DE3812631C1 - Device for contactless interrogation of the state of electrical switching or triggering means in a motor vehicle - Google Patents

Abstract

A device for the contactless interrogation of the state of electrical switching or triggering means in a movable part of a motor vehicle is described. The contactless interrogation takes place by means of the air gap of a rotary transformer. In contrast with known devices, this device can have relatively large production and assembly tolerances. To achieve this, the invention exploits the non-simultaneous interrogation of electrical switching or triggering means by the rotary transformer. <IMAGE>

Description

The invention relates to a device according to the Preamble of claim 1.

From the European patent specification 87 138 is a direction for the power supply of moving elements knows, which in particular rotatably featured on vehicles are see; especially the supply of a pressure sensor as part of a tire pressure monitoring device is addressed there. That facility provides one Data acquisition and transmission device on / in the mobile To supply element via a transformer where on the primary and secondary sides of said transformer movable - in particular rotatable against each other - out leads are. The inductively transmitted energy will also used an optoelectronic emitter, esp in particular an LED corresponding to a current measured value to be controlled serially in order to measure data on the Light paths from the movable element to the fixed one  Transfer vehicle part (chassis). The chassis is closed this purpose a phototransistor as an optoelectronic Data receiver provided, which on the one hand a demodula tion device for recovering the current Measured value and on the other hand the drive power of the Controls influencing circuit arrangement. This circuit arrangement is only necessary to the transmission losses in the rotary transformer increase slightly hold, although this to supply the opto-electro African emitter in the movable element during loading drive the vehicle a not inconsiderable performance must be able to transmit. That invention solves So the task, the driving power said rotation transformers and thus constantly occurring transfers reduce power losses to a level of readiness, if e.g. B. due to non-operation of the vehicle transferring data arise.

In principle, this known device could also be a contactless transmission z. B. a certain condition of switching or triggering means in / on a movable Afford vehicle part. However, the one in the moving Arrangement to be provided for vehicle part complex, expensive, and due to a variety of required components also prone to failure. For the transfer of Signals or status information related to Safety devices on a motor vehicle, and especially with those that are only in emergency situations (e.g. Accident) is required, on the other hand, maximum availability Availability and thus simplicity due to the lowest possible Number of components desired, with suitable construction  elements are also known to be long-term must have reliability. Also for modern LEDs the latter applies only to a limited extent insofar as it is more extreme Are subject to stress in the motor vehicle.

European patent application 1 83 580 describes one contactless inductive device for transmission of driver request commands, in particular from the steering wheel Motor vehicle on the steering column or to the vehicle chassis. There is also a transmission element there Rotary transformer used. This well-known establishment provides that the steering wheel is rotatable relative to the Steering column connected secondary winding of the rotary transformer mators with different, individually switchable resistors stands is resilient, so that according to the driver wish encodable secondary load said rotation transformers results. The primary is the Beauf striking with an almost constant alternating current provided so that the measurable primary voltage is a measure for the load provided on the secondary side according to the current driver request. In this This AC voltage then sensibly becomes the same as peak value directed and with that number of quantization intervals converted analog / digital, the number over corresponds to indirect driver requests.

This arrangement has the advantage that in the movably arranged part of the overall circuit arrangement only a few, and for this to be known as reliable components. For this, however, that device requires the production of a rotary transformer with very tight tolerances, particularly as regards the dimensional stability and constancy of the shear of the magnetic air gap over the permissible angle of rotation of the primary and secondary sides relative to one another. This is also expressly referred to in a special FIG. 2. That order does not allow to inexpensively manufacture and use such a rotary transformer with relatively large manufacturing and assembly tolerances. It also does not allow e.g. B. a relatively low-impedance load resistor stood on the secondary side, since when the rotary transformer is operating near a secondary short circuit, the primary measurable voltage can vary widely depending on manufacturing accuracy or aging of the bearing of parts that are movable and then lead to errors and inaccurate driver request evaluation leads.

