DE3018788A1 - Flowmeter for measuring low liquids flow rates - uses restricted inlet cross=section of body displacement annulus - Google Patents

Abstract

The flowmeter, pref. for liquids, has an annular channel in a sealed housing. The liquid enters the channel via a tangential inlet (15), drives rounded bodies (17), pref. spheres, part a measurement point, and leaves via an outlet (16). The arrangement has an inlet of relatively narrow cross-section compared to the channel and outlet so as to produce more acceleration of the spherical bodies at the sensor (19) position and thus enable smaller flow rates to be measured than with conventional arrangements. The outlet (16) is also tangential to the channel (14). The specific wt. of the rounded bodies (17) is approximately equal to that of the liquid in the annular channel. The inlet is in the form of a nozzle whose cross-section is no more than half that of the outlet.

Description

Flow meter, preferably for liquids

PRIOR ART The invention is based on a through-flow esser according to the genre of the main claim. Such a known flow meter has one round chamber with a tangential inlet opening and one in the longitudinal axis The discharge opening lying in the chamber (DE-PS 22 5: 81) For measuring the flow rate a ball is arranged in the chamber, which is guided in an annular channel and is carried along by the fluid whose flow rate is to be measured. The ball rotates within the chamber. However, this solution has the disadvantage that with smaller flow rates the ball rotates too slowly to be able to with sufficient Accuracy of electrical signals for determining the flow rate at a measuring point generate in the chamber. In addition, the speed of rotation depends on the weight of the Ball dependent. The flow meter can therefore only be used in a certain are preferably arranged in the horizontal position of the ring channel.

Advantages of the Invention The flow meter according to the invention with the characterizing features of the main claim has the advantage that by which is relative to the cross section of the annular channel and the outflow opening narrow inflow opening an increased flow of liquid in the annular channel in front of the outflow opening is generated, which the encircling round body, preferably a ball, for Accelerated outflow opening. This acceleration can also be used for generate evaluable signals at the measuring point. In addition, several round bodies in the form of Place balls in the ring channel so that the number of pulses per unit of time increases can be. In this way, with small flow rates with the invention Flow meter determined quite accurate values, so that the flow meter in more advantageous Way to be used to measure the gasoline consumption of a motor vehicle can.

The measures listed in the subclaims are advantageous Further developments and improvements to the features specified in the main claim are possible. It is particularly advantageous if the round body is almost the same specific Weight like the liquid in the annular channel, so that the flow meter in each Mounting position gives the same measured values. To accelerate the balls in the ring channel in the In the area of the measuring point, it is advantageous if the inflow opening is designed as a nozzle is.

Exemplary embodiments of the invention are shown in the drawing and explained in more detail in the following description. It shows Fig. 1 shows the flow meter according to the invention in cross section, FIG. 2 shows a section through the flow meter along the line II-II from Fig. 1, Fig. 3 shows a section of the flow meter along the line III-III from Fig. 1 with one of a metal layer surrounding sphere and Fig. 4 shows the cross section through a flow meter with a Wiegand module at the measuring point.

Description of the exemplary embodiment The illustrated in the drawing, The flow meter designated by 10 is used to determine fuel consumption of a vehicle. It can be used for both diesel fuel and gasoline. The flow meter 10 has a housing 11 with an inlet connection 12 and an outlet connection 13 for the fuel line, not shown.

In the housing 11 there is an annular channel 114 into which the fuel enters can enter through a tangential inflow opening 15. It is also on the ring canal 14, an outflow opening 16 is provided through which the fuel again flows out of the annular channel 14 exits. In the annular channel 14 there are several evenly distributed balls 17, which are driven by the flow of fuel in the annular channel 14. the Balls 17 move with each revolution past a measuring point, which consists of a Light source 18, for example a light emitting diode on one side of the ring channel 14 and a photosensitive element 19 such as a photodiode on the opposite Side of the ring channel 14 consists. When passing through the measuring point, the balls generate 17 in the photodiode 19 electrical signals in a not shown Evaluation circuit to determine the fuel flow rate as a function of time (idle consumption) or depending on the speed of the vehicle (load consumption in l / kmh) are processed.

In order to achieve a sufficiently accurate, even with very small flow rates To obtain a measured value, the balls 17 in the area of the measuring point 18/19 are thereby accelerated that the outflow opening 16 tangentially in the direction of rotation of the balls 17 leads away from the ring channel 14, which is closed on all sides, and in its cross section is at least twice as large as the inflow opening 15.

