DE2405991C3 - Device for measuring the liquid level - Google Patents

Description

The invention relates to a device for measuring the liquid level in a tank or the like with at least two elongated, vertically protruding down into the tank, with a predetermined distance mutually arranged components, one of which is connected to a supersonic transmitter, which repeatedly transmits short supersonic vibrations in the component, while the other component also a receiver is connected, which transmits to supersonic vibrations, while the other component is connected to a receiver that responds to supersonic vibration and the received Converts supersonic vibrations into electrical signals and also with a transmitter and receiver connected computer, which with the help of electrical signals the fluid level as a function of the progression tngszeit the supersonic oscillation from the transmitter üiier the components and the tank liquid to Recipient calculated.

It has already been proposed to use Hüssigkeitsstandmeßgi'räte to use where the forwarding time is used, which is the supersonic oscillation of a supersonic transmitter through one or more supersonic conductive components and the liquid

surface to the receiver that responds to supersonic conditions is required. There are essentially two different measuring devices: on the one hand there are devices that have only one supersonic conductive component for the measurement and use the supersonic waves that are reflected on the surface of the liquid, and on the other hand devices in which between at least two supersonic conductive components the Supersonic cross-talk is exploited at the liquid surface. For an example of a measuring device of the first-mentioned type, reference is made to US Pat. No. 3,394,589. The USA. Patent 30 80 152 describes a measuring device of the second type.

However, these previously known measuring devices have such an inadequate measuring accuracy that they have not been used to a considerable extent up to now. The bee ^; Impairment of the measurement accuracy in previously known supersonic measuring devices is essentially based on fluctuations and changes in the speed of propagation of the supersonic as a result of temperature differences along the components and also on the difficulty of keeping the frequency of the supersonic transmitter constant.

The object of the invention is to create a device for measuring the liquid level with Works supersonic and does not have the disadvantages mentioned above.

The aforementioned object is achieved according to the invention in that

a) the components are connected to one another by rigid cross struts that are equidistantly spaced extend perpendicular to the components and on the one hand the positions and spacings of the components relative set to each other and on the other hand as cross-talk channels or sound bridges between the Components are used,

b) the liquid level measurement on the liquid surface The cross brace closest to the top is related.

For more information on the state of the art, please refer to the previously known according to the echo principle working measuring devices (DT-PS 8 78 723) referenced, in which the transit time a sound pulse from the transmitter to the liquid surface c and measured back to the receiver. Here you have within the tank at different heights Reflectors arranged to find signal reference points which are closer to the liquid surface are, as the sound signals sending and receiving components. The ones that are interesting for the capture Sound vibrations travel vertically in the liquid tank up to the liquid level and come as an echo back to the receiver in the opposite direction. The path to be measured is constantly changing depending on the height of the liquid level and there are only a graphic representation of the measurement result also the measurement marks generated by evenly distributed reflectors pictured with.

In the case of the fundamentally different measuring principle of the invention, however, it was important to locate the location as much as possible to localize exactly, ar ^ he the forwarding speed the hon /. 1 al from the transmitter component to the receiver component wipe uien sound waves / wipe

f · b / w. Sound bridges

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including detailed drawings prior to the invention are closer cri.m-

65 tert. In the drawings shows

F i g. 1 a schematic view of an inventive Device for measuring the liquid level,

F i g. 2a to 2c different possibilities Supersonic conductive components at a certain distance to connect from each other with rigid cross struts and

F i g. 3a to 3e different possibilities for the supersonic cross-talk between the components strengthen.

Fig. 1 shows a tank 1, the liquid level to be measured is The two elongated components 3. 4 break through the liquid surface 5 of the tank liquid 2 and extend vertically downward into the at a certain distance from one another Tank 1 in. The one component 3, which consists of a material that conducts well supersonic, is on the outside the end lying on the liquid 2 is connected to a supersonic transmitter 6. The other component 4 is in correspondingly connected to a supersonic receiver 7 at the same end. The supersonic transmitter sends short supersonic vibrations into the Component 3 from and the supersonic receiver generates according to the incoming supersonic vibrations electrical signals.

