DE2108410C3 - Paddle wheel flow meter - Google Patents

Description

The invention relates to a paddle wheel flow meter according to the preamble of claim 1.

Heretofore, an actuator rotor has been used in paddle wheel flow meters. In such devices is the

65 Rotor rotatable on one axis and at the same time axially displaceable. Therefore, at constant flow rates, the rotor is held in a stationary position between two fluid pressure bearings and there is no substantial abutment frictional pressure loss. Since the thrust bearings are wetted with liquid, there is no wear and tear and only low friction losses occur. Such known flow meters are shown and described in US patents 26 83 224, 27 09 366, 27 09 755, 30 91 964 and 32 38 776 (DE-AS 11 68 656).

From DE-OS 14 23 869 one knows a flow meter in which in a flow direction Conically widening shield channels are included, which connect to one in the direction of flow create a chamber located between the blade and the rotor.

From DE-AS 11 68 656 a flow meter is also known with two conical diffuser parts, in which holes to achieve a Pressure equalization is available, which secures the rotor against too close an approach to the bearing bracket.

If these known flow meters are used, for example, in a liquid with a viscosity of 1 When used in centipoise, they will have an error in the flow reading of ± 0.5% over a range of 10: 1 with a pressure drop of 0.55 to 1.65 bar. The error is substantial, the range is proportionate tight and the pressure drop is very high. The error limitation is of course a limitation of the measurement accuracy of the flow. The narrow area reduces the salting ability of the instrument. The high pressure drop requires excessive force to pump liquid through the meter. The area can only be expanded by overriding the flow meter. This in turn causes the Pressure drop becomes even greater. An expansion of the range can therefore only be achieved by increasing the force Pumping a liquid through the measuring instrument can be achieved.

The invention is based on the above-mentioned disadvantages of the prior art overcome. This task is given by the characterizing part of claim 1 Features solved. Advantageous further developments and refinements of the invention are set out in the subclaims marked.

It is an outstanding advantage of the invention that through the channel in the rotatable part of the rotor Accuracy over a linear range is further increased because of the flowing through the channel Liquid is angularly accelerated. This acceleration opposes the rotor with a resistance that increases the linearity of the instrument at lower flow rates. Furthermore, the resistance at high Reduced flow rates because the rotor moves close to the inflow diffuser and as a constriction in the River path works. This maintains the accuracy at high flow rates, because the through the Constriction-related pressure build-up on the inflow side of the rotor prevents the rotor from reaching the inflow side Touches the diffuser.

Another advantage of the invention is the reduction of the meter error to ½% over one Range of 15: 1 with a pressure drop of 0.27 bar with a liquid viscosity of, for example, 1

Centipoise. The error compared to the known flow meters is therefore reduced by 80% Area increased by 50% and, in the case of a larger area, the pressure drop by a factor of 50% decreased rather than increased

The measuring device also has only a small error when liquids with significantly higher or viscosities lower than water can be measured.

The invention is explained with reference to the figures of the drawing. It shows ι ο

F i g. 1 a longitudinal section through a flow meter,

F i g. 2 a spider-shaped bearing bracket, for mounting the rotor, from the end face seen,

3 shows a part of the rotor in an enlarged view and cut open,

4 shows another embodiment of the rotor in enlarged view and cut open,

Fig. 5 is a graph showing the working characteristics of flow meters,

F i g. 6 is a graph of the friction factor in relation to the Reynolds number;

F i g. 7, 8 and 9. Graphical representations of operating characteristics of known flow meters.

Description of the preferred embodiment

In Fig. 1, a flow meter 10 is shown, the has a tube 11 made of non-magnetic material, in which a rotor 12 is formed by spider-shaped Bearing bracket 13 and 14 is mounted.

