly by a card reader in which the The interrogator and the response recipient are accommodated. Since the transponders are manufactured in large numbers, they are inexpensive. They have ranges (transponder - reader distance) of one meter and more. However, since the transponder's response channel is not used according to the invention, it can be used in only one

Radio direction, namely from the interrogator to the receiving part of the transponder, the range can be set even larger. Therefore inexpensive transponder modules of the type used for contactless identification systems are also suitable for use in the present invention, where, however, only their receiving part is required, which is why the chip module on which the receiver is located is also used in the Compared to a full transponder chip module can be cheaper.

♦ The receiver, which is assigned to the wheel electronics, does not draw any current from the battery of the wheel electronics. This is because, as is customary with transponders, the receiver does not require any electrical current in order to be kept on standby for the reception of an interrogation signal.

♦ Since the wheel electronics are connected upstream of a receiving circuit that does not consume any electricity, the wheel electronics, unlike in the case of WO / 9308035, does not have to receive a radio signal in one

Be kept ready, which saves electricity.

♦ The wheel electronics only have to be kept in a standby state to the extent that they can be activated by a trigger signal transmitted by the receiver. If the wheel electronics contain a volatile memory, a voltage must be maintained on it to avoid data loss. However, this does not result in significant electricity consumption.

♦ The internal clock of the wheel electronics, which in the state of the art according to the AMI DODUCO company lettering and according to DE 19522486 C2 must continue to run in the energy-saving state of the wheel electronics in order to be able to activate them at predetermined time intervals, can be activated by the Invention be switched off in the power-saving state of the wheel electronics. This brings a further considerable saving in electricity.

♦ When the ignition is switched off or locked, the interrogator can be switched off, and when the vehicle is unlocked or the ignition is switched on, it can be switched on. If that

If the vehicle is idle, the wheel electronics are not queried, which saves a considerable amount of electricity once again, because most vehicles are idle for more than 90% of their lifespan. In this way, the active operation of the wheel electronics is limited to the operating times of the vehicle. One during the

Non-operating pressure drops in a tire that are relevant for driving safety are nevertheless recorded and signaled. For this purpose, it is preferably provided that the interrogation transmitter is switched on when the ignition is switched on or already when the vehicle is unlocked, whereupon he immediately interrogates the wheel electronics and has the opportunity to take a critical look

Report pressure deviation. In this way, the driver experiences a critical pressure change that has occurred during the idle time before he starts the vehicle in motion. This is an important security aspect of the invention. ♦ Because the battery of the wheel electronics is protected much more than in the prior art when using the invention, one no longer has to pay attention to a power-saving mode of operation when designing the wheel electronics as was still required in the prior art to ensure a high level To achieve battery life. The circuitry outlay and the outlay for software for the wheel electronics can therefore be reduced compared to the prior art.

♦ Instead of increasing the lifespan of the battery, the size of the battery and thus the cost of the battery can also be reduced using the invention. The device according to the invention can be operated in such a way that after each query in the wheel electronics, only one measurement and evaluation process is carried out and a signal is sparked if necessary. This can be done at intervals of a few seconds. The device is preferably operated in such a way that after receiving an interrogation signal, the wheel electronics does not only carry out a single pressure measurement, but rather repeats the pressure measurement and evaluation over a longer period of time, for example a few minutes, at regular intervals of a few seconds and then automatically, in accordance with the programming of the Wheel electronics, returns to its energy-saving state. For example, an interrogation signal could be sent every five minutes and trigger an active phase of the wheel electronics, which is a little shorter than five minutes. In this way it is ensured that, on the one hand, there is constant tire pressure monitoring and, on the other hand, when the vehicle is stopped, after a certain overrun time, the wheel electronics definitely returns to its energy-saving state and remains there until the vehicle is unlocked and / or the ignition is switched on.

The radio signals emitted by the wheel electronics contain, as components in digital form, a preamble, the identifier, a tire pressure signal and a postamble. The radio signals are high-frequency signals. The high-frequency transmission takes place in Germany preferably in the 433 MHz range, the so-called ISM band, or in some other countries in the 315 MHz range or in the 868 MHz range. The radio signals transmitted by the wheel electronics are received by the intended receiving antennas. If each wheel of the vehicle is assigned its own receiving antenna, this is preferably located in the vicinity of the respective wheel, in particular on the wall of the wheel housing of the vehicle body. It is also possible to provide a common first antenna for the front wheels and a common second antenna for the rear wheels, which are preferably arranged approximately in the middle between the wheels. The receiving antennas transmit the RF signals via special RF-compatible lines to the central receiving, evaluation and control unit, in which an RF receiver, which has its own receiving channel for each antenna, amplifies and demodulates the signal arriving at the input of the respective receiving channel , The low-frequency signal present after demodulation is decoded and evaluated in order to provide the driver with a warning or other information about the tire pressure via the control part of the device.

