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    • 专利摘要:
    A fluid measuring means (10) comprises a housing (12) in which are formed a flow channel for a fluid to be measured and at least one elongated module housing port (24) which forms a passage from one side. outside (23) of the housing (12) up to the flow channel. The module housing port (24) is oriented along the flow channel. At least one fluid measurement module (28) is provided which is prefabricated separately from the housing (12) and which has a bottom section (30) made as a waveguide (34) for surface acoustic waves. , and at least one signal transducer (40) arranged to excite surface acoustic waves in the waveguide (34) and / or to receive surface acoustic waves from the waveguide (34). The fluid measurement module (28) is inserted into the module housing port (24) such that the bottom section (30) of the fluid measurement module (28) forms a section of an interior wall of the flow channel which comes into direct contact with the fluid flowing through it so that surface acoustic waves emitted by the signal transducer (40) are able to be decoupled by the waveguide ( 34) and propagate through the fluid in the flow channel as acoustic volume waves and / or so that acoustic volume waves are able to be coupled into the waveguide (34) and to be received by the signal transducer (40). Figure 1
    公开号:FR3081998A1
    申请号:FR1905184
    申请日:2019-05-17
    公开日:2019-12-06
    发明作者:Yannick Fuchs;Bertrand Koenig;Noam NANCY;Manon DRUI
    申请人:Buerkert Werke GmbH and Co KG;Burkert S A S;
    IPC主号:
    专利说明:

    Description
    Title of the invention: Fluid measurement means and fluid measurement module for a fluid measurement means and assembly [0001] The invention relates to a fluid measurement means and a fluid measurement module for a fluid measurement means, as well as an assembly comprising a housing of a fluid measurement means and a fluid measurement module.
    In a large number of installations, it is necessary to determine a flow rate of a fluid. It is often also advantageous to be able to determine other properties of the fluid flowing through the installation. For this purpose, means for measuring fluid, therefore devices by means of which it is possible to measure a flow or other properties of the fluid which flows, are inserted in one of the fluid lines of the 'installation.
    The fluid measurement means used must be made as compact and robust as possible and therefore require little mounting space and largely little maintenance. It is also advantageous when the fluid measuring means is able to be applied as universally as possible and when it is in particular possible to use different fluids or to determine different properties.
    A measurement method which is well suited to a problem of this type is the use of surface acoustic waves which are excited in an acoustic waveguide and which are partly decoupled in the fluid and are again coupled out of it and into the waveguide. The fluid for this measurement method is in direct contact with the waveguide. The type and frequency of the surface waves are chosen so that a partial decoupling in the fluid in the form of longitudinal sound volume waves is carried out. The sound waves pass through the fluid and are reflected on a side delimiting the fluid so as to touch the waveguide again. A part of the sound volume waves is again coupled in the same or in another waveguide in the form of surface acoustic waves and continues to pass through it. Thus, this results in a level of an acoustic receiver which is arranged on a waveguide remote from the transmitter, a characteristic signal whose appearance of the intensity over time including the delay over time by in relation to the signal emitted by the transmitter makes it possible to draw conclusions concerning characteristic properties of the fluid, such as the speed of sound, the temperature, the homogeneity, the flow speed, the flow rate, the flow volume, the density, composition of a multiphase flow, concentration or viscosity.
    This measurement method is particularly suitable for liquid or also very viscous, pasty, gel-like or thick fluids, of the homogeneous or inhomogeneous type, including [0006] [0007] [0008] [0009] [0010] Including biological samples. The use for gaseous fluids would also be conceivable, it would be necessary in this case to take into account the speeds of sound which differ clearly from those of liquids. When the fluid flows through the measuring means, it is also possible to detect changes in the fluid over time.
    The propagation in space of the sound volume waves in the fluid is for example obtained by the decoupling of the sound volume waves in the fluid at an angle ô with respect to a surface normal of the waveguide. The relationship can be described by the following formula: δ = arcsin ^^ M c M being the speed of sound of sound volume waves in the fluid, and c s being the speed of sound of surface acoustic waves propagating along the waveguide.
    In the most frequently occurring case, in which the speed of sound in the fluid is lower than that of the surface waves in the waveguide, sound waves are decoupled at an angle other than zero, and sound volume waves travel a distance in space along the waveguide, possibly with multiple reflections in the fluid.
    In known devices, the transmitter and the receiver are mounted on one side of the respective waveguide which is opposite to the interface with the fluid. In order to be able to couple sound surface waves excited on this side of the waveguide in the fluid, Lamb waves are thus preferably excited, therefore waves whose wavelength is considerably greater than the thickness of the waveguide. waves between the emitter and the fluid. In this case, both the upper face and the lower face of the waveguide move, the oscillation also having a longitudinal component. This type of excitation is thus adapted to the decoupling of sound volume waves. It is also possible to choose the wavelength of the surface acoustic waves excited in the order of magnitude of the thickness of the waveguide, surface waves then being excited in a transition zone between the Lamb waves. and Rayleigh waves.
    The devices described hitherto in the state of the art which operate according to the principle described above have a complex structure and an expensive manufacture and maintenance.
    The aim of the invention is to create a means of measuring compact and robust fluid which can be used flexibly, which is based on the principle of surface acoustic waves.
    This object is achieved by a fluid measurement means according to the invention. The fluid measuring means comprises a housing in which a flow channel for a fluid to be measured is produced and at least one elongated module housing orifice, the module housing orifice forming a passage on an external face of the housing up to the flow channel. The module housing hole is oriented along the flow channel. The fluid measurement means further comprises at least one fluid measurement module which is prefabricated separately from the housing and which has a bottom section made in the form of a waveguide for surface acoustic waves, and at least one transducer of signals arranged to excite surface acoustic waves in the waveguide and / or to receive surface acoustic waves from the waveguide. The fluid measuring module is inserted into the module housing opening so that the bottom section of the fluid measuring module forms a section of an inner wall of the flow channel which comes into direct contact with the fluid flowing through it, so that surface acoustic waves emitted by the signal transducer are capable of being decoupled by the waveguide and propagating through the fluid in the flow channel under acoustic volume waves and / or so that acoustic volume waves are capable of being coupled into the waveguide and of being received by the signal transducer.
