DE4014990A1 - Liquid lever measurement arrangement - uses ultrasonic pulse reflection from surface and transition time measurement for use with moving or static liquid e.g. in vehicle fuel tank - Google Patents

Abstract

The arrangement for measuring the level of a liquid in a container (1) contains a system (5) with at least one transmitter and receiver of ultrasonic waves which determines the instantaneous position of a point on the liquid surface in the path of propagation of the ultrasound. - The system contains a pulse generator (27) for periodic transmission of ultrasonic pulses. The transition time of the pulses from the transmitter to the liquid surface and back to the receiver is measured by an evaluation unit (6).

Description

The invention relates to a device for determining the Liquid level of a liquid in a container.

It is known to check the liquid level in a container for example in a fuel tank, by means of one in one vertical tube floating to the container Capture swimmers. Because the pipe is connected to the container the liquid level in the pipe corresponds to the liquid stood in the container as long as there was no constantly changing very agitated free surface of the liquid in the container is available. This measurement method therefore only has one sufficient accuracy with calm liquids.

However, liquids are often in within a container Movement, be it by moving the container itself or during a resting container by an induced movement of the Liquid, for example by stirring the liquid with Tools or the like. This creates on the upper area of the liquid in the container changed over time, wel Len-like or other geometrical level states. Such conditions occur, for example, in motor vehicles Oil tanks, fuel, brake fluid tanks and discs  wash containers, but also in process engineering when mixing of liquids and liquid-carrying household appliances on. It is often necessary to determine the volume of fluid inside the container even during the movement of the liquid to check whether the current liquid volume still corresponds to the specified values.

The object of the invention is a device of the type mentioned at the outset, both in calm as well as for moving liquids in a container can be.

This object is achieved in that at least one Transmitter and a system containing a receiver for transmission and receiving ultrasonic waves arranged on the container which is a current location of a point of fluid surface in the area of the propagation path of the ultrasonic wave len recorded. The invention takes advantage of ultrasonic waves a reflection of the free surface of a liquid drive through the ultrasound emitted by a transmitter waves are reflected to a receiver. By evaluating the difference between the transmitted signal and the received signal the liquid level can then be determined.

In one embodiment of the invention, the system is with a pulse connected for periodic transmission of sound pulses. The transmitter therefore sends an ultrasonic pulse to the is reflected from the surface of the liquid and from Receiver is received. This makes it possible to run the time to measure and evaluate the ultrasonic pulse.

In a further embodiment of the invention it is provided that an evaluation unit is connected to the system Means for detecting the transit time of an ultrasonic pulse from Transmitter to a surface of the liquid and on to Has receiver. With the help of recording the term of the  Sound impulse can change the current position of the liquid level be determined.

In a further embodiment, the pulse generator is connected to the evaluation connected.

The evaluation unit is a further embodiment of the invention connected to a data storage device. This can be the end unit of value data about the position or movement of the container, about the type of movement introduced into the liquid and Similar to be sent to her a calculation of the To allow liquid volume.

In a further embodiment of the invention, the system is as piezoelectric transducer, which is used both as a transmitter, and can also be used as a receiver of sound impulses. The Ultrasonic waves are made using piezoelectric Materials. In the "transmitter" mode, elec trical energy converted into mechanical. When creating one the corresponding alternating voltage vibrate the piezoelectric Discs at their natural frequency and radiate the corresponding the sound waves perpendicular to the surface. In the operating wise "receiver" becomes the mechanical in the electrical Energy transformed. The incoming sound wave excites the piezo electrical disc to vibrate through which an elec trical tension is caused. This tension becomes Evaluation used. This means that the same component can be removed alternately used as a transmitter and a receiver.

In a further embodiment of the invention, several, in Ab stood against each other on a wall of the container Systems provided. With the help of those captured by these systems different locations of the entire liquid level it is possible to check the position of the surface in the container determine and thus the liquid volume in the container calculate, whose volume is known.  

In a further embodiment of the invention is the area of Path of propagation of the sound impulses of a system in the river liquid on both sides of the face, over the free surface of the liquid projecting pipe arranged net that in the area of the liquid level at least one in has its opening provided wall. Such a pipe serves to guide the ultrasonic waves, especially if there is a risk that the reflection of the ultrasound do not wave on a smooth free surface of the liquid returns to the recipient. By in the wall of the pipe The intended opening is the liquid inside the tube in contact with the liquid outside the pipe. The Arrangement of such a tube is also useful, for example moderate if the container is in an inclined position and the ultrasonic waves reaching the free surface at an angle be reflected. Does the ultrasound beam hit the Pipe wall, the beam is reflected again on the pipe wall and always comes across after several reflections Receiver. The one caused by the not direct path Extension of the term can be calibrated into the system.