The radio signals are weak to save energy. Due to the low signal level on the electrical lines between the receiving antennas and the central receiving, evaluating and control device, the electrical lines require complex measures to protect the signals transmitted on these lines against external interference. In a practical tire pressure control system according to DE 195 18806 A1, the electrical lines are elaborately shielded twisted pair cables.

In a further development of the invention, therefore, a single-channel RF receiver with demodulator is preferably arranged in each receiving antenna, so that the electrical lines transmit NF signals instead of RF signals. The NF signals do not require elaborately shielded cables for their transmission; unshielded electrical cables can be used, which are much cheaper. In addition, there is the advantage that the LF signals already formed on the antenna by demodulation show a significantly lower sensitivity to interference than the RF signals transmitted via twisted-pair cables in the prior art. DE 198 56 898 A1 discloses further details, to which reference is hereby expressly made. The receiving antennas of the receiving device are preferably used at the same time as transmitting antennas of the interrogator. A separate interrogation transmitter can advantageously be combined with each antenna, so that no HF-compatible line has to be laid for the interrogation either. The period of time for which the wheel electronics are active after triggering can not only be predefined by programming, but can also be selected as a function of one or more physical states measured in the pneumatic tire and changing during driving. Such a state can be the speed of the vehicle, which can be determined by a centrifugal force sensor additionally provided in the wheel electronics. In low-risk driving conditions (slow driving and standstill), the time intervals in which the wheel electronics work can be significantly longer than when driving fast. The measuring rate and the transmission rate can also be chosen to vary depending on the measured pressure or on its change over time, with the greater and faster the pressure drop, the more often one measures and transmits. On the other hand, this means that with normal pressure and only a gradual change in pressure, the measurement and transmission rates can be extended compared to the prior art. On the one hand, this saves electricity and also allows the frequency of the interrogation signals to be reduced. DE 198 56 860 A1 discloses more details on changing the measurement and transmission rates as a function of one or more physical states measured in the pneumatic tire and changing during driving, to which express reference is made.

Basically, the transmission powers of the interrogation transmitter and the wheel electronics are sufficient to manage the four wheels of a vehicle with a common central antenna for the transmission of the interrogation signals and the reception of the pressure signals. However, the requirement that the receiving device must be able to recognize from the signals transmitted by the radio electronics at which point on the vehicle the wheel from which a signal was received can arise as a boundary condition. DE 198 56 861 A1 discloses how acceleration sensors can be used in the wheel electronics, even if each wheel is not adjacent to it Antenna is provided in the wheel house, but only two or even only one antenna is present, can draw clear conclusions about the wheel position.

Various operating states in which the device according to the invention can be in its active state are disclosed in DE 19522486 C2 and are given again below:

1. Basic state

The tire pressure has its setpoint p ₀ and is constant. The condition is at the start of the journey and when driving slowly. At regular intervals t _g The tire pressure is measured and compared with the last measured value. As long as no change is found between the two values, data transmission from the wheel electronics to the receiving device is not necessary. Even slight differences between the two pressure values, for example caused by the measurement value acquisition or by a temperature change, do not lead to data transmission to the receiving device as long as the differences do not exceed a threshold value Δp ₀ . The last measured pressure value is saved instead of the previously measured value in order to then be compared with the next measured value. For comparison with the current measured pressure value, the mean value of several previously measured pressure values can also be used instead of the last measured pressure value.

At regular time intervals T ₀ > t _j , regardless of whether the threshold value has been exceeded, a complete data telegram, which contains the current pressure measurement value, is transmitted to the receiving device by means of the transmitter provided in the wheel electronics. This regular transmission, which takes place at larger intervals, is used for system monitoring and makes it possible to determine the extent to which a gradual drift in tire pressure is assuming.