According to the invention, the two components 3, 4 are connected to one another by rigid transverse struts 8, which extend perpendicular to the components 3. 4. The purpose of these cross braces, which are preferably equidistant are distributed along the components 3, 4 is, on the one hand, the components with a corresponding distance to fix to each other and on the other hand to generate a supersonic cross-talk channel between the components 3, 4. Some of the oversail vibrations coming from the transducer 6 are transmitted along the component 3 forwarded and reached via the cross struts 8, which are located above the liquid surface 8, the Component 4, while the remaining vibration components are distributed in the liquid or directly below the Liquid surface 5 run. Some of the last-mentioned ones, which come to component 4 and are in this Transmitted oversail vibrations arrive at the receiver 7. It's obvious that those about the Cross struts transmitted oversail vibrations reach the receiver earlier than the vibrations, which have passed through the liquid 2. The transmitter 6 and the receiver 7 are with one Computer 9 connected, according to the present invention, the liquid level from the signals thereby calculates that it is the propagation times of the supersonic oscillation from the transmitter 6 to the receiver 7 Measured via the transverse webs 8 and the liquid 2 with knowledge of the forward speed occurring in the media, so that the measurement level is related to one of the transverse webs 8, which is above the liquid surface 5 is located.

In connection with the computer 9 it must be mentioned that there is only one with a receiver Component is present. the supersonic propagation speed in the transverse webs and the liquid obviously has to be programmed in some way. Because the conduction pathways in the liquid and in practice be short in the transverse webs and, for example, lengths of 10 to 30 mm the error influence remains small due to an erroneously assumed forwarding speed the liquid level determination If more than one receiver component is used, the continuation can be made

Determine the speed with the corresponding equations.

It should be noted that the liquid level measurement is based on the supersonic propagation time on the length of the measuring distance can only be disturbed on the relatively short path between the Liquid surface 5 and the overlying transverse web lies.

With regard to the fluctuations in the forwarding speed the sound waves in the liquid and the components due to temperature and Density fluctuations make it possible to reduce the measurement accuracy to improve significantly by increasing the number of components provided with receivers, such as it was mentioned earlier. With regard to the structure of the computer 9, there is a special feature according to one feature Advantage in providing two components provided with receivers, the distances between them and the sound transmitter in a ratio of 2: 1. In the F i g. 2a to 2c are the components in the aforementioned Way arranged. The component 10 carries the transformer, while the components 11 and 12 are provided with receivers. Cross webs 13 connect the components 10 to 12. In the F i g. 1a and Ic are the components in one Level, while according to F i g. 2b the components according to a preferred material, the corners of an isosceles Define triangle. According to a further feature run in the arrangement according to FIG F i g. 2c the transverse webs from component 10 alternately to component 12 and to component 11. In this way there is a particular advantage with regard to the temporal separation of the mutual cross-talk the transverse webs 13 to the corresponding receivers and the components 11, 12.

Obviously, it is desirable that a possible large part of the supersonic vibrations that takes its way through the liquid wedge and one with a receiver provided component hits, also reaches the recipient. If the cross-talk is good, it is possible to use the Reduce the effect of the supersonic transmitter and the dynamics of the computer without compromising the measurement accuracy to affect. In the F i g. 3a to 3e. whose reference numerals correspond to the reference numerals Parts in Fig. 1, different measures have been taken to improve such To effect cross-talk. In Fig.3a are the sides of the component 4, which face the component 3, at least partially with a material covered, the surface of which carries projections 14 to improve the cross-talk between the Liquid 2 and the component 4 ensure and also cause the supersonic component that the recipient of the Component 4 is reached, is enlarged. To do this optimally To achieve this, the acoustic impedance of the material should be substantially equal to the geometric mean the impedances of the liquid and components. In Fig. 3b the component 4 is provided with notches 15, which are located on the side that is remote from component 3. also in this way the cross-talk to improve. The in F i g. 3c to 3e shown reflector surfaces 16 have the same function. In F i g. 3c, a reflector surface, which is carried by a float 17, lies between each pair of cross struts will. The float 17 can move along the component 4 according to its buoyancy in the liquid move so that the surface 16 is immediately below the liquid surface 5. Apart from the reflector surface 16 can also be carried by a common float 18, which can move along the components 3. 4 (Fig. 3d). F i g. 3e shows a further modified arrangement at of a plurality of reflector surfaces along a? elongated component are distributed so that the reflector surfaces between the components 3, 4 bcfin the.

