EP2553402A1

EP2553402A1 - Mass flow sensor and method for determining the mass flow in a pipe

Info

Publication number: EP2553402A1
Application number: EP11714215A
Authority: EP
Inventors: Holger Neumann; Rajini Kumar Ramalingam; Manfred SÜßER
Original assignee: Karlsruher Institut fuer Technologie KIT
Current assignee: Karlsruher Institut fuer Technologie KIT
Priority date: 2010-03-26
Filing date: 2011-03-17
Publication date: 2013-02-06
Also published as: WO2011116899A1; US8746079B2; US20130014594A1; DE102010012924B4; DE102010012924A1

Abstract

The invention relates to a sensor for determining the mass flow of a fluid (mass flow sensor), comprising a wall element (3) which is insertable in a cutout in a wall of a pipe (1), through which a mass flow (2) flows, wherein at least one gap (11) is formed between the wall element (3) and the wall of the pipe (1) and wherein at least one glass fibre is attached as an expandable connection (4) to the outer side, which is remote from the mass flow (2), of the wall element (3) in a chamber (9) which is closed off with respect to the environment, with the glass fibre being clamped between the wall element (3) and a wall of the chamber (9), wherein at least one fibre Bragg grating sensor (FBG sensor) is provided as the strain gauge (5) on that part of the expandable connection (4) that is clamped between the wall of the chamber (9) and the wall element (3). The invention also relates to a method for determining the mass flow (2) of a fluid in a pipe (1), wherein the fluid exerts a shear stress on a moveable wall element (3), the magnitude of which depends on the magnitude of the mass flow (4), as a result of which the length of an expandable connection (4), which is clamped between the outer side of the wall element (3) and a wall of the adjoining chamber (9), changes and the change in length of the expandable connection (4) is detected using a strain gauge (5) that is attached thereto, and from this the magnitude of the mass flow is ascertained. The mass flow sensor is not inserted into the mass flow so as to avoid a loss in pressure and is suitable for gases and liquids even at low temperatures and for use near strong electromagnetic fields. A prototype needs to be calibrated only once, and this calibration can subsequently be used for any sensor of identical construction.

Description

Mass flow sensor and method for determining the mass flow in a pipe

The invention relates to a sensor for determining the mass flow of a fluid (mass flow sensor), a pipe, which is equipped with such a mass flow sensor, and a method for determining the mass flow of a fluid in a pipe.

Conventional mass flow sensors for determining the mass flow of a fluid, i. a liquid or a gas, are based on the one hand on Wirkdruckverfahren, however, cause by the measurement of a permanent pressure loss in the flow, and on electronic methods that are significantly influenced in the environment of strong electromagnetic fields, which causes high measurement errors or one caused considerable calibration effort. Therefore, various mass flow sensors equipped with a fiber Bragg grating sensor (FBG sensor) capable of accurately determining the change in length of a glass fiber have been proposed.

JP 2005003535 A discloses an optical device for determining t ^' the direction or velocity of a flow, which is based on the fact that an element, to which a glass fiber with an FBG sensor is applied, is deformed by the hydraulic pressure. The disadvantage of this is that a significant hydraulic pressure is formed only in a liquid, so that the device is not suitable for the investigation of gas flows. Furthermore, this device requires a deformable element, which is a major disadvantage, especially at high temperature changes, in which the material properties of this element change significantly, and at low temperatures, since there barely deformable materials exist.

From EP 1936332 AI a flow meter is known in which a flow element is introduced into the flow to detect the Karman vortex via FBG sensors. The disadvantage of this is that

CONFIRMATION COPY The sensor is in the flow, resulting in a higher pressure loss compared to a smooth pipe or channel flow. Another disadvantage is that the sensor detects the flow characteristic Karman vortex by means of an FBG sensor, so that it can not be distinguished whether the change in length of the flow meter due to the change in flow resistance or only due to a change in temperature.

JP 2007017337 A describes a device for determining the flow velocity, which is based on the measurement of the dynamic pressure, which presses on a wall element, wherein the FBG sensor is located in an airtight chamber. A disadvantage of this is that the measuring arrangement must be flown, so that it is not suitable for the investigation of an internal flow and thus not readily as a mass flow sensor. Installation in a pipe would lead to a considerable pressure loss. Since the sensor is located in an airtight chamber, the temperature correction refers only to the temperature-dependent elongation of the glass fiber.

