DE202008014171U1 - Flow rate measuring device - Google Patents

Abstract

Flow meter for liquids comprising a measuring tube (10), wherein the inner wall (11) of the measuring tube (10) forms a measuring section for an ultrasonic measuring device for transit time measurement of ultrasonic signals along the measuring path with at least one ultrasonic transducer (40), a holding element (20) on which the measuring tube (10) is fastened, and a functional element (30), characterized in that the holding element (20) at least one functional element suspension (60) for receiving the functional element (30), wherein the functional element suspension (60) at least one sliding direction (80 , 81) and is oriented so that the least one Abgleitrichtung (80, 81) with the surface normal of the sound exit surface (41) of the at least one ultrasonic transducer (40) forms an angle of 90 ° or less.

Description

The The invention relates to a flow rate measuring device for Liquids.

Flow rate measuring device for liquids, which use ultrasonic waves for flow measurement, are known from the prior art, for example from the German utility model DE 9420760 U1 , The device comprises a measuring path through which the medium flows, at the opposite ends of which deflecting mirrors are provided. About the deflection mirror sound waves of an ultrasonic transducer are deflected into the measuring section and received by the same or a second ultrasonic transducer. By measuring the transit time of individual sound pulses, the velocity of the fluid in the measuring section can be determined and from this the flow rate can be calculated. Alternatively, it is possible to use the wall of the measuring tube itself as a reflector surface. In this case, separate deflection mirrors are not required.

From the EP 1 909 076 It is known to arrange the measuring tube in a capsule, so that the measuring section is no longer in the axis of the supply line, but the liquid to be measured passes only after multiple deflection in the measuring section. In such an arrangement, the ultrasonic transducers can be arranged in line with the measuring section; Deflection mirrors are not required.

to final calculation of the flow rate from the measurement results is an arithmetic unit used, which on the measuring tube itself or is located in its immediate vicinity. The calculator usually has a display on which the measured flow rate can be read.

Of the or the ultrasonic transducers for generating and / or detecting Ultrasonic waves have a sound exit surface, at which the ultrasonic waves are generated or detected. With this sound exit surface breaks through the ultrasonic transducer usually the wall of the measuring tube, so that the ultrasonic waves can be introduced into the liquid.

At the Flow of liquids is common to a gas bubble or gas bubbles are in the liquid transported. Especially with changing flow rates or Temporary flow stops adhere gas bubbles to the wall of the measuring tube at.

Be liable the gas bubbles, which are often air bubbles, in the area of the active surface of the ultrasonic transducers, This leads to distortions of the measurement results. The measurement results with corresponding flow measuring devices are therefore fraught with great uncertainties.

Of the Invention is based on the object, a flow rate measuring device to create liquids that have the disadvantages the devices known in the prior art, in particular the Uncertainties due to gas bubble adhesion in the area of Sound exit surfaces of the ultrasonic transducers, not or only has reduced dimensions.

The solution according to the invention can be found in the Features of the independent claim. Advantageous developments are the subject of the dependent claims.

Therefore includes a flow meter for liquids a measuring tube, wherein the inner wall of the measuring tube determines a measuring section, an ultrasonic measuring device for a transit time measurement of ultrasonic signals along the measuring path with at least one Ultrasonic transducer and a functional element, wherein a holding element is provided, on which the measuring tube is attached and at least a functional element suspension for receiving the functional element wherein the functional element suspension at least has a Abgleitrichtung, so that the least one Abgleitrichtung with the surface normal of the sound exit surface at least one ultrasonic transducer at an angle of 90 ° or includes less.

First some terms used in the invention are closer explained.

With "sliding direction a suspension "is a direction in which the functional element located on the suspension from the suspension can slide freely, provided the sum all forces in the direction of the slip direction is positive, d. H. the disassembled along the sliding direction part of the resulting, acting on the functional element force vector points in the same Direction as the sliding direction. This is usually the case then Case, when the angle between the sliding direction and weight of the functional element is less than 90 °. In other directions apart from the sliding direction exists a holding effect by the suspension, d. H. on the suspension attached functional element is held.

"Function element" a necessary element of the measuring device. It can be z. B. a counter, a signal processing device or power supply act.

In usually a slip direction is opposite to a "plug-in direction", d. H. a direction in which the functional element in the functional element suspension is inserted.

With "surface normal" is denotes the direction perpendicular to a surface, wherein the direction of the surface normals of the surface points away.

