FR2506932A1 - Electronic gas flowmeter e.g. for water treatment plant - has permanent magnet unitary with rotating element and Hall sensor giving periodic signal related of rotation speed - Google Patents

Abstract

The flowmeter contains a permanent magnet (3) fixed to the rotary component (1). A Hall effect sensor (4) is placed such that it is sensitive to the magnetic field created by the magnet (3). This sensor (4) produces an output signal whose frequency corresponds to the magnet's rotation speed. The sensor (4) is pref. part of an integrated circuit which delivers pulses at the above frequency. The output signal can then be input to a frequency-to-current converter connected to an analogue display. It can also be input to a counter connected to a digital display. The counter includes a programmable frequency dividing circuit. The device can be used to measure the flow of gas evolving deposits in water treatment plants.

Description

 The present invention relates to an electronic flow meter of the type comprising a rotary element, designed to facilitate the measurement of the flow rate of a liquid or gaseous fluid, in particular but not exclusively, in explosive or corrosive environments.

We know that in known flowmeters using a rotary element such as a propeller or a turbine, mounted across the flow of a fluid whose flow is sought to measure, the fluid flow is substantially proportional to the speed of rotation of the rotary element, to the sliding of the layers of fluid on the blades of the element close. With correct calibration, the measurement of the flow therefore boils down to a measurement of the speed of rotation of the rotary element. Several techniques for carrying out this measurement have already been proposed; we can quote
- flowmeters with mechanical transmission, in which the rotational movement of the rotary element is transmitted to a tachometer via pinions
- flow meters with electromagnetic induction transmission, in which an inductor integral with the rotary element induces a flow in a stator
- optoelectronic transmission flowmeters, in which light emitters are integral with the rotary element, cooperating receivers being fixed inside the pipeline.

 These known flow meters have drawbacks which prohibit proper operation in explosive and / or corrosive fluids. They mainly raise problems of fouling, space and safety.

When the transmission of the movement is mechanical, the transmission members corrode quickly and it is of course difficult to provide the lubrication necessary for precise operation.

Electromagnetic deb9neters working in alternating current are subject to noise, and the obligation to shield the electrical windings increases their weight and size. In addition, the induced currents are low, so that power amplification is necessary. Finally, any magnetic transmission borrows energy from the rotary element, which adversely affects the accuracy of the measurement, especially in the case of low flow rates. With regard to optoelectronic transmission flowmeters, the transmitting or receiving cells are subject to fouling which rapidly alters their transmission characteristics and, on the other hand, their supply poses safety problems in an explosive atmosphere when their supply is performed in situ, or amplification problems otherwise.

 The present invention overcomes these drawbacks by virtue of a flowmeter with rotary element and electronic transmission, of precise and reliable operation, allowing the measurement of any fluid flow rates and meeting in particular the intrinsic safety standards imposed on flowmeters intended to operate in corrosive or explosive atmosphere.

 The subject of the invention is therefore a flowmeter with a rotary element characterized in that it comprises a permanent magnet secured to the rotary element, a Hall effect sensor arranged to be sensitive to the magnetic field created by the magnet and thus provide a periodic frequency output signal corresponding to the speed of rotation of the magnet.

 Preferably, the sensor is a flow meter, characterized in that the sensor is included in an integrated circuit delivering pulses at said frequency in the output signal of the sensor. This also has the advantage of making it possible to obtain an indication of the flow rate directly in digital form, by counting the pulses present in the output signal of the sensor.

 In practice, the rotary element generally comprises a shaft in the axis of a drive part in the form of a propeller or turbine in particular, and the magnet is mounted perpendicularly on the shaft. Such an element is generally rotatably mounted in bearings carrying the shaft inside a section of pipeline intended to guide the circulation of the fluid whose flow rate is sought, the shaft being disposed longitudinally along the axis of the pipeline and the drive part across the traffic. The Hall effect sensor is then advantageously mounted on the internal face of the pipeline, at the same level of cross section as the magnet, while it is electrically connected to a device external to the pipeline comprising the supply circuits and electronic processing of the output signal.