GB 2454613 A discloses a glass fiber with at least one FBG sensor which is introduced into the flow. To increase the signal strength, one or more flow-shaped elements, in particular spheres or ellipsoids, are firmly connected to the glass fiber. When using multiple elements to enhance the mechanical stress on the glass fiber, the device is a kind of string of pearls, which is introduced into the flow. The disadvantage of this is that the reinforced glass fiber must be introduced into the flow, whereby an additional pressure loss is formed. Compared to a liquid flow number or size of the flow-shaped elements must be increased in a gas flow, whereby the pressure loss further increases. A further disadvantage is that it can not be distinguished here as well whether the stretching of the glass fiber takes place due to the change of the flow resistance or a temperature change. US 6, 408, 698 Bl discloses an electronic sensor which is inserted into the wall and determines the resulting forces of the flow via stretchable connections by means of an electronic sensor. The disadvantage of this is that its signal changes due to electromagnetic fields, which requires a calibration of the sensor in the magnetic field in relation to the size and relative orientation of the sensor to the magnetic field. Each individual sensor must be calibrated for its particular application in order to take into account manufacturing tolerances. Especially when used under cryogenic temperatures with externally impressed magnetic fields this calibration effort is considerable.

In US 2009/0133505 Al a device is described in which the wall shear stress causes a deflection of a rod, which in turn compresses a microresonator. The wavelength change due to the mechanical loading of the microresonator is measured. Both the deflection of the rod and the mechanical load and thus the measurement signal depend on the temperature-dependent physical properties of the rod and the microresonator. A disadvantage here is that the mechanical stress of the rod is on the one hand temperature-dependent and, on the other hand, depends on the purity and structure of the material: impurities or inclusions as well as blowholes influence the ductility of the rod. The same applies mutatis mutandis to the microsensor, so that each mass flow sensor is unique, which must be calibrated temperature and load side. Furthermore, the inadequate reproducibility of the production of micro-resonators as well as the technically demanding coupling between microresonator and glass fiber result in each sensor being a unique specimen to be calibrated. Likewise, the size of the microresonator is crucial in terms of signal quality.

Finally, due to the deflection of the rod, not only does the mechanical loading of the microsensor become mechanical, but also a shift normal to the flow direction, which significantly affects the signal. Thus, a reversibility of the movement and a consideration in the context of a calibration are not necessary given way, which affects the permanent functionality of this sensor.

US Pat. No. 7,168,311 B2 and US Pat. No. 6,426,796 B1 each disclose a sensor which is introduced into a wall and which detects the resulting forces of the flow via a deflection by means of an optical sensor by means of interferometry. The disadvantage of this is that here, too, the mechanical stress of the rod to bend on the one tem depends on the body and on the other depends on the purity and structure of the material. The interferometric measurement is based on the fact that a beam is emitted to a plate and the reflected beam causes interference with the emitted beam, wherein the plate is connected to the bar bending due to the wall shear stress. Due to the deflection of the rod, the plate, which receives the Wandschubspan-voltage, does not move parallel to the flow direction, but is correspondingly transverse. An incident beam on the underside of this plate is then no longer normally reflected (180 °), but experiences an angle deviating from 180 °. This behavior can only be ignored in an extremely small angular range, which considerably limits the range of application of the device in flows. Furthermore, this type of construction of the device makes the highest demands in terms of manufacturing tolerances.

Based on this, it is the object of the present invention to provide a sensor for determining the mass flow of a fluid (mass flow sensor), a tube, which is equipped with such a mass flow sensor, and a method for determining the mass flow of a fluid in a pipe, the disadvantages mentioned and do not have limitations.

In particular, a mass flow sensor is to be provided which operates reliably in the environment of strong electromagnetic fields, is suitable both for gases and for liquids even at very low temperatures, in particular in cryotechnology, and not in The mass flow must be introduced in order to avoid a pressure drop in the flow.

Likewise, the purity or structure of the material selected for the ei ^¬ tual detection element in the mass flow sensor, play no role in order to allow that as only as possible a prototype must be calibrated and this calibration is then applicable for each identical sensor.