With "gas rising direction" is The direction in which gas bubbles are in liquids due to to move their buoyancy. Normally, the gas rising direction parallel opposite to the direction of gravity.

With "breakthrough" is An opening in a wall is referred to by an object is closed or can be. It can be a step between the closing object and the remaining wall occur. The object occluding the opening does not have to form a smooth surface together with the wall.

at the flow rate measuring device according to the invention Prevents gas bubbles at the sound exit surface an ultrasonic transducer accumulate and adhere there. Through a mechanical Fuse becomes a given orientation of the measuring device achieved during assembly: is the flow meter mounted in an inadmissible position, slides the functional element from the functional element suspension and can not be attached to the holding element.

is the flow meter in an impermissible Position mounted, shows the sliding direction of the functional element suspension in the direction of the ground, d. H. the angle between the sliding direction and gravity is less than 90 °; by its weight then slides the functional element out of the functional element suspension.

While the assembly, but at least during installation of the functional element, It becomes obvious if the flow rate meter is in one permissible position is mounted. Measurement error or measurement inaccuracies due to gas bubble adhesions in the area of the sound exit surfaces the ultrasonic transducer caused by an incorrect installation position of the measuring tube could be caused are avoided. A proper Assembly of the functional element to the functional element suspension is not possible in such a case. An accidental Looking ahead via, for example, in a mounting instructions predetermined Installation direction is excluded.

It is particularly preferred when the functional element suspension is designed as a trapezoidal or trapezoidal rail. In a trapezoidal rail runs a Sliding direction perpendicular to the shorter base side, away from the longer base page (base). The insertion direction is usually parallel to this direction of sliding parallel.

is For example, in a trapezoidal rail, the shorter base above the longer base (Base), so the weight of the functional element by the Resting the functional element on the legs and / or the shorter Basic page to be counteracted. So it will be a holding effect reached. Will the appropriate flow meter built in one layer, so that the shorter base side Below the base is a support, as above described, no longer possible. The functional element suspension can produce no holding effect in this case and the functional element can not on the functional element suspension of the retaining element be attached. The functional element then slides from the functional element suspension from.

at a trapezoidal rail can have two insertion directions give. For each of these directions of insertion exists in the rule also an associated sliding direction.

at The functional element may in particular be an arithmetic unit act. This calculator can be used to calculate the flow rate be formed by the flow meter.

It is preferred to provide a display on the functional element. This Display can, for example, provide information about the measured flow rate give.

It is possible that the display is opposite the part the functional element is designed to be rotatable. So it is possible in that after the attachment of the functional element to the holding element (i.e. H. with existing holding action) rotated in such a position that the display can be read horizontally. The functioning the functional element suspension is not reduced thereby.

If the display can not be rotated relative to the functional element suspension, it is preferred if the functional element slides off the functional element suspension as soon as the reading direction of the display of the functional element attached to the functional element suspension exceeds an angle of ± 90 ° with respect to the horizontal. The reading of a display, which in extreme cases z. B. is over head, is so out closed.

It can be provided that two functional element suspensions are provided on opposite sides of the Measuring tube lie. Is it necessary due to the measurement technique to maintain a certain flow direction through the measuring tube, so is achieved by the provision of two functional element suspensions on opposite sides of the measuring tube an increased Variability in the assembly of the invention Flow meter allows. The danger the gas bubble adhesion in the area of the sound outlet surfaces the ultrasonic transducer remains banned if both functional element suspensions the requirements of the invention in relation keep to the sliding direction.

It can also be provided that on the holding element between functional element suspension and measuring tube a gap is provided for receiving cable. In the recording Cable can be, for example, to the connecting cable between the Ultrasonic transducers and the calculator act. By connecting cables be included in the described space, it is avoided that hang these cables around freely.

It a temperature sensor can be provided on the measuring tube. The cable from the temperature sensor to the calculator can also in the space between functional element suspensions and measuring tube are included. Are two functional element suspensions provided on opposite sides of the measuring tube, the temperature sensor is preferably in the range between arranged the two functional element suspensions.

Around to achieve further metrological improvements through pole reversal, are often insulating materials in the area of the sound exit surfaces the ultrasonic transducer used. It can be with these materials z. B. act to ceramic. The case preferably used pot shape permitted for reasons of process reliability and transmission the acoustic signals during the bonding process, the attachment of the piezo elements only on the machined bottom of the pot, as the bottom of the Cavity remains unprocessed. This cavity then forms the Sound exit surface, which breaks through the wall of the measuring tube. So it is in contact with the liquid in the measuring tube. It is special because of its unprocessed surface prone to the adhesion of gas and / or air bubbles. By prevented by the device according to the invention is that such area in the direction of the gas exit direction The risk of bubble adhesion in the area is increased the sound exit surfaces even with such pots minimized.

