DE3833145A1 - Floating-body flow meter with ultrasonic position measurement - Google Patents

Abstract

A floating-body flow meter with ultrasonic (US) position measurement for the determination of the position of the floating body in a measuring tube, in which it is provided that there is a sensor module (3) which can be mounted, preferably by screwing in, in the cover plate of a closing cap (2) of the measuring tube (1), the cap being provided with an inflow stub or an outflow stub (2a), the said sensor module (3) consisting of a sensor carrier (31) which contains in it a first US transducer (32) radiating axially in the direction of the floating body (4) for measuring the distance between the transducer surface of the first US transducer (32) and the surface of the floating body (4) facing it, and a second US transducer (33) radiating radially in the direction of the wall of the closing cap (2) or of the measuring tube (1) for measuring the transit time of the US waves over the known distance between the transducer surface of the second US transducer (33) and the wall, and that the output signals of the first and second US transducers (32, 33) produced as a result of excitation signals fed to the US transducers (32, 33) can be fed to an evaluation device for determining the distance of the floating body (4), using the determined transit time in the evaluation process. <IMAGE>

Description

The present invention relates to a variable area flow knife with ultrasonic position measurement to determine the position of the float in a measuring tube.

For the widely used flow meter after the levitation body or spring washer principle, cf. B. Technical Messen tm, 52nd year, issue 1/1985, p. 21, should be a simple one electronic tap for the position of the measuring body will.

In previously known arrangements for contactless positions Detection of a float is a measuring method by means of Differential throttle provided, see z. B. Company brochure from Krohne Messtechnik GmbH & Co. KG, Duisburg, Germany: "Be contactless position detection of a body by a noble steel tube wall according to the principle of the differential transformer " by R. van der Pol, p. 21.1 ... 21.7. This known technique dert a relatively complex device that a large Has volume and, moreover, a measuring tube with predetermined magne technical properties.

Have the variable area and spring washer flow meters the important property of the local process engineering Display without auxiliary energy, cf. B. "Technical measurement tm, 52nd year, volume 1, 1985, p. 20. To display the measured value is in the transducers previously used, one with line marks ver see glass tube together with the measuring body (float, spring disc), a magnetically coupled drag pointer or a dif Ferentialdrossel-arrangement provided with microcomputer.

The invention has for its object an arrangement for measuring solution of the position of the measuring body, which in a known manner Flow rate characterized, by means of a suitably chosen  To create arrangement of ultrasonic transducers, the Arrangement simple in construction, inexpensive and small volume should be and the advantage of the direct display of the Meßkör perlage should be given.

A variable area flow meter is used to solve the problem of the type mentioned and according to the preamble of the patent claims 1, 2 and 3 proposed, each by the characterizing features of these claims is.

Advantageous developments of the invention are shown in the Characteristics indicated subclaims.

In the following the invention will be based on several figures wrote.

Fig. 1 shows the basic structure of a conventional floating body flow meter.

Fig. 2 u. Fig. 3 show different embodiments of the float flow meter according to the invention.

Fig. 4 is a block diagram showing an evaluation device.

As can be seen from the construction according to FIG. 1, the transducer or transducers can be attached to the upper, lower or both ends of the measuring tube. The design of the measuring body has to take into account the chosen arrangement. All the principles known in connection with the distance measurement are suitable as methods for evaluating the US signals.

A typical arrangement according to the invention is shown in FIG. 2. Here, a module 3 is screwed into the end cap 2 of the measuring tube 1 . Another possible arrangement is shown in FIG. 3. The sensor module 3 'contains a sensor carrier 31 ' provided with one or more support arms, which carries a lower and an upper US transducer 32 ', 33 '.

Common to both embodiments is one in the direction of measurement body shining US converter. The one used as a reference US converter acting second US converter radiates against one in a known Distance from the wall. As a result, the influence of the media and temperature-dependent speed of sound. Another solution to this problem is both End of the measuring tube one in the direction of the measuring body to attach radiant US converters.