Furthermore, a pipe, a pipe section, a channel or a channel piece, which is equipped with such a mass flow sensor, be provided, which has means for flanging into a pipe or in a channel system.

Finally, a method for determining the mass flow of a fluid in a tube is provided, with which a change in length of a glass fiber can be clearly attributed to the change of a flow-mechanical property of the mass flow and length changes due to a temperature change of the mass flow or the environment can be excluded.

This object is achieved with respect to the mass flow sensor by the features of claim 1, with regard to the tube by the features of claim 4 and with respect to the method for determining the mass flow through the steps of claim 7. The subclaims each describe advantageous embodiments of the invention.

A sensor according to the invention for determining the mass flow of a fluid (mass flow sensor) contains a movable wall element which can be inserted (integrated) into a section of a wall of a pipe or channel through which a mass flow flows. The mobility of the wall element is given by the fact that one or more gaps are present between the wall element and the wall of the tube into which the wall element is inserted or integrated. At the outside of the movable wall element facing away from the mass flow, at least one expandable connection is provided in a chamber closed off from the surroundings. A joint is said to be stretchable if a shear stress applied thereto produces a measurable strain. For practical use, however, the material used for this purpose may neither embrittle nor tear. As a result of this condition, for example, rubber is not suitable for use at cryogenic temperatures.

The at least one expandable connection is in each case attached both to the wall element and to a wall of the chamber and in each case clamped between the two attachment points. Preferably, each of the at least one stretchable connection is fixed to a wall of the chamber by means of a first tensioning device and to the movable wall element by means of a second tensioning device and clamped between the wall element and the wall of the chamber by means of a slight bias. The at least one strain gauge is in each case mounted on that part of the at least one expandable connection which is clamped between the wall of the chamber and that of the movable wall element.

In a particular embodiment, a plurality of expandable connections are provided, which are each provided with at least one strain gauge are each attached to a separate first clamping device on a wall of the chamber. In this way, the sensor works regardless of the direction of the mass flow.

At each of the at least one expandable connection, at least one strain gauge is applied or applied to that part of the expansible connection which is clamped between the wall of the chamber and the wall element.

In a preferred embodiment, at least one temperature sensor is provided which is attached to a portion of the expansible connection which does not exist between the wall of the chamber and the transducer element. ment is clamped. Since this further portion of the expandable joint remains independent of a change in length which causes the shear stress of the fluid in the flow in the portion of the glass fiber clamped between the wall of the chamber and the wall member, it remains possible for at least one further strain gauge to be at least provide a temperature sensor and in this way to determine the temperature in the sealed chamber over the change in length of this portion of the expandable connection.

According to the invention, at least one glass fiber is used as a stretchable connection, at least one fiber Bragg grating sensor (FBG sensor) is provided as a strain gauge and applied or applied to the at least one glass fiber. In a particularly preferred embodiment, at least one further FBG sensor is mounted as a temperature sensor on the portion of the glass fiber which is not clamped between the wall of the chamber and the wall element. Fiber Bragg gratings are optical interference filters inscribed in an optical waveguide so that wavelengths that are within a filter bandwidth are reflected. Thus, these grids are suitable as sensors for both strain and temperature, each based on a change in the reflected wavelength.

In addition to the one or more gaps present between the wall element and the wall of the pipe into which the wall element is inserted or integrated, in a particular embodiment the pipe contains one or more openings (bores) connecting the inside of the pipe to the chamber , Through this at least one gap and / or the at least one opening, a part of the mass flow from the tube enters the chamber, whereby the same temperature prevails in the chamber as in the mass flow. In this way, the accuracy of the temperature measurement is significantly increased.

The invention further relates to a tube, which is understood as a piece of pipe, a channel or a channel piece, which with a provided mass flow sensor according to the invention.

In a preferred embodiment, the tube has means for flanging into a pipe or channel system.

In a particular embodiment, the tube has one or more openings (holes) that connect the inside of the tube with the chamber. As a result, a part of the mass flow enter the chamber, so that in the chamber the same temperature as in the mass flow prevails, whereby the accuracy of the temperature measurement increases significantly.