    Due to the modular structure, the fluid measurement module can be manufactured separately from the rest of the fluid measurement means and can simply be inserted from the outside into the module housing orifice of the already finished housing under form of fully prefabricated component. This simplifies manufacture and also allows a simple exchange of the fluid measurement module, whereby it is possible to extend the service life of the fluid measurement means.
    The waveguide can close a vacuum in the wall of the flow channel present in the housing. It is therefore not necessary to form the entire flow channel by the waveguide of a single fluid measurement module.
    In addition, apart from the waveguide, all the housing components of the fluid measurement means are advantageously provided in the housing of the latter, so that the fluid measurement module can be reduced to the components essentials necessary for measurement using the fluid measurement module. The fluid measurement module is thus also advantageously arranged so that it can be used only together with the housing of the fluid measurement means and does not form an independent measurement device.
    The inner wall of the flow channel, including the section formed by the waveguide, can be made continuously planar and entirely of a material resistant to corrosion with respect to the fluid to be measured. The waveguide is preferably always made of the same material as the rest of the wall of the flow channel. This results in a uniform surface, even when the waveguide is not a piece of material from the housing of the fluid measuring means.
    The fluid measurement module must of course be sealed relative to the fluid along the periphery of the module housing so that no fluid can unintentionally drain out of the flow channel in the area of the fluid measurement module.
    At the upstream end and at the downstream end, the housing can respectively have a fixing structure, for example a flange, as known from other means for measuring fluid and through which the means fluid measurement device can be connected to an adjacent section of a fluid line. It is thus possible to integrate the fluid measurement means quickly and easily into an existing installation.
    The flow channel preferably extends in a direction of flow of the fluid in a rectilinear manner and in particular forms in the region of the waveguide a rectilinear measurement path to allow a measurement as precise as possible.
    The flow channel is made so as to be closed in the peripheral direction around the direction of flow. Generally, it is expected that the fluid flows in an installation along a predetermined path from a fluid inlet to a fluid outlet through the fluid measuring means, without zones of the fluid measuring means do not conduct fluid come into contact with the fluid.
    From the manufacturing point of view, it is advantageous to produce the bottom section of the fluid measurement module in a planar manner on its outer face which faces the flow channel and which forms the interface with the fluid.
    The shape of the cross section of the flow channel (seen in a plane perpendicular to the direction of flow) in the area of the module housing orifice can be chosen at will, a polygonal cross section, in particular rectangular, square, hexagonal or octagonal being preferred however. This makes it possible to produce the waveguide in the form of a flat face on its outer face facing the flow channel, which forms one of the faces of the polygon of the cross section of the flow channel.
    It would also be conceivable to produce the external face of the waveguide which is turned towards the flow channel with a constant curvature, steep steps should however be avoided.
    The flow channel is normally delimited by a fluid inlet and by a fluid outlet which can be connected to the fixing structures on the housing. Elements are preferably provided to influence the flow speed along the direction of flow at the fluid inlet and / or at the fluid outlet. It is for example possible to arrange a nozzle at the fluid inlet and / or a diffuser at the fluid outlet, when the flow channel has a cross section smaller than that of the fluid inlet or outlet fluid, respectively, in order to increase the flow velocity when entering the flow channel or to reduce it again when exiting the flow channel. An increase in flow velocity is accompanied by an increase in measurement accuracy at low flow rates.
    The fluid measuring means is preferably made so as to allow the passage of the fluid in the direction of flow both from the fluid inlet to the fluid outlet and in the opposite direction, so so that the fluid inlet and fluid outlet can exchange their function.
    The module housing orifice, perpendicular to the direction of flow, can be slightly wider than the fluid channel so that a shoulder is formed at the transition between the fluid channel and the module housing orifice. , on which an edge of the bottom section can rest and which can be used for the arrangement of a seal between the fluid measurement module and the flow channel.
    In a preferred embodiment, there is provided in the housing at least one additional module housing orifice which is preferably made on one side of the flow channel which is opposite to the first module housing orifice.
    It is in particular possible to insert a second fluid measurement module in the additional module housing orifice, the position of the signal transducer in the two fluid measurement modules along the direction of flow of the flow channel being advantageously different. In this case, each of the fluid measurement modules must have a single signal transducer, one of the signal transducers functioning as a transmitter, the other as a receiver. The functions are preferably performed alternately, the transmitter and the receiver exchanging their role according to a determined scheme.
    It is however in principle possible to provide any suitable number of signal transducers in each of the fluid measurement modules.
    A reflector, for example in the form of a waveguide on which no signal transducer is arranged, could also be placed in the additional module housing orifice.
    In another variant, another measurement module, in particular an analysis module for entering other measured variables, can be housed in the additional module housing opening. The analysis module, like the fluid module, is preferably a separately prefabricated component which should only be inserted into the module housing orifice from the outside and fixed there for mounting on the fluid measuring means . The analysis module closes the respective module housing opening in a fluid-tight manner.
    The analysis module can for example be arranged so as to measure an electrical conductivity, a pH value, a concentration of a chemical substance such as chlorine, the turbidity of the fluid, a redox potential of the fluid, a temperature and / or any pressure or other quantity in particular in relation to the fluid.
    The measurement data obtained by means of the analysis module generally supplement the data obtained by the fluid module, the analysis module being most often arranged so as to determine quantities which are not or difficultly accessible by measuring evaluation by means of surface acoustic waves.
    It is in principle possible to provide on all sides of the housing (relative to the section perpendicular to the direction of flow) of the module housing orifices in which it is possible to insert one or more measurement modules of fluid and / or one or more analysis modules, if necessary designed for different measurement quantities, depending on the requirements concerning the fluid measurement means. Module openings which are not used may be covered by reflectors.
    The housing can advantageously be made in one piece to avoid additional mounting efforts and obtain high precision. Thus, the housing can be designed as an integral body of a suitable material which has the flow channel, the fluid inlet, the fluid outlet, the module housing orifices and, where appropriate, other pipes. fluid and / or other geometric structures. All the electronic components of the fluid measuring means as well as the waveguides can be provided on the fluid modules inserted in the module orifices or possibly on other components which are prefabricated separately and inserted in the housing. This allows a modular structure in which fluid modules and individual analysis modules on the housing are accessible from the outside and can be replaced non-destructively.
