DE3706254A1 - Device for determining a signal time which is assigned to the level of a liquid in a container, in particular in motor vehicles - Google Patents

Abstract

A convertor (4, 4.1) determines cyclically a signal time (s) which constitutes a measure of the propagation time (t) of a sound signal (7) in a liquid. For this, the convertor (4, 4.1) normally evaluates the time interval between a transmission signal (8) and a reception signal (9) which corresponds to the propagation time (t). In the case of a reception signal (9) which is missing because of a fault, a simulation unit (5/5.1) outputs a substitute signal (10) to the convertor (4, 4.1) after the expiry of a reference time (tmax) which begins with the transmission signal (8). As a result, a substitute propagation time (ts) is simulated. <IMAGE>

Description

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

In a known device of this type (DE 34 40 513 A1) experience has shown that the received signal is missing relatively often, there z. B. the sound signal on the moving liquid surface is reflected at an unfavorable angle and is there as a result of no sound power arrives at the converter device.

In the absence of a received signal, however, the converter cannot trigger give more signal to the converter device; the measuring cycle is interrupted and the converter cannot do the signal time determine more and as a result gives a duration as a measurement signal signal that no more information about the fill level ent holds.

The invention is therefore based on the object, the level measurement even when the received signal is absent.

The solution to this problem is characterized in claim 1. There is a simulation unit for simulating an Er Record runtime provided with no reception signal.

The simulation can preferably be implemented in that the simulation unit for the missing received signal Substitutes signal to the converter that the converter from the Em pfangsignal can not distinguish. This will make it run de measuring cycle maintained and the next measuring cycle can be started with a trigger signal.  

The simulation unit can delay the replacement signal Hand over (= reference time) to the converter that corresponds to the time Chen distance between transmission signal and substitute signal (= substitute duration) corresponds. The replacement term is therefore important a fictitious runtime to which a fictitious fill level is assigned is arranged.

To adapt the device according to the invention to the minima len and maximum fill level of different containers, can a simulation unit can be used with advantage in which the reference time can be set.

Preferably, a reference time can be specified, which also is outside the range of values in which each runtime also Level is assigned. This allows a higher-level out Value unit that determines the level from the measurement signal simple way the replacement runtime from the real run differentiate times and the evaluation of the measurement signal take into account accordingly.

Further advantageous embodiments of the invention are in the Subclaims marked.

Two embodiments of the invention are in the following ing figures explained. It shows

Fig. 1 shows a device level with a simulation unit with tilt,

Fig. 2 shows a second device with a simulation unit, which has a comparison device, and

Fig. 3 is a functional diagram that shows several measurement cycles.

The first exemplary embodiment according to FIG. 1 has a container 1 in which there is a liquid. At the bottom of Behäl ters 1, a converter device 2 is mounted, which has zowandler a pie, which generates in response to a trigger signal 6 is a signal in the pulse-like sound 7 and receives back to the liquid upper surface reflected sound signals. 7 The Wand lereinrichtung 2 outputs a trigger signal 6 and a transmission signal 8 and in response to a received, reflected sound signal 7 from a reception signal 9 . The transmit signal 8 from the converter 2 is fed to a simulation unit 5 and an OR gate 3 . Receive signal 9 and transmit signal 8 are present at the same input of the OR gate 3 .

The simulation unit 5 contains a flip-flop, which outputs a pulse-shaped replacement signal 10 to a second input of the OR gate 3 only after a fixed reference time t _{max in} response to the transmission signal 8 . The OR gate 3 is connected upstream of a converter 4 and transmits the transmission signal 8 , the start signal 9 Emp or the equivalent signal 10 to the converter 4 with equal rights.

After receiving a received signal 9 or a Ersatzsi gnals 10 , the converter 4 outputs a reset signal 12 to the tilting stage.

The converter 4 emits a measurement signal 11 which contains the information about the transit time t and thus about the fill level. The measurement signal 11 consists of several successive Si signal times s , which occur alternately as pulse duration and pulse pause in the measurement signal 11 .