The spider-shaped bearing supports 13 and 14 are identical. The bearing bracket 13 contains four Hollow cylinders 15 which are welded to one another and to a cylindrical axle bearing 16. Of the Bearing carrier 14 also has four hollow cylinders welded to one another and to a cylindrical axle bearing 18 17 on. The hollow cylinder 17 and the cylindrical axle bearing 18 are shown in FIG. 2 shown. Instead of four Hollow cylinders, only three hollow cylinders 15 and 17 can be used. The hollow cylinders 15 and 17 are made of spring material so that they are suitably enclosed inside the tube 11 by this.

Disks 19 are arranged at the opposite ends of the bearing brackets 13 and 14. An axle 20, which carries nuts 21 and 22 at its ends, leads through the entire arrangement. The nuts 21 and 22 are tightened so far that the axis 20 is always under tension. A zuflußseitiger Diffuso ^r 23 is pressed between the disks 19 against an outflow side diffuser 24th The diffuser 23 carries a bearing 25. the diffuser 24 has a bearing 26. A cylinder 27 is axially clamped between the bearings 25 and 26 and is thereby held in a fixed position on the axis 20. This means that the cylinder 27 is neither axially displaceable on the axis 20 nor rotatable. The rotor 12 is made essentially in one piece from metal. It contains a hub 28 to which blades 29 are attached. The hub 28 has a cylindrical extension 30 which slides in a cylindrical recess 31 of the diffuser 23. In the middle of the hub 28, a cylinder 32 is attached, which together with the fixed cylinder 27 forms a bearing. The cylinder 27 has a centrally arranged flat annular groove 33 on its circumference. The diffuser 23 is provided with a lip 34 projecting beyond the edge 35 of the hub 28. The diffuser 24 on the outflow side has an identical lip 36. The flow meter 10 described is completely symmetrical to a plane running perpendicular to the axis 20 through the center of the blades 29. Except for the blades 29, it is also rotationally symmetrical to the axis 20. Only the bore 37 through the hub 38 falls out of this symmetry in Fig. 3 is shown

In Fig. 3 it can also be seen that the cylinder 27 has end pieces 38 and 39

During operation of the flow meter 10, means are provided to prevent each vane from passing 29 indicate at one point or several points on the circumference of the tube 11. This can be known in and of itself Way to be done. For example, a magnetic tap can be used when the blades 29 are off consist of ferromagnetic material. In this case the number of pulses generated is proportional to the Speed of the liquid flowing through the tube 11 flows, or proportional to the flow rate.

Mode of action

In operation of the flow meter 10, the lip 34 causes pressure on the left side of the hub 28 drops below the pressure on the right side of the hub 28. This is because the pressure is in one plane transversely to the axis 20 at the location of the lip 34 is not uniform. The lip 34 causes a quick Increase in flow rate from left to right as shown in FIG. 1. If the If fluid reaches the right side of hub 28, the pressure has increased and is substantially uniform. However, the lip 30 can increase this pressure even further. At flow rates of zero and little above that, the rotor 12 moves to its rightmost position, even if the pressure is on the inflow side of the Hub 28 is less than on its right side. This is because at the hub 28 a sufficient Differential pressure occurs, which counteracts the high frictional resistance of the rotor 12. If the Flow increases, the pressure difference increases and the rotor 12 moves to the left, while the pressure on the right side rises. Without the bore 37, the hub 28 or the cylinder 32 would be the right end of the Touch diffuser 23 and cause flow meter to malfunction. The bore 37 allows however, that the increased pressure flows off to the right on the discharge side of the hub 28 through the bore 37 and prevents the hub 28 or cylinder 32 from abutting the diffuser 23 or bearing 25. the Rotational movement of the rotor 12 can be very large compared to the axial movement of the rotor 12 on the Cylinder 27. Axial movement of the rotor 12 on the cylinder 27 occurs only when the flow rate changes changes.

At lower flow rates, improved linearity is achieved in that the bore 37 incoming or outgoing water is angularly accelerated. This has an inhibiting effect on the rotor 12. At high Flow rates, however, maintain consistent accuracy because when the Hub 28 on the diffuser 23, the flow through the bore 37 is reduced. This reduction is coming due to the approach of the hub 28 to the diffuser 23. The liquid can then not escape so easily the bore 37 and flow out of the gap between the hub 28 and the diffuser 23. Hence there is little Accelerate liquid per unit of time at an angle. The flow rate through the bore 37 is due this restriction is reduced.

