DE10121826A1 - Oscillating-jet fluid meter has sensor elements which detect oscillation of impact body rotatably mounted on axis perpendicular to channel axis - Google Patents

Abstract

The meter has a flow channel enlarging from an inlet in the direction of an impact body (3) arranged centrally in the axis of the channel, and tapering again to an outlet channel. The impact body is rotationally mounted about an axis (5) perpendicular to the channel axis, and geometrically shaped so that a reciprocating motion is formed by the free jet. Sensor elements detect the oscillation of the impact body.

Description

The invention relates to an oscillating jet counter with a flow guide channel that extends from an inflow channel towards a center in the baffle arranged and expanded after this in Direction on the outflow channel narrowed again, as well as with sensor elements Detection of the oscillation frequency of the free jet.

Such oscillating jet counters, in which one emerging from the inflow channel Free jet caused by complex hydrodynamic processes in the measuring room a periodic vibration is excited, the frequency - depending on Kon structure and dimensioning - proportional to the flow rate, have a very high measuring dynamics up to 500: 1. However, none of the previously Known sensor elements actually detect this span.

The invention is therefore based on the object of an oscillating beam counter type mentioned above so that the high measurement dynamics range of the vibration frequencies of the free jet possible and so that the high measurement dynamics are fully usable.

To solve this problem, the invention provides that the impact body about a rotation axis perpendicular to the channel axis and geomet is designed in such a way that the free jet causes a pendulum movement can train, and that the sensor elements the vibrations of the impact body to capture.

The water flowing alternately to the left or right of the impact body Free jets and the associated pressure changes in the measuring room exercise the forces resulting from the corresponding geometry of the impact body stimulate a rotary movement around the axis in rhythm with the oscillation frequency.

In order to avoid a stall and thus a failure of the measuring prin To prevent zips, the deflection is intended in a further development of the invention  limit stops of the impact body may be provided. You can use be a special advantage in the stops are the sensors in the form of piezoelectric elements elements or electrical contacts or the like can be installed with the the vibration frequency of the impact body is measured.

In general, however, a variety of other sensors, such as capacitive, inductive, resistive, magnetic, magnetically inductive, optical sen sensors or sensors for measuring mechanical quantities such as Print or use forces.

About the geometry of the impact body and the quality of the bearing can Sensitivity of the measuring principle or the lower limit of the measuring range is influenced be precise adjustment while positioning the stops the sensor principle used allows.

The oscillating jet counter according to the invention combines the respective advantages of a Vibration beam counter with the advantages of high measurement dynamics Nes vibrating body flow meter, in which the vibrations of the Vibrating body are very easy to detect, but only a very small ne dynamic of 20: 1 favorably, so that vibrating body through flow meters are unsuitable for volume measurement in building services. The Evaluability of the vibrating impact body is even better than with usual vibrating body flow meters, because the deflection of the rotatable gela The impact body is very defined by means of the adjustable range Deflection can take place. This is also the reason why everyone is on top guided sensor principles in a combined vibration according to the invention Have your jet adapted.

One of the possibilities of detecting the vibration mentioned above frequency of the impact body that vibrates with the oscillating free jet stands in the arrangement of a magnetic segment on the surface of the Impact body that can be detected by a magnetic sensor.  

Although the combined flow meter of the invention by definition, none uses static measuring principle, it bypasses the problems of conventional mechanical Measuring methods (impeller counters, ring piston counters, etc.) in which the quality and cleanliness of the bearings determines the achievable measurement accuracy. The Movement of the impact body, however, does not correspond to the measurement accuracy of the flow meter, as the impact body only serves as an indicator of the Vibration frequency of the traveling free jet through the measuring room, while the pulse value and the reproducibility with the geometry of the Measurement room, the inflow and outflow channels and the impact body is defined. The quality of the bearing in no way affects the measurement accuracy, everyone However, under unfavorable conditions the increased bearing friction can add value shift the lower limit of the measuring range to higher flow rates, whereby the maximum measuring dynamic of the flow meter becomes smaller. Apart from the measuring principle of the combined according to the invention works with this effect Vibration beam counter with impact body designed as a vibrating body is thus wide independent of wear and soiling.

If there is talk of a special geometry of the impact body, such that a pendulum movement can form, it means that the impact body must not be completely rotationally symmetrical, but that it should be for example, is provided with concave depressions in the inflow face. If necessary, it can also be provided that the impact body on the the back side facing the outflow channel with a leaf-shaped extension is provided.

The oscillating beam counter according to the invention can also be a symmetrical one Vibration beam counter to be formed, both in one and the other Flow direction can work by including the flow guide channel Lich the inflow channel and the outflow channel to the transverse median plane through the Impact body as well as this is symmetrical. With this configuration tion, it is then expedient to prevent excessive attacks Deflection of the impact body or even to rotate through the impact body, in  Arrange symmetrical recesses of the impact body and not outside of the impact body.

Further advantages, features and details of the invention result from the following description of an embodiment and based on the Drawing. Show:

Fig. 1 is a plan view of the open measuring space a first exporting approximate shape of a resonant beam counter according to the invention,

Fig. 2 is a perspective view of the measurement space of Fig. 1 without the shown in FIG. 1 formed as sensors stops,

Fig. 3 is a plan view of the open measuring space of a second embodiment of an oscillating beam counter according to the invention and

Fig. 4 u. 5 enlarged view of the impact body in the central position and one of the end deflection positions limited by the stops.