    A recess may be provided in the housing, which has a cable passage to the module housing orifice and through which the electrical and / or electronic connection cables of the respective fluid measurement module are guided to provide an interface for the fluid measurement module which is capable of being contacted from outside the fluid measurement means.
    In a preferred embodiment, there is provided a valve through which a flow of fluid through the flow channel is capable of being adjusted, the housing having channels for guiding fluid between the channel flow and the valve, and between the valve and the fluid inlet or the fluid outlet. In this way, the valve (made separately from the housing and the fluid measurement module) must simply be placed on the housing and can also be replaced, if necessary. Fluid connections can be fully provided in the housing. The flow channel and the fluid line can be made in a solid section made of material from the housing. The housing can of course be adapted to the requirements of the installation in which the fluid measuring means is to be inserted.
    The fluid measurement means preferably forms together with the valve and an electronic control and evaluation as well as all the fluid and / or analysis modules possibly provided a single component which can be mounted in an installation. by means of the fixing structures at the fluid inlet and at the fluid outlet.
    It is also possible to use the fluid measurement means for the flow control taking into account the measured values determined by the fluid and / or analysis modules. The control signals for the valve can be provided by a control integrated in the fluid measurement means or external.
    The fluid measurement means preferably has an electronic interface for the exchange of data with external systems or for connection to a network. The interface also allows a current supply of the whole of the fluid measurement means and of all the fluid measurement modules and / or of all the analysis modules which are mounted thereon. This interface can be a separately prefabricated component which is inserted from the outside into a housing made on the housing.
    The object cited above is also obtained with a fluid measurement module according to the invention. The fluid measurement module is in particular a fluid measurement module of a fluid measurement means as described above. The fluid measurement module comprises a module housing which has a bottom section made in the form of a waveguide for surface acoustic waves, and at least one signal transducer which is directly connected to the bottom section and which is arranged to excite surface acoustic waves in the waveguide and / or to receive surface acoustic waves from the waveguide. The waveguide is made so as to be brought into planar contact with a fluid on an external face diverted from an interior space of the module housing. The fluid measurement module is designed so that it is not used alone and independently, but always together with a housing of the fluid measurement means as described above. In particular, the bottom section of the fluid measurement module does not form a complete flow channel and achieves, after insertion into the housing of the flow measurement means, that a section of the flow channel of the flow means fluid measurement.
    The fluid measurement module can be produced in the form of an independent unit, that is to say that all the measurement devices necessary for a measurement, such as the signal transducers and the waveguides and , if necessary, other components such as a temperature sensor, can be integrated into the fluid measurement module, so that preferably, the fluid measurement module does not require measurement devices arranged on the fluid measurement means separate from the fluid measurement module for the measurements that it must perform. The fluid measurement means can thus be flexibly fitted with specific fluid measurement modules. An exchange of a defective fluid module in the fluid measurement means for example is also conceivable. The fluid measurement module itself is in no case traversed by the fluid but is only brought into contact with the fluid on the outer face of the waveguide, so that the outer face of the waveguide forms an interface with respect to the fluid and a section of the interior wall of the flow channel. The rest of the areas of the fluid measurement module have no contact with the fluid.
    In the case where a single signal transducer is provided in the fluid measurement module, two fluid measurement modules cooperating with each other are advantageously used on a fluid measurement means. When two signal transducers are provided in a fluid measurement module, the measurement can also be carried out with a single fluid measurement module.
    The signal transducer (s) are preferably produced in the form of piezoelectric transducers, for example interdigitated transducers, and are in particular directly bonded to the waveguide. By applying an alternating voltage to the signal transducer, it is possible to generate surface waves in the waveguide.
    The module housing has for example a cup-shaped housing part which is formed by the bottom section and a peripheral side wall, said at least one signal transducer being arranged inside the housing part bowl-shaped. Such a housing part is simple to produce in a precise manner so that reliable sealing of the module housing orifice in the housing of the fluid measuring means is provided by the bottom section of the module housing. The cup-shaped housing part is preferably made as a component made of a material so that the bottom section merges uninterruptedly into the side wall.
    The side wall is advantageously made with such a height that all of the electronic components of the fluid measurement module can be arranged in the interior space enclosed by the side wall.
    It is possible that the module housing is only composed of the bowl-shaped housing part.
    The module housing must be extended in the direction of the waveguide, which corresponds to the direction of flow through the flow channel and to the longitudinal direction of the module housing orifice in the assembled state. in the fluid measuring means.
    The signal transducer is advantageously arranged at one end of the waveguide. To keep the dimensions of the module housing small, it is favorable that the end of the waveguide also corresponds to the end of the bottom section. If two signal transducers are provided, these should be arranged at the two opposite ends of the waveguide.
    The signal transducer can occupy the entire width of the interior space of the module housing perpendicular to the longitudinal extension of the waveguide, but can in particular extend at least over the entire width of the channel. flow. This allows ultrasound to pass through the fluid over the entire width of the flow channel. The fluid measuring means is thus relatively insensitive to an irregular distribution of the speed of the flow in the flow channel.
    Both the bottom section and the side wall must have such a thickness of material that the module housing is rigid in itself and unwanted deformations of the module housing are excluded.
    The signal transducer can be covered with an attenuation element which limits the propagation of acoustic waves on the waveguide directly below the signal transducer.
    A low attenuation zone which extends over a length of at least between one and twenty times, preferably between five and ten times the wavelength of the surface waves is preferably provided above the guide d waves adjacent to the signal transducer. This area extends along the direction of propagation of the surface waves in the waveguide. This low attenuation zone can for example be an air gap directly above the waveguide. In this zone, the waveguide must not be able to abut against another component when a surface wave passes through it in order to guarantee an undisturbed propagation of the surface waves in the waveguide.