In particular, for the embodiment according to FIG. 2, it is provided that a cover flap 2 of the measuring tube 1 provided in the cover plate of a connection piece with an inflow or outflow 2 a is preferably provided by screw-in sensor module 3 , which consists of a sensor carrier 31 , the in itself a first, axially in the direction of the float 4 radiating US transducer 32 for measuring the distance between the transducer surface of the first US transducer 32 and the surface of the float 4 facing this and a second, radially in the direction of the transducer of the end cap 2 or the measuring tube 1 radiating US transducer 33 for measuring the transit time of the US waves above the known Ab between the transducer surface of the second US transducer 33 and the wall contains, and that the excitation signals supplied by the transducers 32 , 33 resulting output signals of the first and second US converters 32 , 33 of an evaluation device for best The distance of the float 4 can be determined by including the determined transit time in the evaluation process.

For the embodiment according to FIG. 3 it is provided in detail that a in the wall of a with an inflow or outflow pipe 2 a end flap 2 of the measuring tube 1 is preferably screwed in sensor module 3 'is given, which consists of one with one or more support arms provided sensor carrier 31 ', which has a first, axially in the direction of the floating body 4 radiating US transducer 32 ' for measuring the distance between the transducer surface of the first US transducer 32 'and the surface of the float 4 facing this and a second, axially in the direction of the cover plate of the end cap 2 radiating US converter 33 'for measuring the transit time of the US waves over the known distance between the transducer surface of the second US converter 33 ' and the cover plate carries, and that due to the US converters 32 ', 33 supplied excitation signals resulting output signals of the first and second US converter 32 ', 33 ' of an evaluation device for determining the position of the float 4 , including the average transit time it can be fed into the evaluation process.

For a further embodiment (not shown), that at each of the ends of the one enclosing the float Measuring tube one axially in the direction of the upper and the lower Surface of the float radiating upper or lower US converter to determine the duration of the US waves over the Distance between the transducer surface of the upper US transducer and the upper surface of the float or the transducer surface of the lower US converter and the lower surface of the float is given and that due to the US Output signals generated by transducers are generated nale of the upper and lower US converter of an evaluation direction for determining the position of the float Taking into account the two terms can be fed together.

Advantageously, US reflective marks can be in the measuring tube be arranged for the purpose of automated calibration.

An advantageous development of the invention provides that a preferably attached to the sensor carrier temperature sensor 34 for determining the temperature of the medium flowing through the measuring tube is given and that the temperature representative output signal of the temperature sensor 34 as a parameter for determining the position of the float from the output signals of the US converter 32 , 33 , 32 ', 33 ' is used by means of the evaluation device. The temperature sensor can also be attached to the measuring tube in the flow region of the medium.

An evaluation device contains an evaluation circuit 51 receiving and at least preprocessing the output signals of the US converters 32 , 33 and a microprocessor 52 with a sensor interface 521 receiving the output signal of the temperature sensor 34 and the output signal of the evaluation circuit 51 , a display device 522 , a keyboard 523 for inputting Correction or control variables etc. and an interface 524 to an external device, e.g. B. a process computer, see FIG. 4.

Ultrasound reflecting can be used for automated calibration Marks must be attached to the inside of the measuring tube. Ins The position of the float when stationary is also special Medium used for calibration. An additionally attached brought temperature sensor measures the temperature of the medium. The The location of this sensor is arbitrary, but should be in the Flow range of the medium lie.

The arrangement described above can also be applied accordingly a spring washer flow meter.

A significant improvement in measuring accuracy can be counteracted over the evaluation devices previously used by a Correction of the static and dynamic properties of the measurement achieve sensor. Furthermore, there is the possibility that Density and viscosity of the measuring medium in the evaluation too consider. Analog or digital are available for this Correction elements. Because of the greater flexibility, the Use of a microcomputer advantageous. The values of the Koeffi the correction polynomials and the filter equation as well as the Values of density, viscosity and the dependence of these Sizes of the temperature are advantageously in one Storage filed.

