EP2215432A1 - Measuring system, particularly for measuring flow of a measurement medium flowing in a pipe - Google Patents

Abstract

The invention relates to the construction of a measuring system made of at least two materials having different thermal expansion coefficients, such that different measurement deviations induced by temperature that occur with a conventional construction are corrected or do not occur.

Description

 Measuring system, in particular for flow measurement of a flowing in a pipeline medium

The present invention relates to a measuring system, in particular for

Flow measurement of a flowing in a pipe measuring medium, in particular a fluid, which measuring system comprises a measuring tube and at least two holding elements for holding at least one functional component, in particular for holding sensors, which each functional components have at least one functional surface comprises, which measuring tube comprises a support tube which holding elements are in each case connected to the carrier tube at at least one connecting surface and in each case two mutually opposite connecting surfaces of the holding elements have a distance Y and two respective opposing functional surfaces of the functional components, which are held in the holding elements, have a distance X.

There are measuring systems, in particular from the magnetic inductive flow measurement or from the flow measurement based on ultrasound known, where at least two sensors face each other, wherein at least one sensor picks up a measurement signal, which depends inter alia on the distance of the sensors. There is a signal path between the sensors.

US7044001 B2 describes an ultrasonic flowmeter wherein two ultrasonic sensors are spaced apart at an angle to a support tube on which the sensors are mounted. A signal which is emitted by a first sensor in the direction of a second sensor, the speed of the flow of the measuring medium flowing in the support tube is determined by this receiving and the propagation times of the signal.

Ultrasonic flowmeters are widely used in process and automation technology. They allow in a simple manner, the volume flow in a pipeline to determine contactless. The known ultrasonic flowmeters often work after the Doppler or after the transit time difference principle.

When running time difference principle, the different maturities of ultrasonic pulses are evaluated relative to the flow direction of the liquid. The fact is exploited that the propagation velocity of ultrasonic waves in a medium is directly influenced by its flow velocity.

For this purpose, ultrasonic pulses are sent both in and against the flow. The runtime difference can be used to determine the flow velocity and, with a known diameter of the pipe section, the volume flow rate.

The ultrasonic transducers normally consist of a piezo element, also called piezo for short, and a coupling element, also known as a coupling wedge or, more rarely, a precursor body, made of plastic. In the piezoelectric element, the ultrasound is generated and guided via the coupling element to the pipe wall and from there into the liquid. Since the speeds of sound in liquids and plastics are different, the ultrasonic waves are refracted during the transition from one medium to another. The refractive angle is determined by Snell ^'s law. The angle of refraction is thus dependent on the ratio of the propagation velocities in the two media.

Usually, the coupling element is aligned on the pipe or in a sensor holder attached to the pipe.

WO03 / 006932A1 shows the structure of an ultrasonic sensor. The materials from which the coupling elements are made, usually have certain properties to conduct ultrasonic signals, at the same time they usually have a higher thermal expansion than the sensor sleeve. They are firmly inserted into the sensor sleeve or potted in this, in order to prevent a temperature-induced expansion of the coupling elements. Thus, coupling element and sensor sleeve form a contact surface. On the other hand, the measurement error due to a temperature expansion of the measuring tube or the sensors themselves, ie the temperature dependence of the measurement of the geometric dimensions of the measuring system, in particular the distance of the sensors from one another and thus the signal path, did not receive any attention.

The object of the invention is to propose a measuring system for measuring a fluid flowing in a pipeline or in a measuring tube, which has a high measuring accuracy over a wide temperature range.

The object is achieved in that measuring system, in particular for flow measurement of a flowing in a pipeline medium, in particular a fluid is proposed, which measuring system a measuring tube and at least two holding elements for holding in each case at least one functional component, in particular for holding sensors, which functional Components each have at least one functional surface comprises, which measuring tube comprises a support tube, which holding elements are connected to each at least one connecting surface with the support tube and each two opposing connecting surfaces of the holding elements have a distance Y and two are opposing functional surfaces of the functional components, which are held in the holding elements, have a distance X, wherein geometries and material-own sizes of the holding elements and / or geometries and material-own sizes of the functional components and Geomet rien and material own sizes of the support tube are coordinated so that relative distances X (T) = ^ of the functional surfaces of the functional components in