It is therefore an object of the invention to provide a device for contactless interrogation of the state of electrical switching or release means in / on a movable control element to create a motor vehicle, the use of a Rotary transformer with relatively large manufacturing and Assembly tolerances allowed inexpensively without the Uniqueness of driver request or status transmission from the moving part to the fixed part below suffers. The one should continue set of a rotary transformer with a relatively small Inductance and relatively large stray inductance are made possible, as z. B. occurs if the windings of such a rotary transformer as a planar disk winding in the manner of etched / ge printed circuit boards are provided. In the end  should a facility be created which is not just the transmission of driver requests, but also the testing and possibly power supply of a safe essential trigger means in the steering wheel of a motor vehicle made possible without significant availability compromise.

This task is characterized by the characteristics of claim 1 solved.

By the query of a switch that can be actuated according to the driver's request elements or a trigger element in the steering wheel of a force vehicle during certain query times and one there intermediate query of a replacement element for the night education said switching element or trigger element during certain test times over one and the same rotation transformer, its tolerances and spread sizes go equally in both queries. By ver equal to two such successive measurements results, the query result is independent of tolerances and scattering sizes of the rotary transformer can be represented. A Rotary transformer with Eigen permissible according to the invention is inexpensive in mass production adjustable.

Embodiments of the invention are in the drawing shown and in the description below explained. It shows

Fig. 1 is a functional circuit diagram of a first exemplary embodiment, wherein in particular the evaluation can be implemented in both analog and digital form;

Fig. 2 is a functional circuit diagram of a second exemplary embodiment, which is further simplified by using a microcomputer;

Fig. 3 is a schematic representation of the detection of the node voltage according to a switching state selected according to the driver's request in the imple mentation form according to Fig. 2;

Fig. 4a is an extract from a circuit diagram of a first special coupling type of the primary winding of the rotary transformer;

FIG. 4b shows an excerpt from a knitting diagram of a second particular coupling mode of the primary winding of the rotary transformer;

Fig. 5a is a schematic diagram of a third exemplary embodiment for querying a trigger by means of, and

Fig. 5b is a schematic diagram of a modification of the third embodiment.

An oscillator 1 feeds a power amplifier 2 , the output stage of which is implemented as a current source, which impresses a defined alternating current into the primary winding 5 of a rotary transformer 4 via the node 3 . The secondary winding 6 of the rotary transformer 4 is in a first branch 8 a series connection of here, for example, six semiconductor valves, in particular diodes, 8 a to 8 f , parallelge switches. In a second branch 9 of the secondary winding 6 is a further same series connection of semiconductor valves, in particular diodes, 9 a to 9 f , with parallel polarity reversed with respect to the series connection 8 . Between valves 8 a and 8 b , 8 b and 8 c , 8 c and 8 d etc. branching switches 10, 11, 12 etc. are provided, which allow a different number of valves in series connection 8 to be short-circuited.

In terms of construction, one winding end of the secondary winding 6 can be designed as a ground rail 7 of the movable circuit part, to which corresponding switch contacts of the switches 10 to 14 are brought.

From the aforementioned node 3 , the voltage building up over the primary winding 5 of the rotary transformer 4 is passed on to a separation and storage device 16 . It essentially contains elements 17 and 26 for connecting node 3 to corresponding memory elements 18 and 27 depending on the difference and sign of the voltage at node 3 and the voltage values stored or to be stored in said memory elements. In the simplest case, the function module 16 can have two counter-value peak rectifiers with correspondingly dimensioned charging capacitors 18 and 27 , so that the latter charge to the positive or negative peak value of the AC voltage that can be tapped at node 3 .

Via a first connecting line 19 , for. B. the positive peak value of said node voltage a non-inverting input and via a second connecting line 28 the negative peak value of said node voltage passed to an inverting input of an evaluation unit 25 ; in addition to an inverting stage for an input, this evaluation unit can contain a multiple comparator, quantizer or a simple analog / digital converter. The module 15 with the secondary winding 6 said rotary transformer 4 and switches 10 to 14 and the series circuit 8 of the diodes 8 a to 8 f as the operating load and the series circuit 9 of the diodes 9 a to 9 f as the test load of the rotary transformer 4 are easy and in a steering wheel space-saving integrable bar.