Each signal time s is determined by the converter within a measuring cycle M , the duration of which is equal to the signal time s . In addition, the signal time s is a measure of the transit time t , which is also determined during the measurement cycle M by the converter 4 .

At the beginning of each measuring cycle M , the converter 4 outputs a trigger signal 6 to the converter device 2 . At the end of each measuring cycle after the determined signal time s , the converter ends the measuring cycle by outputting the trigger signal for the next measuring cycle M to the converter device 2 (see function diagram 3 ).

The second exemplary embodiment according to FIG. 2, like the exemplary embodiment according to FIG. 1, has a container 1 with a liquid, into which the converter device 2 sends and receives sound signals 7 again.

The converter device 2 is connected to the OR gate 3 , to which it outputs the transmission signal 8 and the reception signal 9 . The OR gate 3 is connected to the converter 4.1 , which sends the trigger signal 6 to the converter device 2 . The converter 4.1 outputs a digital actual value for the running time t , which is formed internally in the converter 4.1 when determining the running time t . As in the exemplary embodiment according to FIG. 1, the converter 4.1 outputs the measurement signal 11 and is connected to the simulation unit 5.1 , to which it outputs the digital actual value.

The quartz-stable simulation unit 5.1 consists of a loadable reference value source 5.3 , which provides a reference value for the reference time t _max , and a comparison device 5.2 , which, for. B. can consist of a digital comparator. The comparator constantly compares the reference value with the actual value offered by the converter 4.1 for the running time t on identity and emits a pulse-like substitute signal 10 to the OR gate 3 when the actual value of the running time t is equal to the reference value.

The time sequence for determining a plurality of signal times s ₁ , s ₂ , s ₃ and for the measurement signal 11 output by the converter 4 / 4.1 is explained in more detail in the function diagram according to FIG. 3. The first measurement cycle M 1 starts - as every measurement cycle - with egg nem pulse-shaped trigger signal 6 emitted by the converter 4 or 4.1 to the converter device 2, by the initiation signal 6 stimulated a pulse-shaped transmission signal 8 generated which, via the OR gate 3 at the converter 4 is forwarded. At about the same time as the transmission signal 8 , the piezo transducer emits a sound signal 7 into the liquid in the container. The sound signal 7 extends to the surface of the liquid, is reflected by it and runs back to the piezo transducer, which in turn converts it into an electrical signal. This signal is processed by the converter device 2 to the pulse-shaped Emp start signal 9 . The time interval between the transmission signal 8 and the reception signal 9 represents the running time t ₁ , which the sound signal 7 in the liquid needed to cover the distance piezo transducer - liquid surface - piezo transducer. The received signal 9 is also forwarded via the OR gate 3 to the converter 4 / 4.1 . To the setter 4 / 4.1 forms the transmission signal 8 and the Empfangssi gnal 9, the running time t _1, and sets the time signal s ₁ from the travel time t ₁ together and a constant lock time T. During the blocking time T , the converter 4 / 4.1 ignores pulses from the OR gate 3 .

The blocking time T serves to avoid interference from echoes of a sound pulse generated in the liquid. The signal time s ₁ is converted by the converter 4 / 4.1 into a pulse duration of the measurement signal 11 .

After the delay time t has elapsed, the converter 4 again emits a trigger signal 6 and thus triggers a new, the second measuring cycle M 2 . During the second measuring cycle M 2, the converter 4 determines the transit time t ₂ , which together with the blocking time T results in the signal time s ₁ . In the measurement signal 11 , the signal time s _{2 is} in contrast to the first measurement cycle M 1 as a pulse pause.