The cross section of the inflow opening 15 is also considerably smaller than that of the annular channel 14 Fuel at the narrow inflow opening 15 at a relatively high speed v1 into the annular channel 14 and meets there at regular intervals on one of the circumferential Balls 17. The ball 17 is accelerated and moved past the measuring point 18, 19 then arrives at the outflow opening at a lower outflow velocity v2 16. There it is on a web 20 arranged in the outflow opening 16 in the circumferential direction of the ring channel 14- continued. At a relatively slow speed, v3 becomes now the ball 17 is moved further in the annular channel 14 until it is again in front of the inflow opening 15 arrives and is accelerated. This process is repeated for each of the balls 17 with each full circulation. Due to the different flow velocities of the Fuel in the annular channel 14 ensures that the balls 17 of the Move the inflow opening 15 to the outflow opening 16 faster than in the further Circulation from the outflow opening 16 back to the inflow opening 15. So that the ball 17 are not additionally accelerated or decelerated by their own weight, is the specific gravity of the balls 17 is almost the same as that of the fuel in the ring channel 114.

To a relatively high speed vl of the fuel at the inflow opening 15, this inflow opening is designed as a nozzle 21. The pressure drops in the fuel line by inserting the flow meter 10 will be small held when inflow opening 15 and outflow opening 16 in the direction of rotation of the balls 17 on the annular channel 14 are not more than 90 degrees apart. It is the measuring point located between the inflow and outflow opening 18, 19 close to the Inflow opening 15 arranged. Good flow conditions and one accordingly low pressure loss in the flow meter 11 results from the inflow opening 15 and the outflow opening 16 lie on an axis 22. It is useful to to arrange the flow meter 10 so that the annular channel 14 in a more or less perpendicular plane and that the inflow and outflow openings 15, 16 in the upper area of the annular channel 14 are arranged. This ensures that there is in the flow meter no air bubbles can collect or that such air bubbles when starting the internal combustion engine are immediately discharged again through the outflow opening 16.

If there is a high number of balls in the lower area of the Ring channel should be close together, it is proposed that the balls 17 are alternately translucent and opaque. Be that way at the measuring point 18, 19 through the opaque balls even at high flow velocities Pulses generated with sufficient time interval. To also ensure that the fuel still passes through the flow meter 10 even if a the balls 17 is blocked in the ring channel 14, the ring channel 14, as Fig. 3 shows, a rectangular, preferably auadratic one Cross section, whose clear height H is slightly larger than the diameter of the balls 17. Such a ring channel 14 can be produced in a simple manner from two housing halves 11a and 11b. As FIG. 2 shows, the housing 11 is divided in the upper plane of the annular channel 14. The two disc-shaped housing halves 11a and 11b are provided with an elastic Seal 23 assembled. By compressing the seal 23 more or less is, the cross section of the annular channel 14 and thus the time for the circulation of the balls 17 change. This makes it possible to set the flow meter 10 so that that the measured value determined with it with the actual flow rate of the fuel matches. Another calibration option is by changing the inlet nozzle cross-section given.

When choosing the balls 17, it is important to ensure that the specific weight of the finished balls is approximately the specific weight of the corresponds to the liquid to be measured. Balls 17 are particularly suitable for this purpose. which consist of a plastic material that contains air pockets. However, it is necessary that such spheres do not swell and also do not absorb any liquid, otherwise the specific weight of the balls will be changed. For fuel consumption meters balls 17a are therefore proposed which, according to FIG. 3, consist of a foamed inside Plastic material 24 and externally with a metal jacket 25, e.g. made of nickel are provided. The metal jacket 25 is applied by electroplating; he does one smooth spherical surface, is resistant to fuel and its additives and he prevents fuel from entering the ball.

In Fig. 4 is the cross section through a flow meter according to the invention shown with a so-called Wiegand module 26 at the measuring point. The Wiegand module 26 consists of a Wiegand wire 27 on which a coil 28 is arranged.

By a weak permanent magnet 29 next to the Wiegand module 26 the Wiegand wire 27 is premagnetized. The Wiegand module 26 is due to this bias set.

A second,. stronger permanent magnet 30 is located on the Wiegand module 26 opposite side of the annular channel 14. Its magnetic field penetrates the rod 27 in the opposite direction and thus resets the Wiegand module 26. Got there now a ball 17a to the measuring point, which has a metal jacket 25 or in the one If soft magnetic material is embedded, part of the magnetic field is from the permanent magnet 30 diverted through this ball 17a and the Wiegand module is set again. With When leaving the measuring point, the Wiegand module is reset again. To this The number of balls 17a passing the measuring point can be detected and evaluated will. To prevent the ball from passing through the measuring point is noticeably delayed, the metal jacket 25 is very thin and the magnetic field of the Permanent magnets 29 and 30 to choose weak.