Typical numerical values are for o: 1 to 10 seconds

T ₀ : 0.5 to 60 minutes

Δp ₀ : 10 to 100 mbar (10 ³ to 40 ⁴ N / m ² )

2. Travel without loss of pressure

At the start of the journey, the tire pressure has the initial value p ₀ . The normal flexing that occurs while driving heats up the tire and thus the air in the tire more or less depending on the speed. This leads to an increase in the pressure in the tire, so that the current tire pressure is above the initial pressure p ₀ and fluctuates depending on the driving speed and the nature of the road. The associated changes in the tire pressure take place so slowly that in the time intervals t ^, the pressure change does not reach the threshold value Δp ₀ and the transmitter is therefore not activated. However, information about the pressure in the tire is sent to the receiving device at time intervals T ₀ with the data telegram, which is also used for system control. From the information about the absolute tire pressure contained in the data telegram, a computer provided in the receiving device recognizes and evaluates slow pressure changes in all tires of the vehicle, in particular in the tires on a common axis, and thus recognizes the pressure changes caused by normal flexing work.

3. Travel with gradual pressure loss

A gradual pressure loss is determined in the same way as slow pressure changes when driving without pressure loss. A creeping pressure loss is recognized by the computer in the receiving device on the basis of the absolute pressure measurement values and from a comparison with the pressure measurement values of the tires with one another.

4. Rapid pressure loss If there is a rapid loss of pressure due to damage to the tire or the valve, the drift of the pressure is so great that the change in pressure from the last formed comparison pressure signal to the current pressure signal exceeds the predetermined threshold value. In this case, a corresponding signal indicating the pressure drop could be sent to the receiving device immediately. In order to eliminate random incorrect measurements, however, a signal is preferably not sent to the receiving device immediately after the threshold value has been exceeded; rather, the measuring rate is first increased, ie the time intervals for a predetermined number of measurements are shortened from ^ to t _n <i ^ , especially to values of t, between 1 and 100 milliseconds. If the exceeding of the threshold value is confirmed in the following measurements, preferably in the following two to ten measurements, the transmitter is activated and the pressure signal is sent to the receiving device. In the performed at the higher rate measurements must be taken into account, of course, that in the shorter time _intervals, t must be reduced in accordance with the same pressure drop rate of the threshold value. Because of the limited sensitivity of the pressure sensor, this will generally not be possible to the extent required. It is, therefore, continue to use cheaper in this case as a comparison pressure signal, the last before the shortening of the time clock from t _"t, the comparison pressure signal formed until the specified number of measurements with a higher measuring rate ended or the measuring rate back to its original value (timing to) was extended.

Another possibility is to send a pressure signal at an increased measuring rate (timing t,) whenever the pressure measured value has changed by a certain amount, for example by 10 to 100 mbar. If no change in the pressure is detected (pressure change smaller than the threshold value Δp ₀ ), then measurement is continued for a certain time with an increased measuring rate (time cycle t,) or a predetermined number of measured values recorded with the increased measuring rate (timing t,) and then switched back to the original low measuring rate (timing t _g ).

It is also possible to switch back to the low measuring rate if the pressure measured value exceeds a predetermined maximum value of, for example, 5 bar or falls below a predetermined minimum value of, for example, 1 bar. The increased measuring rate is then switched over again when the pressure measured values decrease or rise significantly.

5. Filling process

When filling, the pressure change occurs so quickly that the threshold value (between 10 and 100 mbar) is regularly exceeded at a normal measuring rate (time intervals t, between 1 and 10 seconds). The procedure can therefore be the same as for rapid pressure loss. Since the filling process is generally not critical, there is also the possibility that a pressure measurement signal is not sent out until the tire pressure has stabilized again, which indicates the completion of the filling process.

6. Theft monitoring

If the central receiving device is not completely switched off when the vehicle is idle, but only switched over temporarily or to a lower query rate of, for example, a query in 5 to 10 minutes, the tire pressure monitoring device can also be used to monitor the vehicle's wheels against theft. The wheel electronics then sometimes send a data telegram with status information to the central receiving device in the vehicle even when the vehicle is at a standstill. If a wheel is stolen, the data telegram is not sent, which is determined by the evaluation circuit in the central receiver and can respond to an alarm. Because the wheel electronics are supposed to measure the pressure in the tire, they are arranged in the tire. This can be done by arranging it on the valve base, as disclosed in WO 93/08035. It can also be done by attaching it to the wheel rim in the area enclosed by the tire. In the case of wheels which have a plastic ring in the tire's air chamber to maintain emergency running properties on the rim, which stabilizes the tire after a loss of pressure in emergency running, the wheel electronics can also be arranged in a recess in this plastic ring.