The third measuring cycle M 3 starts again with the trigger signal 6 , by which the converter device 2 , when excited, emits a transmission signal 8 to the converter 4 via the OR gate 3 . However, in the measuring cycle M 3, the received signal 9 fails to appear due to a disturbance. Only after the reference time _max, the examples in the execution t of FIG. 1 and FIG. 2 exactly equal to the spare time t _s, are the simulation unit 5 / 5.1 a pulse-shaped compensation signal 10 via the OR circuit 3 to the converter 4 / 4.1 from. This does not differentiate between the received signal 9 and He set signal 10 and determines the signal time s ₃ now from the He set run time t _s , which is equal to the time interval between the transmit signal 8 and substitute signal 10 , and the constant blocking time T. The converter 4 / 4.1 converts the signal time s ₃ back into a pulse duration of the measurement signal 11 .

The replacement term t _s has a value which is above the maximum value for the term t . The substitute transit time t _s thus differs significantly from the regularly determined transit times t , which, when evaluating the signal times s of the measurement signal 11 , which are a measure of the fill level of the liquid in the container, reliably differentiate real transit times t from the simulated substitute transit time t _s enables.

Claims (11)

1. Device for the cyclical determination of a signal time (s) which is assigned to the fill level of a liquid in a container ( 1 ), in particular in motor vehicles,

• - With a converter device ( 2 ),
  • - which generates a transmission signal ( 8 ) excited by a trigger signal ( 6 ),
  • - Which emits a sound signal ( 7 ) into the liquid simultaneously with the transmission signal ( 8 ), and
  • - The signal reflected on the liquid surface ( 7 ) detected again and converted into a received signal ( 9 ), and
• - with a converter ( 4, 4.1 ),
  • - which triggers a measuring cycle (M) for determining the signal time (s) with each trigger signal ( 6 ),
  • - The transmission signal ( 8 ) and the reception signal ( 9 ) are supplied per measurement cycle (M) and the signal time (see the running time (t) between the transmission signal ( 8 ) and reception signal ( 9 ) and a constant blocking time (T) ) determined
  • - which starts the following measuring cycle (M) at the end of the signal time (s) by emitting a further trigger signal ( 6 ), and
  • - which determines the signal time (s) in successive measurement cycles (M) and alternately displays it in a measurement signal ( 11 ) as pulse duration and pulse pause,

characterized in that a simulation unit ( 5 ) is provided which simulates a replacement runtime (t _s ) if the received signal ( 9 ) does not arrive within a reference time (t _max ). 2. Device according to claim 1, characterized in that the simulation unit ( 5 ) delivers a replacement signal ( 10 ) for the failed reception signal ( 9 ) to the converter ( 4 ). 3. Device according to claim 2, characterized in that the simulation unit ( 5 ) sends the replacement signal ( 10 ) to the converter ( 4 ) when the reference time (t _max ) has elapsed after the transmission signal ( 8 ). 4. Device according to claim 3, characterized in that an OR gate ( 3 ) is switched to the converter, to which the transmission signal ( 8 ), the reception signal ( 9 ) and the substitute signal ( 10 ) is supplied. 5. Device according to claim 3 or claim 4, characterized in that a flip-flop is used as the simulation unit ( 5 ), which emits the substitute signal ( 10 ) only after the reference time (t _max ). 6. Device according to claim 5, characterized in that the converter ( 4 ) emits a reset signal ( 12 ) for resetting the flip-flop after it has received a received signal ( 9 ) or a replacement signal ( 10 ). 7. Device according to claim 3 or claim 4, characterized in

• - That the simulation unit ( 5.1 ) has a comparison device ( 5.2 ) which compares a reference value corresponding to the reference time (t _max ) with an actual value corresponding to the transit time (t) , which the converter ( 4.1 ) determines, and
• - That the comparison device ( 5.2 ) emits the equivalent signal ( 10 ) to the converter ( 4.1 ) when the actual value reaches the reference value.

8. Device according to claim 7, characterized in that the reference time (t _max ) is adjustable. 9. Device according to one of claims 3 to 7, characterized in that the reference time (t _s ) is outside of a range in which each runtime (t) is assigned a filling level. 10. Device according to one of the above claims, characterized in that the reference time (t _max ) is equal to the replacement time (t _s ).