The arrangement works as follows:

The impressed alternating current via the node 3 of the primary winding 5 of the rotary transmission 4 is proportional to the secondary current in every view of its time profile, so that the instantaneous voltage on the primary winding ultimately results from the instantaneous load on the secondary winding. At a momentary polarity of the secondary voltage so that the valves 9 a to 9 f are acted upon with a current in the forward direction, a current inflow via the switches 10 to 14 is not possible; the secondary voltage is bracketed to a maximum negative value, which corresponds to that of the added lock voltages of the valves 9 a to 9 f . This means that the primary voltage at node 3 , depending on the ratio of the number of turns and the leakage inductance of primary and secondary windings 5 and 6 of the rotary transformer 4 , cannot exceed a certain negative maximum value. This negative maximum value is supplied as a negative peak value of a half period of the generator signal of the assembly 16 and z. B. by the self-switching diode 26 on the Haltkonden capacitor 27 so that it is fed via line 28 to an inverting reference input of the assembly 25 bar. With opposite polarity of the secondary voltage, the series connection 9 of the valves 9 a to 9 f has no effect. Instead, the positive amplitude of the secondary voltage is now limited to a positive maximum value in accordance with the number of diodes 8 a to 8 f of the series circuit 8 that are not short-circuited by switches 10 to 14 ; this limitation is transferred as a voltage-dependent load to node 3 , so that a positive peak voltage is supplied to module 16 in the second half period of the generator voltage, which is transmitted to holding capacitor 18 by self-switching diode 17 .

Of course, the evaluation device 25 must have certain internal resistances at its inputs so that, for. B. in particular the stored negative voltage when the switch positions change, the new negative peak value during the second half period of the primary voltage can follow sufficiently quickly in both directions. The relevant input resistance, which determines the corresponding time constant together with the capacitance of the holding capacitor 18 , is not shown here. Via a connecting line 19 , this positive voltage corresponding to the current position of the switches 10 to 14 is supplied to the non-inverting signal input of the evaluation device 25 .

If the valves 8 a to 8 f and 9 a to 9 f have the same loading, the evaluation unit 25 thus receives a maximum expected voltage value via the input line 28 and via the input line 19 a voltage value which is quantized analogously according to the position of the switches 10 to 14 . Since the generation of both voltage values is based on the transmission of a respective load through the rotary transformer 4 , it can be seen that the properties of the rotary transformer 4 may well spread within wide limits without the output from the assembly 25 on individual lines 20 to 24 decoded Transmission result is affected. The switching elements 17 and 26 do not necessarily have to be designed as diodes; Controlled semiconductors, e.g. B. field effect analog switch can be provided for switching through said node voltage. The peak value acquisition and storage can also be carried out by a digitally controlled or acting peak value discriminator; the holding capacitors can then also be replaced by corresponding memory cells without being abandoned by the scope of the invention.

Fig. 2 shows another embodiment of the device, which can be used advantageously when, for. B. a microcomputer 29 with CPU 30 , RAM / ROM memory 31 and I / O interface 32 is already available anyway. The functional module 15 is constructed in the same way as in FIG. 1 and is therefore only hinted at. On a line of an output port 33 , the microcomputer 29 with a certain repetition frequency (z. B. 20 kHz) from a pulse to a stage 34 , which switches its output state logically to each individual pulse; in the simplest case it is a flip-flop. The output signal is fed to an amplifier stage with current source output 35 . Said current source output feeds a constant alternating current with a half repetition frequency into the primary winding 5 of the rotary transformer 4 . The node 3 is connected either directly or via a low pass 36 , in the simplest case consisting of a capacitor 37 and a resistor 38 , to an analog A / D input channel 39 of the I / O interface 32 of the microcomputer 29 .