Further advantages and features of the invention result from the subclaims and from the description below of embodiments that Darge with reference to the drawings represents are.

Fig. 1 shows schematically an embodiment of the invention with a container at the bottom thereof four systems in spaced each other and which are connected to an associated evaluation unit with a data memory,

Fig. 2 shows the profile of light emitted by an ultrasonic transmitter ultrasonic pulses in a horizon tal container in which the liquid forms a smooth, horizontal surface,

Forming surfactant Fig. 3 is a view similar to FIG. 2, at which the loading container is, however, in an oblique position and the liquid in the container keitsspiegel an undulating top,

Fig. 4 shows a state of the liquid in a container at the moment of a horizontal acceleration of the container,

Fig. 5 shows an embodiment of the invention, in which the ultrasonic pulses of the system run inside a tube introduced into the liquid and

Fig. 6 shows an arrangement according to Fig. 5, but in which the bottom of the container is in an inclined position and thereby the ultrasonic pulses are reflected from the inner wall of the tube to the receiver.

In Fig. 1, an essentially cuboid container ( 1 ) is shown as an example, which is closed on all sides. The container ( 1 ) is partially filled with a liquid, but the illustration has been omitted for reasons of clarity. Such containers ( 1 ), which of course can also have other geometric shapes, are for example in motor vehicles in which they and the liquid taken up are exposed to accelerating, braking, cornering of the vehicle or similar different conditions. The liquid in the container ( 1 ) adjusts itself according to the respective state, ie the liquid level changes without the volume of the liquid having to change.

The container has on a bottom surface ( 17 ) four spaced systems ( 5 ), each of which can transmit and receive ultrasonic wave pulses. In the execution example, the systems ( 5 ) on the inside of the floor surface ( 17 ) are attached.

Each system ( 5 ) is connected to an AC voltage source ( 2 ) by means of electrical lines ( 3 ) and is supplied by it. Together with the voltage source ( 2 ), a pulse generator ( 27 ) is connected to the electrical lines ( 3 ) to the systems ( 5 ), which forms periodic AC pulses with a frequency of the order of 1 kHz. Each system ( 5 ) is connected on the output side by means of lines ( 4 ) to an evaluation unit ( 6 ), which will be discussed in more detail later. The evaluation unit ( 6 ) is also connected to the pulse generator ( 27 ) and to a data memory ( 7 ).

Each system ( 5 ) consists of a piezoelectric transducer, which serves as a transmitter and a receiver of ultrasound pulses. In order to be able to measure the transit times well, it is advisable to use ultrasound transducers that start up quickly and provide impulses with steep flanks. The piezoelectric disks of the transducers vibrate at an ultrasonic natural frequency in the range of 1 MHz to 50 MHz, depending on the resolution requirement. The AC voltage of the AC voltage source ( 2 ) is designed so that the disks of the transducers reach this natural frequency. Since only short voltage pulses are fed to the transducers with the aid of the pulse generator ( 27 ), they also send out only short ultrasonic pulses accordingly. The frequency of these AC voltage pulses depends on the size of the container and the properties of the liquid and is in the order of magnitude of 1 kHz. Each transducer emits ultrasound pulses at the appropriate frequency, these pulses always being radiated through the disks of the transducers perpendicular to their surface.

As soon as the ultrasound pulse hits a point on a free surface of the liquid, it is reflected back from there to the system ( 5 ). The time span and thus the frequency of the pulse generator ( 27 ) between two sound pulses is so measured that the waves of the first sound pulse return to the system ( 5 ) before the next ultrasonic pulse is emitted by this. Therefore, the system ( 5 ) serves as a receiver after sending out a pulse. The incoming sound wave excites the piezoelectric disk to vibrate, which in a known manner creates an electrical voltage, which reaches the evaluation unit ( 6 ) by means of the lines ( 4 ) and is evaluated there.

In some cases, not every emitted ultrasound so reflect back on the surface of the liquid animals so that it meets the recipient. However, it is sufficient if within a given unit of time at least one of the signals radiated with the pulse frequency pulse is reflected back to the receiver to make an off enable evaluation. This is guaranteed if the Liquid forms a "rough" surface, i.e. H. no smooth surface.