    It is possible to arrange inside the module housing a temperature sensor which is in particular mounted directly on the waveguide so that in addition to the properties capable of being captured by measurement by surface acoustic waves, the temperature in the fluid measurement module is also known, which also represents a variable for the temperature of the fluid passing through it. Many of the measured variables are a function of temperature, so that the measurement accuracy can be increased when the temperature inside the fluid measuring means is known.
    The waveguide may have, in a first zone which is directly adjacent to the signal transducer and which, if necessary, may also extend directly below the signal transducer, a wall thickness that is less than in a second area further away from the signal transducer. The second zone with the greater wall thickness preferably forms a boss approximately in the middle of the waveguide. If two signal transducers are provided, the second area with the highest wall thickness is preferably in the middle between the two signal transducers. To each signal transducer must be connected a first zone having a smaller wall thickness in the direction of the second zone which has a greater wall thickness, which are preferably made with the same length.
    It turned out that the return of energy to the waveguide is fundamentally influenced by the choice of its wall thickness. In order that less energy is returned to the waveguide at a volume wave reflection point, the greater wall thickness present at the reflection point is chosen to be different from the smaller wall thickness which is optimal for coupling or decoupling in the area of the signal transducer. It is thus possible to improve the desired reflection at the point (s) of reflection, since the coupling of sound waves in the waveguide is made more difficult there or is even in the best of cases entirely stop. In the case of a good signal intensity, it is thus possible to achieve a considerably longer path of the volume waves through the fluid and therefore an enlarged measurement range, which is particularly advantageous for the measurement of low flow rates. fluid.
    The first zone having a smaller wall thickness is preferably located below the signal transducer and the low attenuation zone which is adjacent thereto.
    The smaller wall thickness is preferably between 40 and 60% and preferably corresponds to 50%, but at most 100% of the wavelength of the surface acoustic wave used for the measurement . With this optimal wall thickness, the surface waves are particularly well coupled by the transmitter in the wall, from which they continue to propagate in the fluid.
    In a preferred embodiment, the higher wall thickness is 20% to 95%, in particular 50% greater than the lower wall thickness. It is thus possible, by a greater wall thickness, to prevent the coupling of surface waves in the waveguide and thus to improve the reflection at the reflection points. The wall thicknesses with the two distances considered are preferably each constant.
    If more than two signal transducers are used in a fluid measurement module, two signal transducers are advantageously arranged on a common area having a smaller wall thickness.
    For protection against environmental influences, the module housing is preferably at least partially filled with a casting mass covering the waveguide and the signal transducer (s). When a low attenuation zone is provided above the waveguide, this is of course kept free of pouring mass by appropriate measures. The pouring mass can, for example, at least for the most part fill the cup-shaped housing part.
    Alternatively, it is also possible to provide a cover which closes the bowl-shaped housing part.
    Materials with a high speed of sound, preferably> 1800 m / s, are advantageous as a material both for the housing of the fluid measurement means and for the module housing of the fluid measurement module. Metals such as stainless steel, brass or copper, but also high-strength plastics have this property, for example.
    The fluid measurement module can include evaluation and / or control electronics within the module housing. While all the components necessary for the measurement per se are preferably arranged in the measurement module itself, evaluation and control can however also be at least partially carried out by external electronic units or by a control of the means of fluid measurement. The fluid measurement module must in any case have an electrical interface which allows a voltage supply and a data exchange.
    The fluid measurement means is advantageously designed in a modular manner. To this end, the fluid measurement means may comprise an assembly comprising a housing and at least one fluid measurement module separate from the housing, the fluid measurement module (s) in the assembly being optionally supplemented by one or more modules and / or one or more reflectors. The housing is a housing of a fluid measurement means as described above, while the fluid measurement module corresponds to one of the fluid measurement modules described above. The fluid measurement module can be inserted into the module housing orifice so that the bottom section of the fluid measurement module forms a section of an inner wall of the flow channel which comes into direct contact with the fluid flowing through it, so that surface acoustic waves emitted by the signal transducer can be decoupled from the waveguide and propagate as volume acoustic waves through the fluid in the flow channel and / or volume acoustic waves can be coupled into the waveguide and be received by the signal transducer.
    Several different aspects can be achieved with a fluid measurement means as described above.
    A simple flow measurement is for example possible via one or more fluid measurement modules inserted in the module housing orifices of the housing, which capture the fluid flow by a method of measurement using surface acoustic waves.
    However, it is also possible to enter other properties of the fluid using analysis modules provided in addition to the fluid measurement module (s), which are inserted into additional module housing orifices of the housing. .
    In another aspect, the fluid measurement means offers the possibility of combining a flow measurement and, if necessary, a measurement of other properties of the fluid with a flow control, by providing a valve in the means fluid measurement. The fluid measurement means can in particular thus implement a mass flow control by means of the measured values, in particular if a corresponding control is integrated in the fluid measurement means.
    The invention is described in more detail in the following by means of an exemplary embodiment with reference to the accompanying figures. In the drawings:
    [Fig. 1] shows a schematic perspective representation of a fluid measuring means according to the invention in a first embodiment having a fluid measuring module according to the invention;
    [Fig.2] shows a schematic sectional view of the fluid measuring means of Figure 1 in a direction of flow;
    [Fig.3] shows a housing of the fluid measuring means of Figure 1 in the view of Figure 2 without fluid measurement modules inserted;
    [Fig.4] shows a schematic sectional view of the fluid measuring means of Figure 1 along the direction of flow and perpendicular to the direction of the section of Figure 2;
    [Fig.5] shows a schematic perspective representation of a fluid measurement module according to the invention;
    [Fig.6] shows the fluid measurement module of Figure 5 after the insertion of an attenuation element;
    [Fig.7] shows a schematic sectional view of the fluid measurement module of Figure 6 according to the direction of flow;
    [Fig.8] shows a schematic perspective representation of a fluid measuring means according to the invention in a second embodiment having an attached valve;
    [Fig.9] shows a schematic sectional view through the fluid measuring means of Figure 8 in a direction of flow;
    [Fig. 10] shows a schematic sectional view of the fluid measuring means of Figure 8 perpendicular to the direction of flow;
    [Fig.l 1] shows a schematic perspective representation of a fluid measuring means according to the invention in a third embodiment;
    [Fig. 12] shows a schematic sectional view of the fluid measuring means of Figure 11;
    [Fig. 13] shows a schematic representation of an analysis module for a means of measuring fluid in FIG. 11;
    [Fig. 14] shows a perspective sectional view of a housing of the fluid measuring means of FIG. 11 perpendicular to the direction of flow, and [fig. 15], [fig. 16] and [Fig. 17] show different cross-sectional shapes of the flow channel of a fluid measuring means according to the invention.