For the case the more than one ultrasonic transducer in a flowmeter is provided, it is preferable that the sliding direction (s) of the Functional element suspension (s) the above angle condition compared to the surface normals of all ultrasonic transducers comply. Are the surface normals of two ultrasonic transducers arranged parallel opposite, so preferably two are parallel opposite sliding directions parallel to the surface normals two ultrasonic transducers run, provided.

Furthermore It should be noted that in the inventive Flow rate meter, the purge time (i.e. Time needed to absorb most gas bubbles to remove) is greatly minimized. Due to the location of the sound exit surfaces indicates the Gasaufstiegsrichtung of the sound outlet surfaces path. There possibly adhering gas bubbles can be during the flushing process quickly peel off.

In In many cases, a functional element suspension becomes have a crowd of Abgleitrichtungen. This crowd can be continuous be. It is sufficient if at least one sliding direction this group the conditions of the invention with respect to the angle between this at least one sliding direction and the surface normal of the sound exit surface fulfilled the ultrasonic transducer.

Farther can be provided that the one or more ultrasonic transducers, the inner wall breaks the measuring tube with its sound exit surface.

runs the measuring section next to the supply line, because, for example, the measuring tube is arranged in a capsule, which is laterally from the supply line is mounted, it is preferable if a sliding direction perpendicular to the axis of the supply line, away from the measuring path provided is. As a result, a position of the flow rate measuring device prevents the measuring tube above the supply line to come to rest. If the measuring tube were above the supply line arranged gas bubbles in the measuring tube or in accumulate the capsule and the safety of the measurement result negative influence. By providing the described Abgleitrichtung a position of the measuring tube is forced below the supply line; Gas bubbles in the measuring tube are then flushed away through the supply line. The position of the measuring tube below the supply line through a to force appropriate Abgleitrichtung deserves, if necessary, separate independent protection.

The invention will be described below with reference to the accompanying drawings by way of example with reference to an advantageous embodiment wrote. Show it:

1 a cross section through a first embodiment of a flow rate measuring device according to the invention;

2 a side view of the flow meter 1 ; and

3 a cross section through a second embodiment of a flow rate measuring device according to the invention.

In 1 is a cross section through a flow rate measuring device according to the invention 1 shown. The flow rate measuring device comprises a measuring tube 10 , a holding device 20 and an arithmetic unit 30 (indicated by the dashed line).

The measuring tube 10 forms through its inner wall 11 an interior 12 out. In this interior 12 is the measuring section for transit time measurement of ultrasonic waves (not shown).

The inner wall 11 of the measuring tube 10 has an opening 13 for the sound exit surface 41 an ultrasonic transducer 40 on. As a rule, two such ultrasonic transducers 40 each with an opening 13 on a measuring tube 10 intended. The of an ultrasonic transducer 40 emitted ultrasonic waves are then either by at least one deflecting mirror (not shown) or the ultrasonic transducers opposite part of the inner wall 11 of the measuring tube 10 to the other ultrasonic transducer deflected. If the ultrasonic waves move through a flowing medium, the propagation time of the ultrasonic waves changes along the measuring path. The change in the transit time can be used to determine the velocity of the flowing medium and, together with the geometry of the interior 12 to determine the flow rate.

If several ultrasonic transducers 40 are provided, it is preferred if the surface normal of the sound exit surface 41 have no angle with each other. In the example shown, the surface normals of the one ultrasonic transducer run 40 and the other (not shown) in parallel.

The ultrasonic transducer 40 includes a transducer 42 which can vibrate in the ultrasonic range. This may be, for example, a piezoceramic. To protect the transducer 42 in front of the liquid in the interior 12 of the measuring tube 10 is a ceramic pot 43 intended. The ceramic pot 43 is with its worked base 44 firmly with the transducer 42 (eg by gluing). The top of the bottom of the pot 43 forms the sound exit surface 41 of the ultrasonic transducer 40 , The ceramic pot 43 is on its inside - and therefore also on the sound exit surface 41 - unprocessed.

The ceramic pot 43 and the transducer 42 be through a release ring 45 that with a membrane 46 is glued, and a locking ring 47 firmly on the measuring tube 10 fixed. To a liquid outlet in the region of the openings 13 To avoid are sealing elements 48 intended.