X (T ₀ )

Dependence of a temperature T of the measuring medium flowing through the measuring tube, starting from an initial temperature T _{0 of} the measuring medium, so dividing that temperature-related measurement deviations at a temperature change AT = TT _{0 of} the measuring medium, in particular due to temperature-induced changes in the geometries of the support tube and / or due to temperature-dependent changes of material and / or flow properties of the measuring medium and / or due to temperature-induced changes in a Stgnalpfads, smaller than the temperature-induced deviations at a temperature change ΔT = TT _{0 of} the medium to be measured, which at relative

Distances Y (T) = - - the functional surfaces of the functional components occur. Y (T ₀ )

A measuring system thus has n holding elements, where n is an element of the natural numbers. Each two connecting surfaces m and k have a distance Y _mk and two functional surfaces q and r have a distance X _qr , wherein associated holding elements, connecting surfaces, functional components and Funktäonsflächen each have the same index, ie where Haiteelement i with the support tube on the connection points i is connected, the functional component i with the functional surfaces i in turn is supported by the holding element i and i = 1,..., n. Geometries and material-own sizes of the holding elements and / or geometries and material-own sizes of the functional components and geometries and substance-own sizes of the support tube are coordinated so that relative distances x functional surfaces of the functional components in Dependence of a temperature T of flowing through the measuring tube

Set measuring medium, starting from an initial temperature T _{0 of} the measured medium, so that the measurement deviations, less than 50%, preferably less than 20%, in particular less than 10%, in particular less than 5%, in particular less than 2%, in particular less than 1%, than the Measuring deviations are those at relative

Y (J) distances Y (T) = ^{q of} the functional ^surfaces of the functional components occur.

Y _qr (τ ₀ )

A geometry characterizes the structural design, in particular size and shape, of a body. In addition to the external dimensions, for example, density or porosity in the case of open or closed-pore structures are also determined by the geometry. These parameters are inventively given within certain limits. In contrast to material constants, material-specific quantities can change over time and / or via further parameters, in particular via temperature. They are usually calculated using functions, including material constants as coefficients. Thus, thermal expansion, or thermal expansion, is usually described by α, as most physical quantities are not linear. In general, x ^ ^χ _o * (1 + Ji ₁ AT + k ₂ (ΔT) ² + ... + k, χAT) "), with the temperature difference AT = (TT ₀ ), where X _{0 is} the physical quantity is a temperature T ₀ , and with the nth-order temperature coefficients _kn , where n is an element of the natural numbers For the region of interest, the thermal expansion is assumed to be linear.

The basic idea of the invention is the construction of the holding elements and / or the functional components of at least two materials whose thermal expansions are different from each other. In addition to the flow measurement, the invention can also be used in FüNstandsmessung. The shape of the measuring tube is not limited to a circular cross-section. Rectangular tubes or other known from the level measurement container container can be configured according to the invention. Due to the temperature-dependent adjustment of the distance of the functional surfaces, temperature-related measurement errors can be reduced, which would occur in a measuring system where the material's own sizes in relation to the geometry of the measuring system are not sufficiently taken into account in the design of the measuring system according to the invention.

Depending on the measuring error to be compensated for or reduced or depending on the measurement errors to be compensated or reduced, the settings of the spacings of respectively two functional surfaces can lead to a reduction of a measuring error or the division of several opposing functional surface pairs contributes to the mentioned compensation , which can experience quite different Abstandsäπderungen, so the interaction of different distance changes leads to the measurement error reduction.

Functional surfaces may be, for example, the sound exit or the sound output surface of the coupling elements in ultrasonic sensors, the Schalfeintritts- or the Schalleinkoppelflächen the Koppeleiemente or the piezoelectric elements or magnetically inductive flow meters, the opposing electrode surfaces. The wide temperature range is the range in which the thermal expansions can be predicted or predicted, in particular the range in which the linear laws of thermal expansion and stiffness apply and can be assumed. The limits are substance-dependent.