    Figures 1 to 4 show a fluid measuring means 10 according to a first embodiment.
    In an elongated housing 12 is made a flow channel 14 for a fluid which melts in a fluid inlet 16 at one end of the housing 12 and in a fluid outlet 18 at the other end of the housing 12. The flow channel 14 forms, between the fluid inlet 16 and the fluid outlet 18, a completely closed tube in the peripheral direction around a flow direction D. The flow channel 14 here forms a measuring section with rectilinear extension in the direction of flow D, the cross-sectional area of the flow channel 14 being constant over its length.
    The cross-sectional area of the flow channel 14 is in this example, however, less than the cross-sectional area of the fluid inlet 16 and that of the fluid outlet 18. A nozzle 20 is therefore provided at the transition from the fluid inlet 16 to the flow channel 14, which increases the flow speed at the entry into the flow channel 14. A diffuser 22 which again reduces the flow speed after passage through the flow channel 14 is therefore arranged at the transition from the flow channel 14 to the fluid outlet
    18. The nozzle 20 and the diffuser 22 can be made identical and are configured with the least pressure loss possible.
    Since the housing 12 has a substantially symmetrical structure, the fluid inlet 16 and the fluid outlet 18 can be exchanged with regard to their function. The flow channel 14 can thus be traversed by the fluid both in the flow direction D from the fluid inlet 16 to the fluid outlet 18 and in the opposite direction.
    In this example, the shape of the cross section of the flow channel 14 is chosen rectangular (see for example Figures 3 and 4 or Figure 10).
    The wall of the housing 12 is perforated on at least one of the two short sides of the rectangle, here on the two short sides, so as to form a passage from an outer face 23 of the housing 12 to the channel flow 14. The passage forms an elongated module housing orifice 24 which extends over almost the entire length of the flow channel 14 in the direction of flow D. This is clearly visible in FIG. 3.
    Perpendicularly to the direction of flow D and along the short side of the cross section of the flow channel 14, the module housing orifice 24 is a little wider than the flow channel 14 so that 'a shoulder 26 is made, which extends on both sides in the direction of flow D.
    A fluid measurement module 28 shown in detail in Figures 5 to 7 is inserted into the module housing orifice 24. The fluid measurement module 28 is an independent component, prefabricated separately from the housing 12 and comprises a module housing 29 which has a bottom section 30 as well as a side wall 32 which surrounds the bottom section 30 in an annular manner and which blends in one piece and without interruption in the bottom section 30. This is clearly visible in FIG. 7. In this example, the module housing 29 is composed of a bowl-shaped housing part, which is composed of the bottom section 30 and the side wall 32.
    The bottom section 30 forms a waveguide 34 for surface acoustic waves. The waveguide 34 extends over the entire length of the bottom section 30 in the direction of flow D and consequently also over the essential length of the module housing orifice 24 (after deduction of the thickness of the side wall 32). The direction of flow D thus also forms the direction of the longitudinal extension of the fluid measurement module 28 and is subsequently also used in this function for the fluid measurement module 28 not installed.
    In this example, the outer face 35 of the waveguide 34 which faces the flow channel 14 is made planar. The fluid measurement module 28 is inserted into the module housing orifice 24 so that the outer face 35 of the waveguide 34 delimits the flow channel 14 and thus forms part of the interior wall of the channel flow 14 and therefore represents an interface which comes into direct contact with the fluid passing through the flow channel 14. The short side of the flow channel 14 facing the module housing orifice 24 is substantially delimited by the guide 34.
    A respective signal transducer 40 is arranged at the two longitudinal ends 36, 38 (relative to the direction of flow D) of the waveguide 34. It would also be visible to provide a signal transducer 40 only at one end 36, 38.
    The signal transducer 40 is here a piezoelectric transducer in the form of an interdigitated transducer which is in direct contact with the waveguide 34 so that in the transmitter mode, surface acoustic waves are excited in the guide waves 34 by applying an alternating voltage to the signal transducer 40. In the receiver mode, the signal transducer 40 can receive surface waves from the waveguide 34 and transform them into electrical signals. In this example, the signal transducer 40 can operate as a transmitter and as a receiver and can also be used alternately as a transmitter and as a receiver.
    The establishment of the electrical contact and the transmission of the measurement signals or control signals of the signal transducer (s) 40 are here effected by flexible printed circuit boards 42 which are arranged in the interior space 44 of the housing module 29 enclosed by the side wall 32. An interface 46 which is guided out of the module housing 29 is produced on the flexible printed circuit boards 42.
    In the housing 12 of the fluid measuring means 10, it is provided along the peripheral direction around the direction of flow D, with an offset of 90 ° relative to the module housing orifice 24, a recess 48 (see FIG. 4) which has a cable passage 50 towards the module housing orifice 24. In this example, the components forming the interface 46 are guided through the cable passage 50 and are electrically connected to a plug-in module 52 inserted in the recess 48 (see FIG. 1).
    An attenuation element 54 reducing the propagation of acoustic waves, for example unwanted reflections, is arranged in the module housing 29 of the fluid measurement module 28 directly above the signal transducer 40.
    A low attenuation zone 56 is produced directly adjacent to the signal transducer 40, above the waveguide 34 in the flow direction D, in this example providing an air slot directly above the waveguide 34. The height of the air gap above the waveguide 34 is chosen so that the oscillating waveguide 34 does not come into contact with other components, in particular the flexible printed circuit board 42.