The evaluation unit ( 6 ) measures the transit time of an individual ultrasound pulse from the moment in which it is emitted until the time at which the reflection beam of the pulse hits the receiver. The start of the measuring process is triggered by the information supplied by means of a line ( 28 ) from the pulse generator ( 27 ), so that a voltage pulse simultaneously triggers a transit time measurement. As soon as the electrical voltage signal from the impact of the reflection beam on the piezoelectric disk is transmitted to the evaluation unit ( 6 ), the measuring process is stopped. The data memory ( 7 ) transmits the evaluation unit ( 6 ) information about the geometric shape and the nature of the container ( 1 ) and properties of the liquid, and about the current movements or positions of the container ( 1 ).

By means of the data supplied by the data memory ( 7 ), the evaluation unit ( 6 ) is able to determine the position of the point of the upper surface of the liquid relative to the container ( 1 ), which has caused the reflection of the sound pulse. Since four systems ( 5 ) are attached to the floor ( 17 ) in the exemplary embodiment from FIG. 1, the evaluation unit ( 6 ) receives four pieces of information from four different positions of the liquid level at the moment of the measurement. With the help of the data in the data memory ( 7 ) it is therefore possible for the evaluation unit to approximately calculate the shape and position of the surface of the liquid in the container ( 1 ) and to determine the instantaneous liquid volume by means of the likewise entered data of the geometric shape of the container . Of course, it is also possible to obtain more measuring points by means of an even larger number of systems ( 5 ), in order, for example, to be able to reliably determine strongly undulating surfaces. If hardly any changes occur on the surface of the liquid in the container ( 1 ), two systems ( 5 ), in some cases even only one system ( 5 ), are sufficient. The data memory ( 7 ) also contains information as to which surface shapes a liquid in a container usually takes on certain movements or inclined positions of the container due to physical principles.

If, for example, an ultrasound measurement described in this way is carried out in a cylindrical container filled with liquid, in which the liquid is stirred, the rotating liquid creates a paraboloid-like depression in the liquid. Using two measuring points, it is thus possible to determine the volume of the rotating liquid in the container ( 1 ).

Depending on the area of application and the type of request, the results of the evaluation unit ( 6 ) are processed further and used to control further operating variables.

It does not matter whether the systems ( 5 ) on the inside or on the outside of the bottom ( 17 ) of the container ( 1 ) are introduced. If, for example, several reflections occur when the container wall is irradiated, in particular at the interface of the container with the liquid, the time interval between the entry pulse into the liquid and the reflection at the liquid surface can be selected. The same applies for the rest if the systems ( 5 ) are attached to the top of the container ( 1 ) and the sound pulses first radiate through the air or gas space above the liquid.

In Figs. 2 to 4 are some typical forms of free surfaces of a liquid (10) in the container (1) are exemplified in different positions and movements of the container (1). In Fig. 2 the container ( 1 ) is in a resting, horizontal position. The free surface ( 9 ) of the liquid ( 10 ) is smooth, so that perpendicularly emitted sound pulses ( 8 ) from the systems ( 5 ) are also reflected perpendicularly back to the respective system ( 5 ).

In Fig. 3 the container ( 1 ) is in an inclined position and is at the same time subjected to vibratory movements, so that the liquid ( 10 ) has a substantially horizontal surface ( 11 ), but which is subject to wave formation. Within a predetermined period of time, a sound pulse ( 8 ) is reflected from a point ( 12 or 14 ) of the "restless" surface ( 11 ) back to the system ( 5 ). Within this predetermined period of time, measured values of a system ( 5 ) that have already been recorded are stored in the evaluation unit ( 6 ) until a corresponding signal has been received from each system ( 5 ). It is therefore not necessary for all four systems ( 5 ) to receive the reflected sound pulses at the same time, which would be almost impossible, especially with a moving surface ( 11 ).

The container ( 1 ) in Fig. 4 is subject to a horizontal acceleration to one side, so that the liquid ( 10 ) is pressed to the opposite side of the container ( 1 ) from the acceleration direction. The parabolic surface ( 13 ) in the cross section of FIG. 4 can be roughly calculated on the basis of the acceleration values of the container ( 1 ) and on the basis of the characteristic values of the liquid ( 10 ), so that by determining the points ( 15 and 16 ) of the surface ( 13 ) their position in the container ter ( 1 ) and thus the instantaneous volume of the liquid ( 10 ) can be determined.