Fig. 3 illustrates the operation of the device, which does not require rectification and special storage capacitors. Since all instructions in the microcomputer 29 are controlled by one and the same time base, coherence between the control pulse supplied to the stage 34 and the time of the query of the measurement result applied to the A / D input channel 39 can be established by suitable programming of the microcomputer. The figure illustrates in the upper signal curve the current impressed via node 3 of the secondary winding (quite angular) and - after suitable filtering - the measuring voltage present at input 39 (here approximately sinusoidal). The corresponding input line 39 of the I / O port 32 is applied to the internal A / D converter of the microcomputer in a fixed phase phase relationship with the pulse given for sampling, preferably for positive and negative voltage values at different, periodically repeating times. It is evident that in this arrangement it is not important to detect the absolute peak value of the node voltage; rather, to achieve better utilization of the input voltage range of the A / D converter of the microcomputer 29, it may be advantageous to carry out corresponding scans periodically before or after reaching the respective peak values. The quantization of said node voltage required for evaluation is carried out by the microcomputer 29 by means of a suitable software program, so that further components are not required.

In the course of the processing of such a software program, it is also possible that the computer 29 itself sets the maximum value in question when the vehicle is started by means of an initial self-test routine and optimally specifies the precontrol or post-control of the sampling times in order to make maximum use of the input dynamics of the to achieve the relevant A / D channel and a high quantization signal-to-noise ratio. If such a self-test is repeated from time to time during operation of the vehicle, all slowly changing characteristic values of components are compensated for, such as the decrease in diode lock voltages when the vehicle or passenger compartment heats up, for example in winter operation. For this, e.g. B. an already provided for a temperature control or air conditioning of the passenger compartment temperature sensor without additional costs.

Fig. 4a illustrates the primary circuit of the rotary transformer for connecting the node 3 to an A / D input of a conventional microcomputer that only unipolar signal sizes such. B. can process between zero and 10 volts. Accordingly, the primary winding 5 is fed via a coupling capacitor 40 from the amplifier stage 35 , while said node 3 is led via the primary winding 5 onto a rail 41 with half the maximum input voltage U _{emax of} the relevant A / D channel.

Fig. 4b illustrates an equivalent solution in which the node 3 is capacitively connected via a capacitor 40 to the center tap of a voltage divider simulating half the maximum input voltage of the relevant A / D channel from high-impedance resistors 42 and 43 , said center tap being the replacement node 44 feeds the relevant A / D input of the microcomputer 29 .

The basic circuit diagram according to Fig. 5a exemplifies how the device according to the invention with the same advantages for detecting the state of a trigger in the steering wheel of a motor vehicle, for example a squib for a safety system, can be carried out without a high degree of operational reliability and availability must be waived.

Instead of the diode chains 8 and 9 and switches 10 to 14 , the trigger means 46 to be constantly monitored is connected to the secondary winding 6 of the rotary transformer 4 via a first controlled switch 45 . Via a second, controlled switch 47 , the replica replacement element 48 is connected in parallel to the secondary winding of the rotary transformer 4 . The triggering means 46 can essentially be an ohmic resistance, such as that of a squib. Accordingly, an ohmic resistor with the desired setpoint of the squib resistor is then also provided as a replica replacement element. The controlled switches 45 and 47 can be implemented as self-controlling switching diodes.

Analogous to the devices according to FIGS. 1 to 3, the node voltage U _K during the loading of the rotary transformer 4 with the triggering means 46 (to be monitored over the operating load) and with the substitute element forming it is detected; both voltage values are then compared for agreement within a defined tolerance. If the tolerance is exceeded - for example, due to a total failure or short circuit of either the triggering means 46 or the replica replacement element 48 - a programmed alarm can be given. If the controlled switches 45 and 47 are designed as self-controlling diodes, the corresponding comparison values of the node voltage are provided within a period of the driving alternating current exactly as in the exemplary embodiments according to FIGS. 1 to 3. If externally controlled switches are used, there is also a long period Continuous effective or peak value detection of the node voltage UK for evaluation possible.

Fig. 5b shows a modification of the aforementioned embodiment example. Here, the secondary winding of the rotary transformer 4 is divided into two partial windings 6 a and 6 b . The triggering means 46 is connected to the winding 6 a via the controlled switch 45 . To the winding 6 b , the replica element 48 is connected via the controlled switch 47 . The primary voltage of the rotary transformer 4 to be examined is also tapped at node 3 . This modified exemplary embodiment has the advantage that the resistances of the triggering means 46 and the replica replacement elements 48 do not have to be the same due to freely selectable numbers of turns of the secondary windings 6 a and 6 b , in order nevertheless to have the same node voltage on the primary side during query and test times U _K in the absence of an error. Otherwise, the mode of operation of this embodiment is analogous to that of the example according to FIG. 5a.