    In this example, the waveguide 34 has in its longitudinal direction in the flow direction D two different wall thicknesses Ij and T 2 (see for example Figure 7) which define in the waveguide 34 a first and a second zone 60, 58. A second zone 58 having the greater wall thickness T 2 extends approximately at the center of the waveguide 34 (relative to the direction of flow D), while a first zone 60 having the smaller wall thickness Ij extends below the signal transducer 40 and a little beyond it in the direction of the zone which has the greater wall thickness T 2 . The length of the zone 60 adjacent to the signal transducer 40 corresponds for example to five to ten times the wavelength of the surface acoustic waves which are used confinedly for the measurement. The smaller wall thickness Ij is chosen so as to obtain a good coupling of surface acoustic waves in the waveguide 34 or a good decoupling of surface acoustic waves out of the waveguide 34. Indeed, the wall thickness Ij preferably corresponds to approximately half the wavelength of the surface waves. The greater wall thickness T 2 is however chosen so that as little as possible coupling of the surface waves in the waveguide 34 is achieved during a reflection of waves of sound volume.
    The transition between the zones 58, 60 is carried out continuous, therefore without stages in order to exclude as much as possible unwanted reflections from the surface waves along the waveguide 34.
    The low attenuation zone 56 is located above the first zone 60 which has the smallest wall thickness T b [0106] A temperature sensor 62 is also arranged in the interior space 44 of the module measuring fluid 28, which is shown in the area of the right signal transducer 40 in FIG. 5, but which can also be arranged at another location, in particular in direct thermal contact with the waveguide 34.
    The module housing 29 is for example filled with an electrically non-conductive pouring mass to protect the electrical components of the fluid measurement module 28 against environmental influences (not shown for reasons of representation). The air gap above zone 56 at low attenuation is of course excluded.
    Alternatively, as shown in FIG. 2, it is possible to provide a cover 64 which closes the interior space 44 of the fluid measurement module 28.
    An assembly comprising the housing 12 and the fluid measurement module 28 forms the main part of the fluid measurement means 10.
    For mounting, the fluid measurement module 28 is inserted from the outside into the module housing 24 of the housing 12 in the form of a fully prefabricated unit, so that its bottom section 30 forms part of the peripheral wall defining the flow channel 14.
    In the case where the fluid measurement module 28 must be exchanged or be replaced by another component, for example by an analysis module which will be described below or by a reflector, it is accessible from the external face 23 and can be removed from the module housing 24 to the outside.
    To measure a fluid, a fluid flow is generated through the flow channel 14, which flows from the fluid inlet 16 to the fluid outlet 18 or vice versa. In the fluid measurement module 28, one of the signal transducers 40 excites surface acoustic waves in the waveguide 34, which are partly decoupled in the fluid at the outer face 35 of the waveguide. wave 34 which is turned towards the flow channel 14, and which extend here in the form of acoustic volume waves. These acoustic volume waves are reflected one or more times on the inner wall of the flow channel 14 and are again partially coupled in the same or in another waveguide 34 after the reflection. They are captured there by a signal transducer 40 functioning as a receiver and are converted into electrical signals.
    The surface acoustic waves extend from the signal transducer 40 acting as a transmitter in the direction of flow D or against the direction of flow D to the second signal transducer 40 which then acts as a receiver.
    The properties of the desired fluid are determined for example by a measurement of the difference in transit times between the surface acoustic waves emitted and the surface acoustic waves received, in evaluation electronics which can be carried out either in the module fluid measurement 28, either as an external unit.
    The two signal transducers 40 can be arranged either in the same fluid measurement module 28, or in different fluid measurement modules 28. It is only important that a transmitter and at least one receiver are always provided, the roles of transmitter and receiver can be distributed over the individual signal transducers 40 at will and also in a variable manner over time.
    FIGS. 7 to 10 show a second embodiment of the fluid measurement means 100.
    For the sake of clarity, the reference numbers already introduced are kept for identical components or only slightly modified.
    In this embodiment, a valve 170 which is attached to the outside on the elongated housing 112 at right angles to the flow channel 114 is integrated in the fluid measuring means 100.
    In this example, the flow channel 114 is not produced continuously in a rectilinear manner between the fluid inlet 16 and the fluid outlet 18. The fluid inlet 16 rather leads to an outer surface of the housing 112 via a first fluid guide channel 172, while the fluid outlet 18 merges into a second fluid guide channel 174 which also leads to the surface of the housing 112 and the mouth of which is at side of a mouth of the first fluid guide channel 172.
    The fluid inlet and outlet of the valve 170 are in fluid communication with the ports of the two fluid guide channels 172, 174 so that the valve 170 can regulate the flow through the flow channel 114 by influencing a flow of fluid between the two fluid guide channels 172, 174.
    The fluid inlet 16 and the fluid outlet 18 can of course, as described in the first embodiment, exchange their function so that the flow channel 114 and the fluid guide channels 172, 174 are capable of being crossed by a flow in the opposite direction.
    In this example, a diffuser 22 (which acts as a nozzle in the reverse flow direction) is arranged between the first fluid guide channel 172 and the flow channel 114.
    Two module housing orifices 24 arranged on opposite short sides of the flow channel 114 are also provided in this embodiment.
    A fluid measurement module 28 is however here inserted only in the upper module housing orifice 24 in the figures, while the lower module housing orifice 24 in the figures is closed in a fluid-tight manner by a false cover 176 serving only as a reflector for sound volume waves.
    The fluid measurement module 28 in this case has two signal transducers 40 so that the measurement of the fluid by surface acoustic waves can be entirely carried out by this fluid measurement module 28.
    It would of course also be possible to insert a fluid measurement module 28 or another measurement module in the second module housing orifice 24.
    The measurement principle is as described in the first embodiment, with the only difference that the flow of fluid through the flow channel 114 is capable of being adjusted by means of the valve 170 of a passage d maximum flow until complete interruption of fluid flow.
    FIGS. 11 to 17 show a third embodiment of the fluid measurement means 200.
    The structure of the fluid measurement means 200 is similar to that of the fluid measurement means 100 described above of the second embodiment. Here too, a housing 212 is equipped with a flow channel 114 (see for example FIG. 12) through which a fluid can flow. A valve 170 is mounted on the housing 212, the connections of the latter being made analogously to the second embodiment by fluid guide channels 172, 174 in the housing 212.