The essential idea of the invention is to match the geometric relationships of sensor and carrier tube and their properties with respect to their expansion over the temperature so that the influence of the temperature of the measuring tube is reduced to the measurement. The effects of different expansion over temperature of support tube and retaining element and / or functional component compensate each other in the ideal case. For example, there is the support tube and the holding member made of a first material and the functional component consists of a second material, wherein both materials differ and the coefficients of thermal expansion of both Materiaien and the geometric dimensions of the support tube and retaining element and functional component are coordinated accordingly. Depending on the application, this can be changes both in the radial direction of the measuring tube and in the axial direction. As a result, the measuring accuracy is less dependent on the temperature of the medium to be measured.

The material of the functional component, such as a Ultraschallkoppeielements is no longer selected purely for manufacturing aspects or the quality of the sound-influencing properties, but the geometric dimensions of the functional component and / or the support member are dependent on the ratio of the geometric dimensions of the support tube and / or the Halteeiements, the substance-own sizes of the material of the support tube and / or the holding element and the intended use of the measuring system. Among other things, the temperature expansion coefficients are included for material selection. Of the

Thermal expansion coefficient of the functional component support tube and / or the holding element is a function of the coefficient of thermal expansion of the support tube and / or the holding element. The sound velocities in coupling elements, carrier tube and / or measuring medium are relevant for the measurement with an ultrasonic flowmeter, the electrical conductivities for a magneto-inductive measuring device. However, some of these are known or a prerequisite for the material used or they can be determined during or shortly before the actual measurement. Thus, they are not relevant to the geometric design of the measuring system in the production of the measuring system according to the invention.

The support tube expands upon heating or cooling in a certain dependence on the temperature difference around which it is heated or cooled, and on material-own sizes of the material of which the support tube consists, and on the geometric conditions of the support tube. A technically qualified person is usually known in this context as the term expansion, although cooling is actually a shrinkage.

Similarly, retaining elements, which are fixedly mounted on the support tube and / or functional components expand. If the material of the functional component has a higher thermal expansion compared to the support tube and / or the holding element at the same temperature difference, the functional component expands more, so to a greater extent. Since the expansion of the functional component is limited at least in one direction by the retaining element or by the fastening in the retaining element, the functional component expands in a desired direction.

The material's own sizes are to be matched to the existing geometries. The measurement deviation due to the temperature-induced expansion of the support tube is, as already described, reduced by the deviating from the support tube expansion over temperature of the functional component and / or the Halteeiements.

This is particularly advantageous for flow measurements, where the error due to the thermal expansion of the piping system need not be considered separately. Since such a correction or a separate temperature measurement are not carried out at low-price solutions of a flow measurement, the invention enables cost-effective high measurement accuracy in comparison with the prior art Achieve technology. But also in the level measurement, the measuring system according to the invention can be used advantageously.

Depending on the application, isotropic materials may be used or anisotropic materials may be used for the production of the functional component and / or for the production of the support element and / or for the production of the support tube, in particular with different inherent sizes, e.g. axially and radially different coefficients of thermal expansion.

An example of a temperature-related measurement deviations, in addition to the geometric changes of the measuring system, is the temperature dependence of the speed of sound in the medium to be measured, which leads to a measurement error, especially in ultrasound flow meters.

Uneven temperatures on the outside of the measuring tube and the sensor and the measuring medium lead to a temperature gradient in the sensor. This problem may be compounded if the functional component is a good thermal insulator. Under certain circumstances, this temperature gradient leads to indefinite thermal expansions. The expansions are indefinite if the temperature gradient is unknown. If the temperature in the sensor and that in the environment is always approximately constant, the temperature gradient can be determined and taken into account in the design or dimensioning of the sensor. A favorable improvement, ie a reduction of the temperature gradient, provides good isolation, i. a good thermal insulation, on the outside of the sensor.

A further advantageous embodiment of the device according to the invention is to be seen in that the holding elements have a tempering device, whereby a predetermined temperature of the holding elements and / or the functional components attached to the holding elements is adjustable.

The tempering device can be located in the holding element and / or on the holding element, in particular around the holding element around. In particular in the case where sensors are attached to the holding elements and functional components of the sensors or their distance from each other are to be aligned, If the sensors are to be tempered, it is preferable for temperature control devices to be mounted in and / or on and / or around the sensor housing.