The rotor 12 or the hub 28 does not contact either the diffuser 23 or the diffuser 24. The fluid pressure bearings are designed for low abutment friction.

The approach 30 is adjacent to the surrounding cylindrical recess of the diffuser 23 Movement of the rotor 12 to the left thereby increases the flow of liquid between the diffuser 23 and the extension 30 further restricted and is proportional to the distance between the rotor 12 and the diffuser 23

Although the operation of the flow meter 10 with liquid flow from left to right in FIG F i g. 1 enables the essentially complete symmetry of the flow meter 10 also the use for flow measurements from right to left in Fig. 1.,

Either one bore 37 or a plurality of bores 37 can be provided as desired. in the illustrated case, only one hole 37 is used.

Other designs

In Fig. 4, a rotor 50 is rotatably mounted between the diffusers 51 and 52. The rotor 50 is integral with an axis 53 is formed which is supported in recesses in the diffusers 51,52. The axis 53 and the rotor 50 runs through a channel 54.

The operation of the flow meter according to the invention is explained below.

In Fig. 5 is a graph of the operating characteristics of a known flow meter denoted at 55. Another flow meter characteristic curve is denoted by 56. Curve 56 pertains to the flow meter according to the present invention. The revolutions per unit volume are plotted on the ordinate R. On the abscissa Q is the flow rate in volume per unit of time, e.g. B. gallons per minute applied. A horizontal straight line 57 is drawn in and would represent the ideal curve for any flow meter. This curve shows that there is absolutely no error in the flow meter in the measurement. However, it must be pointed out that the value of R at the level of the straight line 57 is not equal to zero.

The straight lines 58 and 59 limit the desired permissible error.

It should be noted that the curves 55 and 56 run almost the same except for a certain area which is slightly larger than the distance B \.

The curve 55 has a bulge 60 which extends beyond the desired error tolerances The bulge 60 is caused by a phenomenon which is shown on the basis of a curve 61 in FIG. 6 are explained can.

In Fig. 5 / is the friction factor and, Vs is the Reynolds number. The curve 61 has a region A of a laminar flow, an area B, of a transitional flow and a region C of a turbulent flow corresponds to the areas A, B and C are obtained by dividing the positive abscissa by the lines 62 and 63 educated

/ v _Ä -

is there

ο = density
V = speed
D = pipe diameter and
u = viscosity

For a given liquid wedge and a given pipe diameter, ρ, D and μ are constant. Hence, Nr increases with V. Increasing V therefore causes / in area A to fall because V increases with Nr.

The resistance F at the rotor of the flow meter is represented by the equation

F = K _r

where Kp is a function of F and g is the acceleration due to gravity.

Therefore, Ka decreases as / decreases and V and Nr increase in area A. The reduced resistance causes an increased rotor speed and thus the bulge 60 in curve 55. The areas A ', B' and C in FIG. 5 correspond to the areas A and ßbzw. Cin Fi g. 6th

The liquid flowing through the bore 37 is angularly accelerated. This creates a drag on the rotor 28. The drag reduces the rotor speed up to curve 56 in FIG. 5. At high values of Q , there is no decrease in speed on curve 56 because rotor 28 moves close to diffuser 23 when it is rotating at high speed and the main flow is from left to right in FIG. 1 runs. The liquid in the bore 37 can then not so easily emerge radially between the rotor 28 and the diffuser 23 because of the narrowing provided. This constriction is generated by the rotor 28, which moves very close to the diffuser 23

In the F i g. 7, 8 and 9 are curves 62 and 63 and 64, respectively shown. The curve 62 corresponds to the curve 55 for water. The curve 63 corresponds to a liquid with a lower viscosity and also lower density than water. The curve 64 corresponds to a Liquid with a much higher viscosity and lower density than water.