    In this example, a respective module housing orifice 24 is provided on each side of the flow channel 114 of rectangular cross section. As a general rule, only one or two of these module housing orifices 24, in particular opposite module housing orifices 24, are equipped with fluid measurement modules 28.
    However, an analysis module 280 (see FIG. 13) is inserted into at least one of the remaining additional module housing holes 24. The analysis module 280 optionally has a structure similar to that of the fluid measurement module 28 and includes a module housing 229 which consists of a bowl-shaped housing part whose bottom section is turned towards the flow channel in the inserted state. This module housing 229 receives the respective measurement devices which are determined by the respective type of analysis module 280. The module 229 housing is here at least partially filled with a pouring mass to protect the measuring devices from environmental influences.
    The insertion of the analysis module 280 can be done in the same way as the insertion of the fluid measurement module 28. A measurement side 282 which forms an outer face of the bottom section points in particular towards the inside the flow channel
    14, so that the fluid flowing through it comes into contact with the measurement side 282 which then delimits the flow channel 114 in a manner similar to the fluid measurement module 28.
    Analogously to the first embodiment, the module housing orifice 24 has for example shoulders 26 on which the measurement side 282 of the analysis module 280 can rest (see FIG. 14).
    The analysis module 280 can be arranged to measure any property of the fluid or environmental conditions. It is for example possible to measure an electrical conductivity, a pH value, a concentration of a chemical substance, a turbidity of the fluid, a redox potential of the fluid, a temperature and / or a pressure. For this purpose, one or more suitable measuring elements 283 are for example mounted in the analysis module 280 so as to come into contact with the fluid.
    The fluid measurement means 200 can thus be produced in the form of an analysis apparatus for a multitude of fluid properties, the individual module housing orifices 24 being able to be equipped differently with an identical housing 212 according to the intended use.
    As in the second embodiment, the unused module housing orifices 24 are closed by false covers 176 which serve in particular as reflectors for the acoustic waves.
    The fluid measurement means 200 has a control 284 (see FIG. 11) which is connected to the valve 170 by control lines 286 and to the individual fluid measurement modules 28 and to the individual analysis modules 280 by control lines 288. The control unit 284 can also communicate with external units or a network via appropriate electronic interfaces 290, for example a bus system. The interface 290 makes it possible, for example, to integrate the fluid measurement means 200 into a total installation in terms of control.
    The interface 290 also here has an output by which control signals can be sent to external actuators, for example, so that the fluid measurement means 200 can also carry out complex process adjustment in an installation . It would, for example, be possible to monitor a chlorine content in a water treatment installation, the fluid measuring means 200 controlling external actuators (for example valves), via which fresh water or chlorine are dosed correspondingly.
    The fluid measurement means 200 thus constitutes a complete and independent measurement unit which is capable of being placed in an installation conducting fluids through the fluid inlet 16, the fluid outlet 18.
    It is possible to implement the fluid measurement means 200 in the form of a mass flow control unit, for example, by regulating the flow rate through the flow channel 114 by the valve 170 according to the values entered by the fluid measurement module (s) 28 and the analysis module (s) 280.
    In the example shown here, the direction of flow D is chosen from the fluid inlet 16 to the fluid outlet 18. A flow conditioning element 220 is here arranged at the transition between the inlet of fluid 16 and the flow channel 114, which ensures a more uniform flow through the flow channel 114, in particular when the cross section of the fluid inlet 16 is round and that of the flow channel 114 is polygonal. The flow conditioning element 220 is for example a plate having a plurality of parallel fluid passages, as shown in Figure 12.
    In addition to the rectangular cross-sectional shapes of the flow channel 114 shown in FIGS. 11 to 14 with four module housing orifices 24 formed on the sides, other shapes of polygonal cross-section, such as cross-sections hexagonal or octagonal, are also conceivable, as shown in FIGS. 16 and 17. In this case, a module housing orifice 24 can be provided on each of the planar faces of the housing 212, in which it is possible to insert a module fluid measurement 28, an analysis module 280 or a false cover 176. It is of course possible to provide different analysis modules 280 for the measurement of different properties.
    The characteristics of the individual embodiments can of course be combined or exchanged at will with each other according to the appreciation of a person skilled in the art.
    权利要求:
    Claims (1)
    [1" id="c-fr-0001]
    [Claim 1] [Claim 2] [Claim 3] [Claim 4]
    claims
    Medium for measuring fluid (10; 100; 200), comprising a housing (12; 112; 212) in which a flow channel (14; 114) for a fluid to be measured and at least one orifice for receiving the fluid are provided elongated module (24) which forms a passage from an outer face (23) of the housing (12; 112; 212) to the flow channel (14; 114), the module housing orifice (24) being oriented along the flow channel (14; 114), and comprising at least one fluid measuring module (28) which is prefabricated separately from the housing (12; 112; 212) and which has a bottom section (30) formed as a waveguide (34) for surface acoustic waves, and at least one signal transducer (40) arranged to excite surface acoustic waves in the waveguide (34) and / or to receive surface acoustic waves of the waveguide (34), the fluid measurement module (28) being inserted in the modu housing orifice the (24) so that the bottom section (30) of the fluid measurement module (28) forms a section of an inner wall of the flow channel (14; 114) which comes into direct contact with the fluid flowing through it, so that surface acoustic waves emitted by the signal transducer (40) are capable of being decoupled by the waveguide (34) and propagating through the fluid in the flow channel (14; 114) in the form of acoustic volume waves and / or so that acoustic volume waves are capable of being coupled in the waveguide ( 34) and to be received by the signal transducer (40).
    Fluid measuring means (10; 100; 200) according to claim 1, characterized in that the bottom section (30) of the fluid measuring module (28) is made planar on its outer face (35) facing the flow channel (14; 114).
    Fluid measuring means (10; 100; 200) according to one of the preceding claims, characterized in that the flow channel (14; 114) is closed in the peripheral direction around a flow direction (D ) and has in the area of the module housing orifice (24) a polygonal, in particular rectangular, cross section.