Finally, the invention relates to a method for determining the mass flow in a pipe. For this purpose, the tube is flowed through by a mass flow of a fluid which exerts a shear stress on the movable wall element. The strength of this shear stress is preferably proportional to the size of the mass flow. The shear stress calls for a change in the length of the one or more stretchable joints, i. the one or more glass fibers, which are clamped between the outside of the wall element facing away from the mass flow and a wall of the chamber. The change in length of the stretchable connections is in each case detected by means of at least one FBG sensor, which is attached to or applied to the respective expandable connection. After a previous calibration, the size of the mass flow can be determined from this.

In a preferred embodiment, a preferably very small portion of the mass flow is introduced through the at least one gap between the wall member and the wall of the pipe and, if present, through at least one additional opening in the pipe into the chamber. This ensures that the same temperature prevails in the chamber as in the mass flow, so that the temperature of the mass flow can be determined via a temperature sensor. For this purpose, preference is given to the change in length of a further section of at least one glass fiber, which does not exist between a wall of the chamber and the wall element is clamped, by means of a mounted thereon strain gauge in the form of an FBG sensor determined. In this way, a proportion of the change in length of the one or more expandable compounds, ie glass fibers, which is due to a change in temperature and not on the effect of the shear stress, calculate out.

The invention has in particular the advantages mentioned below.

The mass flow sensor according to the invention is independent of the magnitude of the hydraulic pressure and therefore enables the determination of the mass flow in both liquid and in gas flows.

In the mass flow sensor according to the invention there is no additional pressure loss compared to a pipe or channel flow, since the movable wall element which receives the shear stress of the flow is inserted into the wall of the pipe or pipe section. The mass flow sensor according to the invention avoids pressure loss by avoiding any internals that could lead to additional pressure loss compared to a smooth pipe or channel flow. Rather, the movable wall element of the disclosure is merely moved by the wall shear stress, which occurs anyway in the pipe or channel. So here is not the back pressure, but the wall shear stress is the actual input for the determination of the size of the mass flow.

In a preferred embodiment, the mass flow sensor according to the invention provides information as to whether the length of glass fiber has actually changed as a result of the change in the flow resistance of the mass flow to be investigated and not also due to a temperature change. This information is provided by determining only the temperature with another FBG sensor. On the one hand, this also measures the absolute temperature of the flow of the mass flow and, secondly, the change in length due to the influence of temperature is clearly detected here, as a result of which the measurement results are obtained. are much more accurate.

In the mass flow sensor according to the invention, in a preferred embodiment, the strain gauges are exposed directly to the flow temperature via gaps and / or openings, so that not only a correction of the temperature-dependent elongation of the glass fiber takes place, but also a correct measurement of the absolute temperature. The measurement of the absolute temperature is necessary for the determination of the density of the fluid, which is needed to determine the size of the mass flow.

Finally, the mass flow sensor according to the invention is independent of the properties of the materials used for this purpose.

The invention is explained in more detail below with reference to an embodiment and the figure.

The figure shows a section of a pipe 1 which is separated from a mass flow 2 from a fluid, i. a gas or a liquid is flowed through. In a part of the wall of the tube 1 is a movable wall element 3, which has an inside facing the mass flow 2 and an outside facing away from the mass flow 2. On the outside of the movable wall element 3 is in a closed to the environment chamber 9, a glass fiber as a stretchable connection 4, which has both a first fiber Bragg grating as a strain gauge 5 and a second fiber Bragg grating as a temperature sensor 6 attached , The glass fiber as a stretchable connection 4

itself is fastened with slight prestressing by means of a first tensioning device 7 on a wall of the chamber 9 and by means of a second tensioning device 8 on the movable wall element 3. The first fiber Bragg grating as a strain gauge 5 is mounted on that part of the glass fiber as a stretchable connection 4, which is located between the first tensioning device 7 and the second tensioning device 8; while the second fiber Bragg grating is used as the temperature sensor 6 is mounted on a non-clamped portion of the glass fiber as a stretchable connection 4.

A small part of the mass flow 2 penetrates through the gap 11 between the movable wall element 3 and the remaining wall of the tube 1 and possibly also through additional holes 10 in the tube 1 in the sealed against the environment chamber 9, so that there the same temperature as prevails in the mass flow 2, which can be determined by a change in length of the corresponding portion of the glass fiber as a flexible connection 4 by means of the second fiber Bragg grating, which serves as a temperature sensor 6, the temperature of the mass flow 2.