The measuring tube 10 is fixed with a base plate 21 of the holding element 20 connected. The connection is made by screws 50 produced. To further avoid the risk of liquid leakage from the measuring tube 10 is between the measuring tube 10 and the base plate 21 another seal 51 intended.

Starting from the base plate 21 extend to both sides of the measuring tube 10 side plates 22 respectively 22 ' , The side plates 22 . 22 ' are symmetrical to the longitudinal plane of the measuring tube 10 designed. Thus, there are also two functional element suspensions 60 . 60 ' present on opposite sides of the measuring tube 10 are arranged. The following is the description on a side plate 22 limited. For the other side plate 22 ' The same applies.

On the side wall 22 is a functional element suspension 60 provided, which will be described later in more detail. Basically, the functional element suspension is suitable 60 for attaching an arithmetic unit 30 it. Inside the sidewall 22 is a gap 23 intended. This can be used for cable storage 52 serve. At this cable location 52 For example, it may be the connection cable between the output 49 of the ultrasonic transducer 40 and the calculator 30 act. This can reduce the risk of damage to a hanging cable and the installation aesthetics of the flow meter 1 increase.

At the measuring tube 10 can also have a temperature sensor 53 be provided. The measured values of this temperature sensor 53 can calculate the flow rate through the calculator 30 be taken into account. All you need is the temperature sensor 53 with the calculator 30 be connected. An optionally too long connecting cable between the two components may also be in the space 23 be recorded.

The functional element suspension 60 stands in front of the side wall 22 of the holding element 20 out. It is essentially trapezoid-shaped steals (cf. 2 ) and faces adjacent to the side wall 22 a circumferential groove 61 on. The trapezoidal shape of the functional element suspension 60 is formed by four sides 62 . 63 . 64 . 65 ,

The illustrated embodiment has two insertion directions, ie the calculator 30 (see. 1 ) can both in the by the arrow 70 as well as by the arrow 71 indicated direction on the functional element holder 60 be plugged in. For the trapezoidal shape of the functional element suspension 60 This means that the front of the in one insertion direction 70 or 71 crossing sides 62 or 63 shorter than the rear one 64 or 65 , page 62 is shorter than page 65 , Page 63 is shorter than page 64 , For a secure hold of the calculator 30 in both directions of insertion 70 . 71 To ensure it is preferred that the angles between the sides 62 and 63 , Pages 62 and 64 , as well as the pages 63 and 65 is the same size and the sides 62 and 63 are the same length.

The calculator 30 has a shoe claw on its back 31 So it's on the functional element suspension 60 can be deferred. Here is the width of the shoe claw 31 chosen so that they only in the two insertion direction 70 . 71 on the functional element suspension 60 can be pushed. Is the calculator 30 completely on the functional element suspension 60 deferred, so at least attacks in the area of the page 62 (at insertion direction 70 ) or page 63 (at insertion direction 71 ) the shoe claw 31 in the groove 61 one. It is also possible that the shoe claw 31 in the groove 61 in the area of the pages 63 and 64 (at insertion direction 70 ) or pages 62 and 65 (at insertion direction 71 ) intervenes. In the area of the page 65 (at insertion direction 70 ) or page 64 (at insertion direction 71 ) finds no interference with the groove 61 instead of. Another security element for securing the calculator 30 in the functional element suspension 60 is not scheduled.

Due to the special design of the functional element suspension 60 can be any insertion direction 70 . 71 at least one sliding direction each 80 . 81 be assigned. In the case of the trapezoidal shape of the functional element suspension 60 arises for each insertion direction 70 . 71 in each case a continuous family of sliding directions, their direction within the sector indicated by the dashed lines 80 ' . 81 ' lies.

Due to the inventive design of the functional element suspension 60 becomes an installation of the flow rate meter 1 avoided, which leads to measurement uncertainty due to gas bubble adhesions in the area of the sound exit surfaces 41 the ultrasonic transducer 40 can come. As will be described below, the flow rate measuring device according to the invention can be used 1 namely mount only in such a position in which the angle between the surface normal on the sound exit surface 41 of the ultrasonic transducer 40 and the gas rising direction (in 1 by arrow 72 indicated) is less than 90 °. This prevents ascending gas bubbles in the area of the ultrasonic transducers 40 adhere.

Will the calculator 30 eg in the direction of the insertion direction 70 on the functional element suspension 60 deferred, this is the calculator 30 in permissible position of the flow rate measuring device 1 by its weight on the holding element 20 held.