The invention is not limited to the illustrated embodiments limited, as details can optionally be changed as appropriate. So it is possible, instead of a rectangular cross section of the annular channel 14 To choose a circular cross-section, the diameter of the ring channel then slightly larger than the ball diameter must be. With a rectangular cross-section of the ring channel but rollers can also be used instead of balls for the determination circulate the flow rate in the annular channel 114. Of course you can with the flow meter described the respective flow rate of others Determine liquids in the same way. In principle it is also possible in the same Way to measure gas quantities. In this case the balls or rollers need one have a specific weight corresponding to the respective gas (evacuated spheres), this ensures that the balls do not sink down in the ring channel, instead, driven by the gas flowing through, they circulate in the ring channel. For fuel consumption measurement are foamed plastic balls made of ABS, galvanized with a metal layer (Acrylonitrile butadiene styrene), PPO (polyphenyloxide), PP (polypropylene) or PA6 (Polyamide 6). As shown in FIG. 1, the measuring point can be perpendicular to the annular channel 17, but it can just as well lie horizontally. In any case electrical impulses are generated when the balls pass through the measuring point, which be forwarded to an electronic evaluation circuit. The flow rate can be determined here by counting the pulses. Through the pulse train (frequency) the flow rate per unit of time, for example the idle consumption of a motor vehicle in liters per hour and by comparing the Pulse sequence with the speed of a motor vehicle can be the respective Determine fuel consumption in liters per 100 km. The passage of the balls on the measuring point can also be detected by known inductive sensors. Balls with a metal shaft are particularly suitable for this. It can for that but balls containing iron filings or ferrites can also be used.

It is essential to the invention in all alternative solutions that each im Annular channel encircling ball in the area of the measuring point through the one at the inflow opening Medium reaching the ring channel is accelerated, so that too at very small flow rates a sufficiently strong electrical impulse for a digital evaluation can be generated. The acceleration of the balls in the The area of the measuring point is also prevented from abutting several Balls get to the measuring point, otherwise the pulses generated there may be would be distorted. With the flow meter according to the invention can be through accordingly selected distances of the balls with a ball diameter of about 5 mm with a high linearity measure flow rates from 0.5 l / h to 80 l / h.

Claims (1)

Claims flow meter, preferably for liquids, with a in a closed housing located annular channel in which the liquid enters through a tangential inflow opening and exits through an outflow opening, as well as with at least one round body driven by the flow in the ring channel, which moves with each circulation to one in the ring channel between the inflow and outflow opening lying measuring point moved past for generating a measuring signal, characterized in that, that the outflow opening (16) is tangential in the direction of rotation of the round body (17) leads away from the ring channel (14), which is closed on all sides, and has a larger cross section than the inflow opening (15). -2. Flow meter according to claim 1, characterized in that all round bodies (l7) located in the annular channel (14) have almost the same specific Have the same weight as the liquid in the annular channel (14). 3. Flow meter according to claim 2 characterized in that the Inflow opening (15) is designed as a nozzle (21), the cross section of which is substantial smaller than that of the annular channel (14) and at most half the size of that of the outflow opening (16) is. 14. Flow meter according to claim 1, characterized in that in the outflow opening (16) has a web (20) arranged in the circumferential direction of the annular channel (14) is. 5. Flow meter according to claim 1, characterized in that the outflow opening (15) and inflow opening (16) in the direction of rotation of the round body (17) on the circumference of the ring channel (14) are not more than 90 degrees apart. 6. Flow meter according to claim 5, characterized in that the inflow opening (15) and outflow opening (16) lie on an axis (22). 7. Flow meter according to claim 6, characterized in that the Annular channel (14) lies in an approximately vertical plane and that the inflow and outflow openings (15, 16) are arranged in the upper region of the annular channel (14). 8. Flow meter according to claim 1, characterized in that the Measuring point (18, 19) between the inflow and outflow opening (15, 16) close to the Inflow opening (15) is arranged. 9. Flow meter according to claim 1, characterized in that as round body several balls (17) arranged at a distance from one another in the annular channel (14) are. 10. Flow meter according to claim 9, characterized in that the Balls (17) are alternately translucent and opaque. 11. Flow meter according to claim 9, characterized in that the Balls (17) consist of a plastic material which contains air pockets. 12. Flow meter according to claim 11, characterized in that the balls (17a) consist of a foamed plastic material (24) inside and are provided on the outside with a metal jacket (25). 13. Flow meter according to claim 1, characterized in that the Annular channel (14) has a rectangular, preferably square cross-section, the clear height (H) is slightly larger than the diameter of the round body (17, 17a). 14. Flow meter according to claim 13, characterized in that the housing (11) consists of two, in the plane of the annular channel (14) with an elastic Seal (23) assembled disc-shaped halves (lla, llb) consists. 15. Flow meter according to claim 14, characterized in that To adjust the flow meter, the seal (23) is more or less compressed is. 16. Flow meter according to claim 1, characterized in that on the measuring point on one side of the ring channel (14) a Wiegand module (26) with a weak magnet (29) and on the opposite side of the ring channel stronger permanent magnet (30) of opposite polarity is arranged.