 Thus designed, the flow meter according to the invention has very high operating safety, even for a fouling or corrosive fluid, and there is no risk that an electrical spark will cause an explosion. In addition, it is compact, and since the Hall effect sensor requires only a very low current, in direct current, the energy consumption is low. The assembly with the electronic signal processing circuits, lends itself well to a battery supply.

 The transmission of the "rotational speed" information of the rotary element, proportional to the flow rate, is carried out electronically, the variation of the magnetic field generated by the magnet causing in the sensor a variation of the resistance of an element. sensitive to semiconductor which results in the output signal. The variation occurs at each turn of the magnet, therefore of the drive part of the rotary element, so that the or / sensor provides a periodic / pulse signal whose frequency is equal to the speed of rotation of the rotating element (in number of revolutions per unit of time), and therefore proportional to the flow rate.The output signal from the Hall effect sensor can be processed in analog mode to display the measurement results by a device with a mobile indicator in front a scale previously calibrated, in combination or not with a directly digital processing where said output signal is applied to the input of a circuit for counting its pulses, advantageously comprising a programmable frequency divider, the division rate of which can be set according to the preexisting relationship between the frequency of the pulses in the signal and an arbitrary 3 unit flow (1 m / h for example) and a cumulative flow count.

Other characteristics and advantages of the invention will appear during the description which follows of a particular embodiment, given solely by way of nonlimiting example, with reference to the figures which represent
- Figure 1 a diagram of a Hall effect sensor flow meter according to the invention
- Figure 2, an electrical diagram for mounting the Hall effect sensor
- Figure 3, an electrical diagram of an analog measurement circuit of the instantaneous flow
- Figure 4, an electrical diagram of a flow totalizer counting circuit.

 In Figure 1, the flow meter, mounted in a pipe C, comprises a propeller 1, arranged perpendicular to the direction of flow of the fluid, symbolized by the arrow F, 'whose flow is to be measured. This propeller is driven in rotation by the fluid, at the same time as a shaft 2, which is integral with the propeller along its axis and mounted on bearings in the pipeline, and on which a permanent magnet is fixed radially 3. The speed of rotation of the assembly is directly proportional to the fluid flow. An integrated circuit forming a Hall effect sensor 4, molded from an electrically neutral and insulating material, is fixed on the same support as the bearings the shaft 2, in the vicinity of the rotation path of the magnet 3. Thus, the poles of the magnet 3 are presented successively in front of the Hall sensor 4. This sensor comprises, as known per se, an element sensitive to the magnetic field which consists of a wafer of semiconductor material excited in direct current and the resistance variations of which are detected under the effect of the magnetic field, in a signal which is applied to the base of an amplifier transistor translating these variations in the form of pulses in the output signal. Such an integrated circuit sensor can be, for example, of the type sold under the reference "TL 170C" by the company TEXAS INSTRUMENTS. In this particular case, the passage of the blades of the magnet 3 causes the appearance on the output terminal 1 of a pulse sensor whose amplitude is 5 volts.

 A permanent magnet 3 of small dimensions does not significantly disturb the flow of the fluid.

However, it is of course possible to integrate it into the propeller or into the turbine itself. I1 is formed in the form of an elongated cylindrical bar, so that the distance between: the poles of the magnet and the sensor is relatively small. The sensor 4 is electrically connected, through the wall of the pipe, to a circuit 5 for supplying and electronic processing of the signal from the sensor, which will be described below with reference to FIGS. 2, 3 and 4.

 In FIG. 2, the sensor 4 is supplied by a stabilized voltage source 21, for example of 24 volts, through a ballast resistor 8, a Zener diode 6 being connected in parallel to the source 21 with a polarized filtering capacitor 7 A DC voltage, stabilized and filtered, is thus available across the diode 6, and this voltage can be used to supply a certain number of C-MOS circuits which will be described later.

The output signal from the sensor 4 is routed on two terminals 30 and 40 connected respectively to a circuit for measuring the instantaneous flow rate and to a circuit for counting the flows accumulated by totaling the pulses.

 FIG. 3 represents the instantaneous flow measurement circuit by a galvanometer 11, previously calibrated. The input signal from terminal 30 is routed on a frequency-current converter 12 of the C-MOS type, such as that designated commercially under the reference LM 2917.