Claims (10)

1. Device for contactless interrogation of the state of electrical switching or triggering means in a motor vehicle, which preferably in a movable, in particular rotatably mounted control element, for. B. a steering wheel, are arranged with a rotary transformer, characterized in that

• - That in at least one primary winding ( 5 ) said rotary transformer ( 4 ) a defined alternating current can be fed;
• - That be said with the at least one secondary winding ( 6 ) by flowing current during query time intervals be electrical switching or triggering means ( 8, 10 to 14; 46 );
• - That with the at least one secondary winding ( 6 ) flowing current during test time intervals arranged in the movable control element He set element ( 9; 48 ) to replicate said switching or triggering means ( 8, 10 or 14; 46 ) can be acted upon;
• - That during said time intervals on at least one primary winding ( 5 ) said rotary transformer alternately adjusting voltages U _K comparison means ( 16, 25; 29 ) can be supplied;
• - That by said comparison means, depending on at least one predeterminable limit or quantization size, the two alternately detectable voltages U _K related to each other and to a discrete, the instantaneous state of the electrical switching or triggering corresponding driver request or alarm signal are evaluable.

2. Device according to claim 1, characterized in that said switching or triggering means ( 8, 10 to 14; 46 ) and said replacement element ( 9, 48 ) for replication during said time intervals by externally controllable switching means to at least one secondary winding ( 6 ) said rotation transformers ( 4 ) can be switched on. 3. Device according to claim 1, characterized in that said switching or triggering means ( 8, 10 to 14; 46 ) and said replacement element ( 9, 48 ) for replication during said time intervals by semiconductor valves self-controls to the at least one secondary winding ( 6 ) are switchable. 4. Device according to claim 1, characterized in that said electrical switching means consist of an equally meaningful series circuit ( 8 ) of n + 1 semiconductor valves ( 8 a- 8 f) , in particular diode paths, and n switch paths ( 10-14 ) and that by a different switch each stretch a different number of n semiconductor valves that can be short-circuited, and that the selectable number of short-circuitable semiconductor valves corresponds to a specific driver request. 5. Device according to claim 1, characterized in that said replacement element for replication as a further, series connection ( 9 ) of semiconductor valves ( 9 a to 9 f) , in particular diode paths, is formed out, and that said first and second series circuit device with the opposite valve polarity are connected in parallel. 6. Device according to one of claims 4 or 5, characterized in

• - That a first peak value of a primary voltage said rotary transformer can be detected during polling time intervals and transferred to a first storage element ( 18 ) and can be corrected or overwritten by a corresponding peak value from a subsequent polling time interval;
• - That a second peak value of the primary voltage of said rotary transformer can be detected during test time intervals and can be transferred to a second memory element ( 27 ) and, if necessary, can be corrected or overwritten by a corresponding peak value of a subsequent test time interval;
• - That the value stored during test time intervals can be supplied as a reference value for values that can be expected during query time of a quantization function, for example an assignment function or analog / digital conversion ( 25 ).

7. Device according to claim 6, characterized in

• that the range of values between zero and the peak value of the primary voltage that can be obtained during test time intervals can be divided into n / n + 1 discrete value intervals by said quantization function and
• - That the primary voltage that can be obtained during sampling time intervals can be evaluated by signaling the discrete value interval that includes it.

8. Device according to one of claims 1 to 3, characterized in that said electrical triggering means ( 46 ) consists of a release resistor, in particular a squib, and its connection and connection elements within the be movably mounted control element, and that said replacement element ( 48 ) to replicate the trigger by means of be essentially from a test resistor. 9. Device according to claim 8, characterized in that said tripping resistor ( 46 ) from a first secondary winding ( 6 a) can be fed, and that said test resistor ( 48 ) from a second secondary winding ( 6 b) can be fed. 10. The device according to claim 9, characterized in that the two secondary windings ( 6 a , 6 b) have different numbers of turns, and that the test resistor ( 48 ) has a trigger resistance ( 46 ) deviating value.