Preferably, the temperature of the temperature control device is controlled by the temperature of the medium to be measured as a controlled variable or it depends on the time course of the temperature of the medium and / or the temperatures in the support tube and / or the temperature of the environment of the measuring system.

Many design examples for tempering are conceivable. Thus, preferably heating wires or in designated facilities flowing

Cooling or heating fluids, in particular in connection with at least one

Temperature sensor, which determines the temperature of the medium used.

A limitation to the aforementioned embodiments is not hereby given.

According to an advantageous embodiment of the invention it is proposed that a relative change AX (T) = ^X ^ ^'X ^ of the distance of the functional surfaces of the

X (T ₀ ) functional components at a temperature change AT-TT _{0 of} the measuring medium, starting from an initial temperature T _{0 of} the measuring medium, is smaller than a relative change AY (T) - ^γ (T) - ^γ ( ^τo ) of the distance of the connecting ^surfaces of

Y (T ₀ )

Support tube.

A very advantageous embodiment of the device according to the invention provides that a relative change .DELTA.Z (r) = ^{X (} ^ ^T ' ^{) "X (} ' ^To ^ the distance of the functional surfaces

X (T ₀ ) of the functional components at a temperature change AT = TT _{0 of} the measuring medium, starting from an output temperature TQ of the measuring medium, is approximately zero.

The distance of opposing functional surfaces of the functional components is approximately constant over a wide temperature range or a distance of, the measuring medium facing sides of, on the functional surfaces of bodies attached to functional components is approximately constant over a wide temperature range, or a distance of sides or surfaces of the bodies, in particular sensors, which are attached to the functional surfaces of the functional components is approximately constant over a wide temperature range.

In a measuring system according to the invention with n holding elements, where n is the natural number element and in each case two connecting surfaces q and r, which have a distance Y _qr and two functional surfaces q and r, respectively, which have a distance X _qr , wherein associated holding elements,

Connecting surfaces, functional components and functional surfaces each have the same index, i. wherein Haiteeiement i is connected to the support tube at the joints i, the functional component i with the functional surfaces i in turn is supported by the holding element i and i- 1, ..., n, are geometries and material-own sizes of the Haiteelemente and / or geometries and In-house sizes of the functional components and geometries and material-specific sizes of the support tube are coordinated so that a relative

X (T) -X (T) change AX qm = ^q Y / T ^q1 I of the distance of the functional ^surfaces of the

^Ä qrUθ) functional components at a temperature change ΔT = T-To of the measured medium, starting from an initial temperature T _{0 of} the Meßmedäums, less than 50%, preferably less than 20%, in particular less than 10%, in particular less than 5%, in particular less than 2%, in particular less than 1%, is, as a relative change

Y (T) - Y (T) & Ϋ _ψ (T) = ^q - the distance of the connecting surfaces of the support tube. )

If sensors such as ultrasonic wall mounted on the holding elements, the distance between the functional components or the functional surfaces of the sensors, such as piezoelectric layers or the surface of the sound outlet from the sensor into the measuring medium, which emit and receive the Uftraschallsignal over a wide temperature range approximately constant. Thus, opposing sensors, which face each other in particular axially, in particular in a measuring tube for flow measurement, a in a wide temperature range approximately the same distance and thus one approximately the same signal path. A temperature-related measurement deviation, as occurs in the prior art by changing the signal path under the influence of temperature, is significantly reduced.

In combination with a pipeline with approximately constant

Inner diameter, for example, a lined with a liner carrier tube, this is among other things particularly advantageous for ultrasonic flow measuring devices, which measure the transit time parallel to the flow direction of the medium.

If, for example, a measuring system according to the invention which determines a flow with a method which requires at least one measured value and a free cross-section A of the measuring tube, the distance of the sensors over a wide temperature range can be kept constant, but by the extension of the support tube is Messfehier introduced into the calculation of the flow. If the free cross section of the measuring tube or its clear width is kept constant, the measurement error is substantially reduced. But also in the level measurement, the measuring tube according to the invention can be advantageously used. Thus, the distance of sensors or the length of a signal path can be kept approximately constant, as e.g. also with magnetic inductive flowmeters or optical measuring devices.