Claims (7)

1. Variable area flow meter with ultrasound (US) - Posi tion measurement to determine the position of the float in a measuring tube, characterized in that in the cover plate with an on or off flow connector ( 2 a ) provided end cap ( 2 ) of the measuring tube ( 1 ) sensor module ( 3 ), which can be mounted by screwing in, is provided, which consists of a sensor carrier ( 31 ) which contains a first US transducer ( 32 ) radiating axially in the direction of the float ( 4 ) for measuring the distance between the Transducer surface of the first US transducer ( 32 ) and the surface of the float ( 4 ) facing it and a second US transducer ( 33 ) radiating radially in the direction of the wall of the end cap ( 2 ) or the measuring tube ( 1 ) for measuring the Contains the travel time of the US waves over the known distance between the transducer surface of the second US transducer ( 33 ) and the wall, and that they learn from the US wall ( 32 , 33 ) supplied excitation signals resulting output signals of the first and second US converter ( 32 , 33 ) of an evaluation device for determining the distance of the float ( 4 ) can be fed into the evaluation process including the determined transit time ( Fig. 2). 2. Variable area flow meter with ultrasound (US) -Posi tion measurement to determine the position of the float in a measuring tube, characterized in that in the wall of a nozzle with an inflow or outflow ( 2 a ) provided end cap ( 2 ) of the measuring tube ( 1 ) preferably screw-in sensor module ( 3 ') is provided, which consists of a poorly provided with one or more support sensor carrier ( 31 '), the first, axially in the direction of the float ( 4 ) radiating US wall ler ( 32 ') for measuring the distance between the transducer surface of the first US transducer ( 32 ') and the surface of the float ( 4 ) facing it and a second US transducer ( 33 ) radiating axially in the direction of the cover plate of the end cap ( 2 ) ') For measuring the transit time of the US waves over the known distance between the transducer surface of the second US transducer ( 33 ') and the cover plate carries u nd that due to the US transducers ( 32 ', 33 ) supplied excitation signals output signals of the first and second US transducers ( 32 ', 33 ') of an evaluation device for determining the position of the float ( 4 ) including the determined Runtime can be fed into the evaluation process ( Fig. 3). 3. Variable area flow meter with ultrasound (US) -Posi tion measurement to determine the position of the float in a measuring tube, characterized, that at each of the ends of the one enclosing the float Measuring tube one axially in the direction of the upper or the lower surface of the float radiating upper or lower US converter to determine the transit times of the US wel len about the distance between the transducer surface of the upper US transducer and the upper surface of the float pers or the transducer surface of the lower US transducer and the lower surface of the float is provided and that the stimulus supplied by the US converters The resulting output signals of the upper and of the lower US converter of an evaluation device for determination the position of the float by referencing the two terms can be fed together. 4. variable area flow meter according to one of claims 1 to 3, characterized, that in the measuring tube US reflective marks for the purpose of a automated calibration are arranged.   5. variable area flow meter according to one of claims 1 to 3, characterized in that a preferably attached to the sensor carrier temperature sensor (34) is provided for determining the temperature of the medium flowing through the measuring tube and that the temperature signal representing the output signal of the temperature sensor ( 34 ) is used as a parameter for determining the position of the Schwebekör pers from the output signals of the US converter ( 32 , 33 ; 32 ', 33 ') by means of the evaluation device. 6. variable area flow meter according to claim 5, characterized, that the temperature sensor on the measuring tube in the flow area the medium is attached. 7. variable area flow meter according to one of the preceding claims, characterized in that the evaluation device ( 5 ) receiving the output signals of the US converter ( 32 , 33 ) and at least preprocessing evaluation circuit ( 51 ) and a microprocessor ( 52 ) with a the output signal of the temperature sensor ( 34 ) and the output signal of the evaluation circuit ( 51 ) receiving sensor interface ( 521 ), a display device ( 522 ), a keyboard ( 523 ) for entering correction or control variables, etc. and an interface ( 524 ) to one external device, such as a process computer, contains.