Is the flowmeter (erroneously) mounted such that it is part of the weight of the calculator 30 in the direction of the sliding direction 80 or a sliding direction from the crowd 80 ' acts, the calculator glides 30 due to its weight from the functional element suspension 60 , This is only the case when the angle between the sliding direction 80 or a sliding direction from the crowd 80 ' and the gravitational acceleration is less than 90 °. This is desirable because such a location of the flow rate measuring device 1 is inadmissible. Because the flow meter could be 1 mount in such an inadmissible position could be in the area of the sound exit surfaces 41 the ultrasonic transducer 40 Adhere to gas bubbles, which could lead to a falsification of the measurement result. This is excluded by the invention.

In 3 is an embodiment of a flow rate measuring device 1 shown at the measuring tube 10 in a capsule 90 is arranged. The measuring tube 10 is non-coaxial with the utility line 91 that runs perpendicular to the leaf level. At the functional element suspension 60 is (if necessary additionally) a sliding direction 92 intended. This is an assembly of the flow rate measuring device 1 forced, at the measuring tube 10 below the supply line 91 lies. A collection of gas bubbles in the measuring tube 10 or in the capsule 90 can be so effectively prevented. Possibly. existing or emerging gas bubbles are through the supply line 91 dissipated.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 9420760 U1 [0002]
• - EP 1909076 [0003]

Claims (13)

Flow meter for liquids comprising a measuring tube ( 10 ), wherein the inner wall ( 11 ) of the measuring tube ( 10 ) forms a measuring section for an ultrasonic measuring device for transit time measurement of ultrasonic signals along the measuring path with at least one ultrasonic transducer ( 40 ), a holding element ( 20 ), on which the measuring tube ( 10 ), and a functional element ( 30 ), characterized in that the retaining element ( 20 ) at least one functional element suspension ( 60 ) for receiving the functional element ( 30 ), wherein the functional element suspension ( 60 ) at least one sliding direction ( 80 . 81 ) and is oriented so that the least one sliding direction ( 80 . 81 ) with the surface normal of the sound exit surface ( 41 ) of the at least one ultrasonic transducer ( 40 ) includes an angle of 90 ° or less. Flow rate measuring device according to claim 1, characterized in that for each ultrasonic transducer at least one sliding direction ( 80 . 81 ) is provided. Flow rate measuring device according to claim 1 or 2, characterized in that more than one ultrasonic transducer ( 40 ) is provided and that a Abgleitrichtung ( 80 . 81 ) with the surface normals of the sound exit surfaces ( 41 ) of at least two ultrasonic transducers ( 40 ) includes an angle of 90 ° or less. Flow rate measuring device according to claim 1, 2 or 3, characterized in that the at least one functional element suspension ( 60 ) is designed as a trapezoidal or trapezoidal rail. Flow rate measuring device according to one of claims 1 to 4, characterized in that on the functional element ( 30 ) a display is provided, which opposite the functional element ( 30 ) is rotatably mounted. Flow rate measuring device according to one of claims 1 to 5, characterized in that a temperature sensor ( 53 ) is provided. Flow rate measuring device according to one of claims 1 to 6, characterized in that two functional element suspensions ( 60 ) are provided on opposite sides of the measuring tube ( 10 ) are arranged. Flow rate measuring device according to claim 7, characterized in that the temperature sensor ( 53 ) between the functional element suspensions ( 60 ) on the measuring tube ( 10 ) is arranged Flow rate measuring device according to one of claims 1 to 8, characterized in that between the functional element suspension ( 60 ) and the measuring tube ( 10 ) a gap ( 23 ) for receiving cable ( 52 ) is provided. Flow rate measuring device according to one of claims 1 to 9, characterized in that the sound exit surface ( 41 ) of the ultrasonic transducer ( 40 ) is formed of ceramic and / or pot-shaped. Flow rate measuring device according to one of claims 1 to 10, characterized in that the functional element ( 30 ) is an arithmetic unit. Flow rate measuring device according to one of claims 1 to 11, characterized in that the ultrasonic transducer ( 40 ) the inner wall ( 11 ) of the measuring tube ( 10 ) with its sound exit surface ( 41 ) breaks through. Flow rate measuring device according to one of claims 1 to 12, characterized in that at least one sliding direction ( 80 . 81 . 92 ) is provided perpendicular to the axis of the supply line, away from the measuring section.