A further development of the invention provides that the flow measuring system operates on the basis of ultrasound and comprises at least two ultrasonic sensors spaced apart from one another parallel to the main flow direction of the measuring medium in a measuring tube, wherein the inner diameter of the

Measuring tube is approximately constant over a wide temperature range and wherein the distance of the functional surfaces of the sensors over a wide temperature range is approximately constant. The functional surfaces of the ultrasonic sensors are the ends of the leading bodies of the ultrasonic sensors. They fulfill the function of the transmission of the sound from the sensor to the measuring medium and back. The Voriaufkörper are preferably fixed in a metal sleeve, which in turn serves as a holding element, wherein the fixing of the flow body in the metal sleeve is designed so that the flow body can expand freely in the direction of the opposite sensor, so the sensors each at the, the opposite end facing away from the sensor body to the holding element, ie in the metal sleeve, are fixed. The flow body itself thus represents a functional component with the sound output surface as a functional surface. An alternative is the fixation of the ultrasonic sensor to a holding element, wherein the sensor facing away from the opposite end of a sensor is fixed to the holding element. In both cases, the flow body is the distance-compensating functional component, a lining of a support tube comparable or accepting their functionality, which compensates for the axial extent of the measuring tube and optionally the first part of the support member. Such a Ultraschallail-Messzeiie can have very small dimensions and is therefore variable.

In a further advantageous embodiment of the invention, a flow measuring system is proposed, wherein the distances of the functional surfaces of the sensors over a wide temperature range are approximately constant, the angle of the functional surfaces to each other but change over the temperature.

A very advantageous variant of the solution according to the invention can be seen in the fact that the length of the measuring tube over a wide temperature and / or

Pressure range is approximately constant. In particular, the length of the central axis of the measuring tube inlet to the measuring tube outlet is referred to as the length of the measuring tube.

The Haiteeiemente can, in addition to sensors, for example, the tube ends closing plates, creating a hollow cylinder with a, over a wide temperature range constant volume. The functional surface or the side of the functional component which faces the measuring medium is the side of the plate which points into the tube to the measuring medium. The holding elements may in this case be designed as a plate itself. Such a container with a, over a wide temperature range constant volume, can be used in many areas. With it can be particularly advantageous measure a volume of a fluid. Another expedient embodiment of the solution of the invention is that the distance of the functional surfaces of the sensors in dependence on the change in cross section of the measuring tube, that is, to the change in the inner diameter. Thus, a compensation or reduction of temperature-related measurement deviations, in particular due to temperature-induced changes in the geometries of the measuring tube and / or due to temperature-dependent changes of material and / or flow properties of the measuring medium and / or due to temperature-induced changes in a signal path, even with a measuring tube without Auskäeidung, by setting the sensor distance possible.

The invention will be explained in more detail with reference to the following figures,

Fig. 1 shows a sectional view in the longitudinal direction of an inventive

Measuring tube 1 with holding elements and functional components. Fig. 2 shows a sectional view in the longitudinal direction of an inventive

Inline Ultraschali measurement system.

Fig. 3 shows a detailed view of a HaStelements in section. Fig. 4 shows a detailed view of another holding element in section.

1 shows a sectional view in the longitudinal direction of a measuring tube 1 according to the invention with holding elements 14 and functional components 28. The holding elements 14 are made of a first material, the functional components 28 of a second material, the functional components 28 are preferably glued to the holding elements 14 or otherwise materially interconnected. The Haiteelemente 14 are firmly connected to the support tube and protrude into the interior of the measuring tube 1 in. The material from which the holding elements 14, which are connected to the support tube 2, are made, is matched with the material of the support tube 2. Thereby, the radial extent of the support tube 2 is compensated and the holding elements 14, remain in the radial direction over a wide temperature range at the same position. The material of the functional components 28, which compensate for the axial extent of the support tube 2, is also dependent on the material of the support tube 2. In addition, it depends on the material of the holding elements 14 and on the geometries of the components. The functional components 28 have functional surfaces 16, the mutual distance 15 is dependent on the temperature-dependent thicknesses of the functional components 28 and the temperature-induced increase of the Haiteelemente 14 in the axial direction of the support tube 2. The Funktionsfiächen 16 may have a, over a wide temperature range, the same distance 15 to each other, so that, for example when attaching sensors, a parallel signal path of constant length to the main flow direction of the measuring medium 4 is formed. On the other hand, their distance may also depend on the structure of the attached sensors. These are in turn subject to a geometric temperature dependence. Since this temperature dependence of the sensors is known, the structural design of the Haiteelemente 14 may be designed so that not have the functional surfaces 16 gieächen distance, but functional surfaces of the sensors. The geometry and the materials of the sheath elements 14 and the functional components 28 are thus additionally dependent on the geometry and the materials of the sensors applied to them.