In order to be able to detect completely smooth surfaces ( 26 and 25 ) according to FIGS. 5 and 6 even when the container bottom ( 17 ) is in an inclined position, a so-called “beam guidance” is carried out for an ultrasonic pulse ( 21 ). For this purpose, a tube ( 18 ) is seen before, which is attached to the container bottom ( 17 ) in the liquid ( 10 ) in such a way that it encloses the system ( 5 ) with its lower end face. On its free, upper end face, the tube ( 18 ) projects beyond the free surface ( 26 ) of the liquid ( 10 ). In the lower area of the tube ( 18 ) just above the system ( 5 ), two openings ( 19 ) are provided through which the liquid ( 10 ) in the tube ( 18 ) communicates with the liquid ( 10 ) outside the tube. This creates a form of a communicating tube, through which the height of the liquid level ( 20 ) in the tube ( 18 ) corresponds to the height of the liquid level ( 26 ) in the container ( 1 ). The tube (18) is arranged perpendicularly to the container bottom (17), so that it is at an inclined position of the floor (17) also in an inclined position according to Fig. 6. However, since the liquid level mirror ( 25 ) and the liquid level ( 22 ) within the tube ( 18 ) according to FIG. 6 are still in a horizontal position, it is not possible to transmit a sound pulse ( 24 ) emitted by the system ( 5 ) directly to reflect back on the system ( 5 ). Rather, the reflection beam ( 23 ) of the sound pulse is reflected on the wall of the tube ( 18 ) and returned from there to the system ( 5 ). In order to allow such reflection from the tube wall, the tube must be made of a material whose speed of sound is different from that of the liquid ( 10 ). From one embodiment, for example, a double-walled tube is provided that carries an air or gas jacket. If the reflection beam ( 23 ) is reflected from the surface ( 22 ) once or several times on the wall of the tube ( 18 ), it always strikes the system ( 5 ). The runtime extension of the reflection beam ( 23 ) caused by the non-direct path is calibrated in the evaluation unit ( 6 ) by means of the data memory ( 7 ).

If the diameter of the tube ( 18 ) and the material pairing of liquid and tube inner wall are chosen so that the formation of the surface ( 22 ) in the tube ( 18 ) is influenced by the capillary action, it is possible to carry out the ultrasound analogously to the guidance in a light guide attributed to the system ( 5 ).

It is of course also possible to arrange the systems ( 5 ) so that the ultrasonic pulses hit the respective surface of the liquid from above and are then also reflected upwards, ie the evaluation is not influenced by the speed of sound in the respective liquid.

Claims (9)

1. Device for determining the liquid level of a liquid in a container, characterized in that at least one transmitter and a receiver containing system ( 5 ) for transmitting and receiving ultrasonic waves is provided, which is a current position of a point of the liquid surface in the area the path of propagation of the ultrasonic waves. 2. Device according to claim 1, characterized in that the system ( 5 ) is provided with a pulse generator ( 27 ) for periodically emitting ultrasonic pulses. 3. Apparatus according to claim 1, characterized in that an evaluation unit ( 6 ) is connected to the system ( 5 ), which has means for detecting the transit time of an ultrasonic pulse from the transmitter to a free surface of the liquid and further to the receiver. 4. Device according to one of claims 1 to 3, characterized in that the pulse generator ( 27 ) is connected to the evaluation unit. 5. Device according to one of claims 1 to 4, characterized in that the evaluation unit ( 6 ) is connected to a data memory ( 7 ). 6. Device according to one of claims 1 to 5, characterized in that the system ( 5 ) is designed as a piezoelectric transducer, which can be used both as a transmitter and as a receiver of ultrasonic pulses. 7. Device according to one of claims 1 to 6, characterized in that the system ( 5 ) on the container ( 1 ) is angeord net that the ultrasonic wave pulses substantially perpendicular to a container surface ( 17 ) on which the system ( 5 ) is appropriate, radiated and received. 8. Device according to one of claims 1 to 7, characterized in that around the region of the propagation path of the ultrasonic pulses of a system ( 5 ) in the liquid ( 10 ) is arranged an open tube ( 18 ) on its two end faces. 9. Device according to one of claims 1 to 8, characterized in that several, at a distance from each other on one side ( 17 ) of the container ( 1 ) attached systems ( 5 ) are provided.