An embodiment of the invention is shown schematically in the accompanying drawings, in which

FIG. 1 shows a block diagram of the arrangement of the essential components of a tire pressure monitoring system in an automobile,

FIG. 2 is a block diagram of a receiving device provided in the vehicle and

Figure 3 is a block diagram of a wheel electronics in connection with a

Is recipient.

Figure 1 shows schematically four wheels 1 of an automobile 2. On each wheel 1, wheel electronics 3 are attached in a structural unit with a receiver 4; it is located inside the pneumatic tire of wheel 1 and is fastened to the rim or to the foot of a valve or - if it is a wheel with emergency running properties - in a recess in a plastic ring surrounding the wheel rim. The wheel electronics 3 and receiver 4 are identical to one another and have matching installation positions with respect to the respective wheel 1. Under the floor 5 of the vehicle body there are two antennas 6 and 7, arranged in the region of the longitudinal center line of the vehicle. One antenna 6 is located between the front wheels and the other antenna 7 is located between the rear wheels. Both antennas 6 and 7 are connected by a high-frequency line 8, for example a coaxial line, to a receiver 9 provided in the body, which is supplied with power by the vehicle battery 10.

According to the block diagram in FIG. 2, the receiving device 9 contains as essential components a high-frequency stage 11 designed according to the number of antennas 6 and 7, a modulator / demodulator 12, a microprocessor 13 for signal evaluation and for control tasks, an interrogator 14 BUS driver 15 for a BUS interface 16 and a display unit 17 arranged on the dashboard in a structural unit with an operating part 18, which are connected to the microprocessor 13 by means of a bidirectional BUS 19. The voltage supply for all these components comes from the vehicle electrical system, represented by the connection of the two parts of the receiver 9 to the battery 10 of the vehicle.

According to the block diagram in FIG. 3, the wheel electronics 3 consists of an assembly 20, which contains an integrated pressure and temperature sensor with associated measurement, evaluation and control circuit, an HF stage 21, a radio antenna 22 and an electric battery 24, which supplies the module 20 and the HF stage 21 with current. The HF stage 21 feeds the

Radio antenna 22. The pressure sensor in the assembly 20 is preferably a piezoelectric sensor.

The wheel electronics 3 is assigned a receiver 4 with a receiving antenna 23. The receiver 4 works like the receiving part of a transponder and therefore does not require a power supply from the battery 24. A trigger circuit 25 is provided at the output of the receiver 4 and is connected to a trigger input of the module 20. The device shown in Figures 1 to 3 works as follows:

Most of the time, the wheel electronics 3 are in a power-saving state, in which their functions are largely switched off; it only requires a small current of less than 1 μA in order to be ready for a trigger signal from the trigger circuit 25 and to store data which may be stored in a volatile memory.

If the vehicle is unlocked and / or its ignition is switched on, then the receiving device 9 and with it the interrogation transmitter 14 is switched on, which generates an interrogation signal at time intervals T ₀ of, for example, 5 minutes, and this via the modulator / demodulator 12, the HF stage 11 and the antennas 6 and 7 emits. This interrogation signal is received at each of the wheels 1 by the local receiving antenna 23 and activates the receiver 4 with the energy transmitted by the interrogation signal, so that the latter outputs a trigger signal to the module 20 via the trigger circuit 25. This is then switched to its normal operating state and kept in its normal operating state for a predetermined period of time T, <T ₀ , during which an internal clock is running in the module 20. T ₁ is expediently only slightly shorter than T ₀ . During this normal operating state, a pressure and temperature measurement is carried out in a predetermined time cycle t _j of, for example, a few seconds. The measurement is evaluated. Only if the evaluation shows that a warning signal is to be transmitted, or if a readiness signal is sent which signals the receiving device, for example at regular time intervals T ₀ , that the wheel electronics are functioning properly, does the microprocessor 13 initiate the RF stage 11 To transmit a digital HF signal, which contains information about the measured pressure and / or about a measured change in pressure and, moreover, an identifier characterizing the individual wheel electronics, by means of which the receiving device 9 can determine from which of the wheels 1 the signal comes. The signal emitted by the radio antenna 22 is received primarily by the closest of the two antennas 6 and 7, fed to the receiving device 9 via the line 8, reaches the two-channel RF stage 11, is demodulated in the modulator / demodulator 12 and by the Microprocessor 13 processed. The microprocessor 13 controls the BUS driver 15, which then transmits a display signal generated by the microprocessor 13 to the display unit 17, on which it is used, for. B. is displayed on a liquid crystal display.