Fig. 2 and Fig. 3 are explained in more detail below together for the sake of simplicity. FIG. 2 shows a longitudinal sectional view of an inline ultrasound measuring system according to the invention with an approximately constant distance 15 and an approximately constant angle of the functional surfaces 16 of the ultrasonic sensors to one another. As functional surfaces 16, the areas facing the measuring medium 4 and the mutually opposite surfaces of the flow body 24 are considered here. Likewise, piezo elements or other functional elements would be possible. The flow body 24 are on the one hand part of the sensors and at the same time functional component. In Fig. 3 is a detail view of an ultrasonic sensor is shown. The structure of a sensor is at least two parts, ie it consists of at least two joined parts, which consist of different materials. Here it is the sensor sleeve 25 and the flow body 24. For better clarity, the sensor sleeve 25 is cut and the flow body 24 shown uncut. The sensor sleeve 25 is firmly connected to the support tube 2. It preferably consists of a material with a similar coefficient of thermal expansion as the support tube 2. It can also be made of the same material. The sensor sleeve encloses the flow body 24 radially completely. The flow body 24 is made of a different material than the sensor sleeve 25, in particular its thermal expansion is significantly higher, and it is preferably stoffschiüssig connected to the Sensorhüise 25, preferably via an adhesive surface 26, which extends circumferentially around the flow body. The opposing between the two adhesive surfaces 26 parts of the flow body 24 of the two sensors can expand freely in the direction of the respective opposite sensor. It is achieved, the structural design of the flow body 24 depending on the materials used by Voriaufkörper 24, sensor sleeve 25 and support tube 2 and depending on the geometries of the sensor sleeve 25 and support tube 2 provided that the distance 15 of the two functional surfaces 16 of the Voriaufkörper 24 via a wide temperature range is approximately constant. Likewise, it can be achieved that the angles between the functional surfaces 16 of the sensors are approximately constant over a wide temperature range.

4, another holding element with a functional component is shown in section. in the measuring tube 1, a bore 30 is provided. In the bore 30, a first disc 31 is inserted with an opening 31 so that it closes the outside of the measuring tube 1 and a second disc with an opening 32 forms with the inside of the wall of the measuring tube 1 a conclusion. Between these discs 31 and 32, sealed with O-rings 33, a membrane 34 with a clamped body, such as a therein gehaiterter lead body 24, introduced. The membrane 34 is made of a different material than the measuring tube 1, can move between the discs 31 and 32 in the longitudinal direction of the measuring tube 1 and is designed so that the temperature-dependent longitudinal extent of the measuring tube 1 is compensated at the flow body 24. Thus, for example, the distance between two Voriaufkörper be kept approximately constant. LIST OF REFERENCE NUMBERS

1 measuring tube

2 carrier tube

3 lining

4 measuring medium

5 Inner diameter of the measuring tube

6 Length of the measuring tube

7 tempering device

8 channels

9 carrier tube wall

10 signal path, e.g. acoustic path

11 channels in the lining

12 input of the measuring tube

13 Output of the measuring tube

14 holding elements

15 Distance between the functional surfaces of the retaining elements

16 functional surfaces

17 shoulders

18 Inner lining wall

19 Outer lining wall

20 Frontal lining walls

21 line

22 footbridge

23 spacers

24 flow body

25 sensor hips

26 adhesive surface

27 measuring channel

28 Functional component

29 interface

30 hole

31 First disc with opening Second disc with opening seal diaphragm

Claims

claims

1. Measuring system, in particular for flow measurement of a flowing in a pipeline measuring medium (4), in particular a fluid, which