In the embodiment according to FIGS. 1 and 2, the liquid to be measured passes through an inflow channel 1 with a defined step into a flow guide channel 2 in which there is an impact body 3 located on the central axis 11 . The flow guide channel extends up to a point downstream of the impact body 3 , from where the flow guide channel 2 narrows again to the outflow channel 4 , which in the exemplary embodiment shown is considerably wider than the inflow channel 1 . Due to the already mentioned complex hydrodynamic processes in the measuring space, a free jet emerging from the inflow channel 1 is excited to periodic vibrations, the frequency of which is linear to the flow, the oscillating free jet alternately flowing past the impact body 3 on the left or right. The impact body 3 is rotatably mounted on an axis 5 lying perpendicular to the flow axis and provided with a flag 6 , that is to say a leaf-shaped extension. The oscillating free jet and the associated pressure changes in the measuring chamber exert 3 forces on the flag 6 of the impact body, which stimulate it to rotate about the axis in the rhythm of the oscillation frequency. The amplitude of these vibrations is limited by stops 7 and 8 in order to prevent a stall and thus the failure of the measuring principle. This can only be shown in Fig. 1 to be equipped with a piezo element or electrical contacts and thus serve as a sensor element for the oscillation frequency of the vibrating impact body and thus ultimately the oscillation frequency of the free jet. Detection of the oscillation frequency of the vibrating impact body is also possible, for example, via a magnetic plate 9 fastened to the flag, which oscillates under a sensor element 10 .

The positions 7 and 8 of the stops 7 and 8 , which can be positioned at any point on the impact body, are chosen such that angles of rotation of the impact body 3 of up to + -10 ° are possible. Depending on the sensor principle used (capacitive, inductive, resistive, magnetic, magnetic inductive, optical, pressure or dynamometer), the angle of rotation can be adjusted as required via the position of one or more stops 7 and 8 . The advantage, which is that the vibrations of a mechanical component are much easier to measure than the vibrations of the free jet itself, remain even with a very high measuring dynamic of 500: 1.

In FIGS. 3-5, an embodiment of a combi ned vibrating beam transducers body counter according to the invention, in which the flow is guide channel 'including the inlet channel 1' and of the discharge passage 4 'to the transverse center plane 16 through the collision member 5' as well as the formed 2 symmetrically , Characterized such an oscillating jet can be counter for measuring fluid flow in both directions, ie both the inlet channel 1 'to the outflow channel 4' and vice versa from the channel 4 'for the channel 1' use. In this symmetrical embodiment, the stops 7 'and 8 ' are arranged in sym metrically in the impact body 5 'arranged somewhat larger recesses 12 and 13 , wherein one of these stops 7 ' and 8 'designed as pins can be equipped with a piezo element or electrical contacts and can thus serve as a sensor element for the vibration frequency of the vibrating impact body 5 '. To measure the flow direction, at least one sensor S1 or S1 'must also be attached at a suitable location. Through these recesses 14 and 15 there is also a geometry through which a pendulum movement of the impact body 5 'can be formed due to the oscillating free jet, even with the symmetrical formation of the impact body 5 ' shown in FIGS . 3-5 instead of asymmetrical only one flow direction permitting training in FIGS . 1 and 2.

Claims (10)

1. oscillating jet counter with a flow guide channel that widens from an inflow channel in the direction of an impact body arranged centrally in the channel axis and then narrows again in the direction of the outflow channel and with sensor elements for detecting the oscillation frequency of the free jet, characterized in that the impact body ( 3 ) about a perpendicular to the channel axis ( 10 ) lying axis of rotation ( 5 ) and is geometrically designed such that a pendulum movement can form through the free jet, and that the sensor elements detect the vibrations of the impact body ( 3 ). 2. Vibration beam counter according to claim 1, characterized in that the deflection of the impact body ( 3 ) by one or more stops ( 7 , 8 ) is limited on both sides. 3. oscillating jet counter according to claim 2, characterized in that the maximum angle of rotation through the design of the stops in one large area can be variably adapted to the sensor principle. 4. oscillating jet counter according to claim 2 or 3, characterized in that in the stops ( 7 , 8 ) sensors are integrated. 5. Vibration beam counter according to one of claims 1 to 4, characterized in that the impact body ( 3 ) is provided on its surface with a magnetization, which can be detected by a magnetic sensor. 6. oscillating jet counter according to one of claims 1 to 5, characterized records that the forced mechanical movement of the impact body the use of all the state of the art physi sensor principles for the detection of the oscillation frequency.   7. oscillating jet counter according to one of claims 1 to 6, characterized in that the impact body ( 3 ') in the end faces with concave recesses ( 14 , 15 ) is provided. 8. oscillating jet counter according to one of claims 1 to 7, characterized in that the impact body ( 3 ) on the outflow channel ( 4 ) facing back is provided with a leaf-shaped extension (flag 6 ). 9. oscillating jet counter according to one of claims 1 to 7, characterized in that the flow guide channel ( 2 ') including the one flow channel ( 1 ') and the outflow channel ( 4 ') to the transverse central plane ( 7 ) through the impact body ( 5 ') as well how it is symmetrical. 10. Vibration beam counter according to claim 9, characterized in that one or more stops ( 7 , 8 ) are arranged in symmetrical recesses ( 12 , 13 ) of the impact body ( 5 ).