    Fluid measuring means (10; 100; 200) according to one of the preceding claims, characterized in that the flow channel (14; 114) is delimited by a fluid inlet (16) and by a fluid outlet (18), and in that a nozzle (20) is provided at the fluid inlet (16) and / or
    a diffuser (22) is provided at the fluid outlet (18). [Claim 5] Fluid measuring means (10; 100; 200) according to one of the preceding claims, characterized in that at least one additional module housing orifice (24) which is produced in particular on one side of the channel flow (14; 114) which is opposite to the first module housing orifice (24) is provided in the housing (12; 112). [Claim 6] Fluid measuring means (10; 100; 200) according to claim 5, characterized in that an analysis module (280) is inserted in the additional module housing opening (24). [Claim 7] Fluid measuring means (10; 100; 200) according to one of claims 5 and 6, characterized in that the analysis module (280) is arranged to measure an electrical conductivity, a pH value, a concentration of a chemical, turbidity of the fluid, redox potential of the fluid, temperature and / or pressure. [Claim 8] Fluid measuring means (10; 100; 200) according to one of Claims 5 to 7, characterized in that a second fluid measuring module (28) is inserted in the module housing orifice (24) additional. [Claim 9] Fluid measuring means (10; 100; 200) according to one of the preceding claims, characterized in that a recess (48) is provided in the housing (12) which has a cable passage (50) to the module housing (24) and through which the electrical and / or electronic connection cables of the fluid measurement module (28) are guided. [Claim 10] Fluid measuring means (10; 100; 200) according to one of the preceding claims, characterized in that a valve (170) is provided by means of which a flow of fluid through the flow channel (114 ) can be adjusted, the housing (112) having fluid guide channels (172, 174) between the flow channel (114) and the valve (170) and between the valve (170) and the fluid inlet (16) or the fluid outlet (18). [Claim 11] Fluid measurement module (28), in particular fluid measurement module (28) of a fluid measurement means (10; 100; 200) according to one of the preceding claims, comprising a module housing (29) which has a bottom section (30) produced in the form of a waveguide (34) for surface acoustic waves, and at least one signal transducer (40) which is directly connected to the bottom section (30) and which is arranged to excite surface acoustic waves
    in the waveguide (34) and / or for receiving surface acoustic waves from the waveguide (34), the waveguide (34) being arranged so as to be brought into plane contact with a fluid on an outer face (35) diverted from an inner space (44) of the module housing (29). [Claim 12] Fluid measurement module (28) according to claim 11, characterized in that the module housing (29) has a cup-shaped housing part which is formed by a bottom section (30) and a peripheral side wall ( 32), said at least one signal transducer (40) being arranged in the bowl-shaped housing part. [Claim 13] Fluid measurement module (28) according to one of claims 11 and 12, characterized in that the signal transducer (40) is covered by an attenuation element (54). [Claim 14] Fluid measuring module (28) according to one of claims 11 to 13, characterized in that a zone (56) with low attenuation which extends over a length of at least one to twenty times the length of A surface wave wave is provided adjacent to the signal transducer (40) above the waveguide (34). [Claim 15] Fluid measurement module (28) according to one of claims 11 to 14, characterized in that a temperature sensor (62) which is in particular mounted directly on the waveguide (34) is provided on the inside the module housing (29). [Claim 16] Fluid measurement module (28) according to one of claims 11 to 15, characterized in that the waveguide (34) has in a first zone (60) connecting below the signal transducer (40) and / or directly to the signal transducer (40) a wall thickness (TJ less than in a second zone (58) further from the signal transducer (40). [Claim 17] Fluid measurement module (28) according to one of claims 11 to 16, characterized in that the module housing (29) is at least partially filled with a casting compound. [Claim 18] Assembly comprising a housing (12; 112; 212), in which a flow channel (14; 114) for a fluid to be measured is produced and at least one elongated module housing orifice (24) which forms a passage for an outer face of the housing up to the flow channel (14; 114), the module housing orifice (24) being oriented along the flow channel (14; 114), and at least one measurement module fluid (28) separated from the housing (12; 112; 212) according to one of the res-
    dications 11 to 17, the fluid measuring module (28) being able to be inserted into the module housing orifice (24) so that the bottom section (30) of the fluid measuring module (28) forms a section of an inner wall of the flow channel (14; 114) which comes into direct contact with the fluid flowing through it, so that surface acoustic waves emitted by the signal transducer (40) are capable of being decoupled by the waveguide (34) and propagating through the fluid in the flow channel (14; 114) in the form of acoustic volume waves and / or so that waves of sound volumes are adapted to be coupled in the waveguide (34) and to be received by the signal transducer (40).
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    同族专利:
    公开号 | 公开日
    DE102019112332A1|2019-12-05|
    FR3081999A1|2019-12-06|
    US20190368907A1|2019-12-05|
    CN110553690A|2019-12-10|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20050072217A1|2003-09-30|2005-04-07|Discenzo Frederick M.|Lubricity measurement using MEMs sensor|
    WO2008034878A2|2006-09-20|2008-03-27|Fachhochschule Coburg|Method and device for determining characteristics of a medium in form of a liquid or a soft material|
    US20120060591A1|2009-05-25|2012-03-15|Sensaction Ag|Apparatus for determining the properties of a medium in the form of a fluid or a soft material|
    WO2017125612A1|2016-01-24|2017-07-27|Sensaction Ag|Device for determining properties of a medium comprising a damping element and/or open guide element|
    FR3080683A1|2018-04-30|2019-11-01|Buerkert Werke Gmbh|MEANS OF MEASURING FLUID|
    DE102018133066A1|2018-12-20|2020-06-25|Endress+Hauser Flowtec Ag|Ultrasonic measuring device|
    法律状态:
    2020-05-22| PLFP| Fee payment|Year of fee payment: 2 |
    2020-07-10| PLSC| Publication of the preliminary search report|Effective date: 20200710 |
    2021-05-25| PLFP| Fee payment|Year of fee payment: 3 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1854646|2018-05-30|
    FR1854646A|FR3081999A1|2018-05-30|2018-05-30|FLUID MEASURING MEANS AND FLUID MEASURING MODULE FOR FLUID MEASURING MEANS|
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