The desired polarizations are obtained at the input by a resistor 22 in shunt, and on the other hand, by two dividing bridges 9 and 10, equipped with adjustment potentiometers, which make it possible to obtain the adjustment of 0S and 100%, values which correspond, for example, to 4 and 20mA respectively.

The galvanometer 11 can be graduated directly in flow units or be replaced by any display device, using iodine or liquid crystal.

FIG. 4 represents the totalizing circuit, making it possible to know the accumulated flow rates. Its purpose is to count the number of pulses, which corresponds to a number of propeller rotations, and consequently the flow of a determined volume of fluid. The signal applied to terminal 40 is the output signal from sensor 4. The switches from sensor 4 are very fast. This is why a frequency division is carried out in stages 13 and 14, constituted by programmable 8-bit dividers of the type
CD 40103B, for example. The input signal is also limited in current thanks to a series resistor 23, and its oscillations are damped by capacitors not shown. The division factor of the two stages 13 and 14, depending on the relationship between flow and speed of rotation (known by construction or determined by calibration), so that at the output of the divider 14, one pulse is obtained per unit of volume, the unit volume being arbitrary, for example lm3. These pulses are negative and they are too short to command a relay. Also, the divider 14 is followed by a monostable 15 which fixes, by an RC circuit, the time constant at approximately two seconds, which makes it possible to control an output transistor 17 in the collector circuit of which is connected a relay 18 which - even controls a counter 19, the latter therefore counts the number of volume units delivered. The base of transistor 17 is connected to the output of monostablel5 by a resistor 16 and relay 18 is for example a REED mercury relay.

 In a particular application, using a propeller flow meter, an apparatus according to the invention has been produced for measuring the flow of gases from the digestion of sludge in a water treatment station. A miniature cylindrical magnet 3mm in diameter and 10mm in length was mounted on the propeller shaft and radially to it. An integrated circuit forming a Hall effect sensor has been placed inside the pipeline so that this sensor is 5 mm from the path of the magnet poles.

3
When the gas flow rate is 1,000 m / h (in real volume, including pressure drops) the turbine rotates at 8,800 rpm.

Under these conditions, the Hall sensor emits 533 pulses
3 per m. The pulses are routed on dividers set to divide the frequency by 41, then by 13, in order to finally obtain a pulse at the output of the dividers for 533 pulses from sensor 4. These are therefore pulses at the rate of a pulse for lm which are recorded in the counter 19, which therefore indicates a volume in number of cubic meters. The instantaneous flow measurement is obtained from the same sensor output signal by frequency-current conversion using a C-MOS circuit.

It would of course be possible to use instantaneous measurements to obtain, by integration, the cumulative flow rate of the fluid in the pipeline.

 Many variants can be introduced, in particular by substitution of equivalent technical means, without departing from the scope of the present invention.

Claims (7)

 1. Flow meter with rotary element, characterized in that it comprises a permanent magnet (3) integral with the rotary element (1) and a Hall effect sensor (4) arranged to be sensitive to the magnetic field created by the magnet (3) and thus provide a periodic output signal of frequency corresponding to the speed of rotation of the magnet.  2. Flow meter according to claim 1, characterized in that the sensor (4) is included in an integrated circuit delivering pulses at said frequency in the sensor output signal.  3. Flow meter according to claim 1, characterized in that it comprises a frequency-current converter (12), receiving the output signal from the sensor (4), the output of the converter (12) being connected to a display device analog of the measured flow (11).  4. A flow meter according to claim 1, 2 or 3, characterized in that it comprises a pulse counting circuit (13, 14, 15) receiving the output signal from the sensor (4) to provide an indication of flow by pulse totalization.  5. Flow meter according to claim 4, characterized in that the counting circuit comprises a frequency divider assembly (13, 14) with programmable division rate as a function of a preexisting relationship between the frequency of the pulses in the signal and a flow rate unitary.  6. Flow meter according to claim 5, characterized in that it comprises, after the frequency divider, a counter (19) of the unit flows.  7. Flow meter according to any one of claims 1 to 6, characterized in that the rotary element and the sensor are mounted on the same support inside a pipe section (C), the rotary element comprising a drive part with a fluid mounted across said pipe section.