1 sheet of drawings

Claims (9)

Patent claims: 1. Device for measuring the liquid level in a tank or the like with at least two elongated, vertically protruding down into the tank, with a predetermined distance from each other arranged components, one of which is connected to a supersonic transmitter which repeatedly transmits short supersonic vibrations in the component, while the other component connected to a receiver. who responds to supersonic vibrations and receives them converts genen supersonic vibrations into electrical signals and also with a transmitter and receiver connected computer, which with the help of the electrical signals the liquid level as Function of the propagation time of the supersonic oscillation calculated from the transmitter via the components and the tank liquid to the receiver. characterized in that a) the components are connected to one another by rigid cross struts (8; 13) which are identical Distances perpendicular to the components (10, 11, 12) and on the one hand the layers and Define the distances between the components relative to one another and, on the other hand, as cross-talk channels or sound bridges between the components are used, b) the liquid level measurement on that of the liquid surface The cross brace closest to the top is related. 2. Apparatus according to claim 1, characterized in that three components (10, 11, 12) are arranged to one another in such a way that the distances between the component (10) connected to the transmitter (6) on the one hand and the one with the receivers (7) connected components (11, 12) on the other hand different and corresponding to a 2: 1 ratio corresponding to the measurement result with respect to the Swan ^ _{0 is} the propagation velocity fluctuations of the supersonic vibrations in the transverse struts (13) and in the liquid (2) to be corrected. 3. Device according to claim 2, characterized in that that the components (10, 11, 12) are arranged according to the corners of an isosceles triangle are. 4. Apparatus according to claim 1 or 2, with at least three components, characterized in that the cross struts (13) offset in the longitudinal direction from the component (10) connected to the transformer (6) to the components (11, 12) connected to a receiver (7). 5. Apparatus according to claim 1 to 4, characterized in that the component or components provided with the receiver (s) are covered at least partially along their component facing the transmitter (6) with a material, the acoustic impedance of which corresponds to a geometric mean value of the acoustic impulse / the 6ο liquid and the components. Un.i caü the surface of this material is provided with sacrificial projections, which amplify the (speaking of the supersonic vibrations and the components (3, 4) and increase the part of the supersonic vibrations, change the direction of propagation / den Lnpfänjcrn)? ueewandi is b. Device according to Claims 1 to 4, characterized in that the person with the recipient (s) connected component (s) is / are provided with, for example, notch-shaped recesses, which are located on the sides that are separated from the component (3) connected to the transformer (6) are. 7. Apparatus according to claim 1 to 6 thereby characterized in that between the component (3) connected to the transformer (6) and the / themselves component (s) (4) extending parallel to it and connected to receivers is an additional elongated one Component (18) is arranged, which at regular intervals perpendicular to the components (3, 4) has aligned surfaces (16) which come from the first-mentioned component (3) Supersonic vibrations within the liquid (2) against the components connected to the receivers (7) (4) reflect. 8. Apparatus according to claim 1 to 4, characterized in that one or more components (3, 4) between the individual cross struts (8) contain a float (18) between the cross struts (8) is movable and carries a reflector surface (16) which is perpendicular to the components (3, 4) and the supersonic vibrations transmitted in the liquid differ from that with the transmitter (6) connected component (3) is reflected in the direction of the components (4) provided with receivers (7). 9. Apparatus according to claim 1 to 4, characterized in that a single float (18) is provided which is movable over the entire length of the components (3, 4) and is perpendicular to the components (3, 4) extending reflective surface (16) with which the transmitted in the liquid (2) Supersonic vibrations from the component (3) connected to the transformer (6) to the with receivers (7) provided components (4) are reflected.