Measuring system, a measuring tube (1) and at least two holding elements (14, 14 ') for holding at least one functional component (28, 28'), in particular for holding sensors, which functional components (28, 28 ') in each case at least one functional surface ( 16, 16 ') comprises, which measuring tube (1) comprises a carrier tube (2), soft holding elements (14,

14 ') on at least one connecting surface (29, 29') with the support tube (2) are in communication and two opposing connecting surfaces (29, 29 ') of the holding elements (14, 14') a distance Y ₂ ^ - have and two each are opposed functional surfaces (16, 16 ') of the functional components (28, 28'), which are gehaitert in the holding elements (14, 14 '), a distance Xi6, iβ ^p , characterized in that geometries and in-house Sizes of the holding elements (14, 14 ') and / or geometries and material-own sizes of the functional components (28, 28') and geometries and material-own sizes of the support tube (2) are coordinated so that relative distances

X "ΛT) = ^X ' ⁶ ' ^{i6 of} the functional areas (16, 16 ') of the functional components

(28, 28 ^r ) in dependence on a temperature T of the measuring medium (4) flowing through the measuring tube (1), starting from an initial temperature T _{0 of} the measuring medium (4), so that temperature-dependent

Measuring deviations at a temperature change AT = TT _{0 of} the measuring medium (4), in particular due to temperature-induced changes in the geometries of the support tube (2) and / or due to temperature-dependent changes of material and / or flow properties of the medium (4) and / or due to temperature-induced changes of a signal path

(10), are smaller than the temperature-related measurement deviations at a temperature change AT-TT _{0 of} the medium (4), which are at relative Distances I ^■ *> 29,29, (V7)> = _v ^{Y2% i} A / π ^T n) N of the functional surfaces (16, 16 ') of the functional 1 29,29A - ¹ O -'

Component (28, 28 ') occur.

2. Measuring system according to claim 1, characterized in that geometries and material-own sizes of the holding elements (14, 14 ') and / or geometries and material-own sizes of the functional components (28, 28') and geometries and material-own sizes of the support tube (2) so are matched to each other, that relative distances X, 1,6, 16J VT) '- 2 ~ yB ^K. f5f-r1 \ the functional surfaces ( ^λ 16, 16 ^! ) 'of the functional components λlö, l6' ( ^l θ i

(28, 28 ') as a function of a temperature T of the measuring medium (4) flowing through the measuring tube (1), starting from an initial temperature T _{0 of} the measuring medium (4), so that temperature-related measuring deviations at a temperature change AT = TT ₀ of Measuring medium (4), in particular due to temperature-induced changes in the geometries of the support tube (2) and / or due to temperature-dependent changes of material and / or flow properties of the measuring medium (4) and / or due to temperature-induced changes of a signal path (10), are approximately zero.

3. Measuring system according to claims 1 and 2, characterized in that a relative change in the distance of

Functional surfaces (16) of the functional components (28) at a temperature change AT = T-To of the measuring medium (4), of a

Starting temperature T _{0 of} the measuring medium (4), is smaller than a relative change .DELTA.F _29I29 , (7> ^Y ^ ^{'(T) "Y} ^ ^{' (T} ° ^{) of} the distance of the

Connecting surfaces (29) of the support tube (2).

4. Measuring system according to claims 1 to 4, characterized,

~ X (T) X (T) that a relative change AZ _{16 i6} , (T) = ¹⁶ '- ¹⁶ ' ^{16 ϋ) of} the distance of the

Functional surfaces (16) of the functional components (28) at a temperature change AT = TT _{0 of} the measuring medium (4), starting from an output temperature To of the measuring medium (4), approximately

Is zero.

5. Measuring system according to claims 1 to 4, characterized in that the holding elements (14) have a tempering device, whereby a predetermined temperature of the Haiteelemente (14) and / or on the holding elements (14) attached functional components (28) can be adjusted ,