The first fiber Bragg grating as a strain gauge 5 undergoes a change in length (contraction or dilation) due to the temperature change, which depends on the temperature of the mass flow 2 and / or due to the tensile force exerted by the wall element 3 on the glass fiber as a stretchable connection 4. The tensile force is created by the shear stress (wall friction), which exerts the fluid of the mass flow 2 on the movable wall element 3. The shear stress that the fluid exerts on the wall here depends proportionally on the mass flow 2. The magnitude of the change in length of the first fiber Bragg grating as a strain gauge 5 due to the thermal contraction or thermal dilation can be determined by the value of the temperature, which was determined with the fiber Bragg grating, which serves as a temperature sensor 6, so that finally the traction and thus the height of the

Shear stress the size of the mass flow can be determined uniquely.

The mass flow sensor according to the invention was constructed and installed by means of flanges in a tube. From a compressed gas cylinder, a nitrogen flow was generated. The mass flow change produced in this way caused a change in the wavelength of the light backscattered on the fiber Bragg grating. An assignment of measured wavelength change to determining mass flow is based on a still too successful calibration. If the fluid, temperature and pressure are known, the viscosity can simply be determined by a substance database for a person skilled in the art, so that the calibration must be carried out only once later. With known bias of the fiber, a sensor can later resort to this known calibration and does not need to be recalibrated.

Claims

claims

1. A sensor for determining the mass flow of a fluid (mass flow sensor), comprising a in a section of a wall of a pipe (1) by a mass flow (2) can be flowed through, insertable wall element (3), between the wall and the pipe (1) at least one gap (11) remains and at the mass flow (2) facing away from the outside in a sealed chamber to the environment (9) at least one expandable connection (4) is mounted between the wall element (3) and a wall the chamber (9) is clamped, wherein on the part of the expansible connection (4), which is clamped between the wall of the chamber (9) and the wall element (3), at least one strain gauge (5) is provided, characterized in that at least one glass fiber as the at least one expandable connection (4) and at least one fiber Bragg grating sensor (FBG sensor) are provided as the at least one strain gauge (5).

2. mass flow sensor according to claim 1, characterized in that at least one further FBG sensor as at least one temperature sensor (6), on another part of the expandable connection (4), not between the wall of the chamber (9) and the wall element (3) is provided for.

3. Mass flow sensor according to claim 1 or 2, characterized in that a plurality of expandable connections (4) are provided, each provided with at least one strain gauge (5) and each at its own first clamping device (7) on a wall of the chamber (9). are attached.

4. tube (1) which is equipped with a mass flow sensor according to one of claims 1 to 3.

5. tube (1) according to claim 4, which has at least one additional opening (10) which connects the inside of the tube (1) with the chamber (9).

6. tube (1) according to claim 4 or 5, comprising means for flanging into a pipe system.

Method for determining the mass flow of a fluid in a pipe (1), said pipe (1) being dependent on a mass flow (2) of a fluid acting on a movable wall element (3) between and the wall of the pipe (1). at least one gap (11) remains, exerts a shear stress whose strength depends on the size of the mass flow

(2) depends, whereby the length of at least one glass fiber as at least one expandable connection (4) between the mass flow (2) facing away from the outside of the wall element (3) and a wall of the wall element adjacent to the environment Completed chamber (9) is clamped, changes and the change in length of the at least one expandable connection (4) by means of at least one fiber Bragg grating sensor (FBG sensor) as at least one strain gauge (5) on the at least one expandable connection (4) is shown, from which the size of the mass flow is determined.

8. The method of claim 7, wherein a part of the mass flow (2) through the at least one gap (11) between the wall element

(3) and the wall of the tube (1) and, if present, through at least one additional opening (10) in the tube (1) into the chamber (9) closed to the environment, whereby the same temperature prevails in the chamber (9) as in the mass flow (2)

prevails, so that by means of a further FBG sensor as a temperature sensor (6), which is not clamped between a wall of the chamber (9) and the wall element (3) on another part of the at least one expandable connection (4) is mounted, the temperature of the mass flow (2) is determined, whereby a portion of the change in length of the expandable connection (4), which is due to a change in temperature, is excluded.