The flow meter according to FIG. 1 is essentially a universal measuring device that means that it is suitable for Measuring liquids can be used with viscosities that change over a wide range. This is to be attributed to the fact that many liquids with a viscosity different from that of water have a have a lower density than water. When these fluids flow through the bore 37, will due to the acceleration of the liquid, the rotor 28 is not exposed to so great a resistance in this Fall is only a small amount in the bore 37 at any one time.

Another compensation factor is that with very high viscosities the flow through the bore 37 takes place more slowly and the area in which from Rotor 28 energy is transferred to the liquid in the bore 37, is smaller than in the case of low viscosities. Hence the resistance is low.

Both factors - low density and high viscosity - make the device according to the present invention unusually useful for a wide range of viscosities. Through the invention causes the bulge at the lower speed end of the Curve 62 drops to a more precise level. However, the invention does not cause the curves to drop 63 or 64.

It should be noted that the flow meter according to the

present invention has less error over a larger linear range because the Curve 56 in Fig. 5 is the internal flow meter diagram from a point 65 on between the straight lines 58 and 59 drop off.

The measuring range is widened towards small flow ranges. For example, the area of the curve "5 ¹ I is approximate

C "
A ' I Ii'

= 12: 7 = 1.7: 1

then the area of curve 56 is approximately

Ii ' I

A '

= 17: 2 = 8.5: 1.

An improvement at lower flow rates causes a tremendous increase in the linear range. If the range is initially 10: 1, there will be a five percent increase in the range at the lower end an area ratio of 20: I.

For this purpose .1 drawings are available

Claims (6)

Patent claims: 1. Paddle wheel flow meter, with a rotor having an axial play, each with a diffuser on both sides of the same, the outside diameter of which increases or decreases in the direction of flow, and in The vicinity of the rotor is at least as large as the diameter of its hub and that of its The end face facing the rotor hub each delimit an intermediate space in which one line each flows out to influence the static pressure on both sides of the rotor hub, characterized in that that these pressure equalization lines of one the two spaces connecting channel (37, 54) are formed, which runs completely within the rotor (12) and opens into the spaces within the edge (35) of the rotor hub (28). 2. Flow meter according to claim 1, characterized in that the channel (37) is eccentric extends to the central axis through the rotor hub (28) (Fig. 3). 3. Flow meter according to claim 2, characterized in that the diffuser (23) at its end adjacent to the rotor (12) has a circumferentially extending, radially outwardly projecting lip (34), the outer diameter of which is greater than that of the rotor hub (28), that the middle part of the rotor hub (28) is longer than its outer part and has a projection (30) which is displaceable in contact with the diffuser (23) in the same, that the diffuser (23) has a cylindrical recess which the projection ( 30) receives that the rotor hub (28) has a cylindrical bore, that an axis (20) fixed in relation to the diffuser (23) penetrates the bore and the rotor hub (28) is rotatably and axially slidably mounted on this axis (20) that the axis (20) has grooves corresponding to the fluid flow between the axle (20) and bore allow that a central part of the axle (20) has a smaller diameter than ao their ends provided with three spiral grooves s ind, and that the outer part of the rotor hub (28) has a longitudinal bore as a channel (37) which extends at a certain distance from the outer diameter of the rotor hub (28). 4. Flow meter according to claim 1, characterized in that the rotor (50) on its axis (53) is attached and the channel (54) is provided in the axis (53) (Fig. 4). 5. Flow meter according to claim 2, characterized in that the rotor (12) has a pierced one Has rotor hub (28), the bore of which is provided with a hollow cylinder (27), and that one Axis (20) penetrates the diffusers (23, 24) and the cylinder (27). 6. Flow meter according to claim 5, characterized in that the axis (20) at both ends is provided with a thread and a nut (21,22) at each end of the axis (20) the diffusers (23,24) press firmly against the cylinder (27) so that it cannot twist.