The wheel electronics 3 repeat the measurements in the specified cycle t ,, until it is switched off again by their internal clock. Between the individual measurements, it places itself in a power-saving state, in which its internal clock continues to run and consumes electricity. When the time period T, started by an interrogation signal, of a few minutes expires, the internal clock is also switched off and the wheel electronics fall back into their extremely energy-saving state, from which they are only activated again by the next interrogation signal.

The operating mode of the receiving device 9 can be changed by means of an operating part 18 provided in the dashboard.

The receiver 4 can essentially consist of a chip module as used for transponders, the return channel provided in the case of transponders not being required for the return of a response signal.

Suitable transponders, the chip module of which can generally be used, are available from AmaTech Electronic Components Manufacturing GmbH, Roßbergweg 2 in 87459 Pfronten; AmaTech offers them for contactless identification systems, especially for installation in identity cards in credit card format.

Claims

Expectations:

1. Device for monitoring and wireless signaling of a pressure or a change in pressure in pneumatic tires of wheels (1) on vehicles (2) consisting of a receiver (9) provided in or on the vehicle (1), to which at least one antenna (6, 7 ) heard, and from one in the

Pneumatic device (3) for measuring, evaluating and transmitting tire pressure signals, hereinafter referred to as "wheel electronics", which

- a battery (24) as a power source,

a pressure sensor, which records the pressure prevailing in the pneumatic tire,

an evaluation circuit which evaluates the pressure measurement signals supplied by the pressure sensor,

- And a transmitter (21), which is controlled by the evaluation circuit and signals, which contain information about the pressure in the tire and / or about the condition of the wheel electronics (3), transmitted to the receiver (9), the wheel electronics (3) at intervals (T ₀ ) for a period (T,) which is shorter than these intervals (T ₀ ), is activated and otherwise remains in a power-saving state, characterized in that on the vehicle (1) Interrogator (14) provided and the wheel electronics

(3) a receiver (4) is assigned to the same wheel (1), which is sensitive to query signals sent by the query transmitter (14) and does not derive the energy required for its function from the battery (24), but from the query signals themselves, and that the receiver (4) has a trigger circuit (25), the output of which is connected to a trigger input of the wheel electronics (3), so that it is activated by triggering and returns to its energy-saving state after the period of time (T) mentioned.

2. Device according to claim 1, in which the power-saving state of the wheel electronics (3) is characterized in that it is only kept sensitive to the reception of a trigger signal and, if necessary, is kept under voltage for the preservation of data in a volatile memory, its internal clock is switched off in this state.

3. Device according to claim 1 or 2, characterized in that the interrogator (14) and the receiving device (9) with the locking system or with the ignition lock of the vehicle (2) is connected such that the interrogator (4) and the receiving device ( 9) switched off when the ignition is switched off or when the vehicle is locked (2) and when the

Ignition key, when switching on the ignition or when unlocking the vehicle (2).

4. Device according to one of claims 1 to 3, characterized in that the wheel electronics (3) is set so that after receiving a query signal in its then starting active period (T,) several

Measurements and evaluations carried out in succession.

5. Device according to claim 4, characterized in that the measurements are carried out in a cycle (t ₀ ) of 2 s to 4 s.

6. Device according to claim 4 or 5, characterized in that the active period (T,) is 0.5 min to 10 min, preferably 3 min to 5 min.

7. Device according to one of the preceding claims, characterized in that a single-channel RF receiver with a modulator is arranged at each antenna (6, 7) of the receiving device (9) and lines (8), which lead from these antennas (6, 7) to the receiving device (9), transmit LF signals instead of HF signals.

8. Device according to claim 7, characterized in that an interrogator (14) is also arranged in each of the antennas (6, 7) belonging to the receiving device (9).

9. Device according to one of the preceding claims, characterized in that the wheel electronics (3) contains a centrifugal force sensor, with the aid of which the measuring rate and transmission rate of the wheel electronics (3) can be changed.

10. Device according to one of the preceding claims, characterized in that the measurement and / or transmission rate can be changed as a function of the pressure and / or as a function of a time change in the pressure by means of an evaluation and control circuit in the wheel electronics (3).