CH639198A5 - Flow meter for liquid and gaseous media - Google Patents

Description

The invention relates to a flow rate measuring device for liquid and gaseous media, with a guide body which surrounds a cavity on all sides and is made of non-ferromagnetic material and which has an inlet and an outlet opening for the medium at a distance from one another and a control slide arranged between these openings, which slide valve is at least partially consists of ferromagnetic material and which can be displaced towards the inlet opening by a force acting counter to the flow and through the flow towards the outlet opening and with at least one field coil arranged on the circumference of the guide body in the direction of movement of the control slide, which is connected in an electrical circuit and with a display device connected is.

Several flow rate measuring devices of the type described in the introduction have become known.

For example, there is a flow meter that has a floating body inside a guide member. The control-effective piston of the device arranged in the vertical position remains in the rest position in a cylindrical part which has the inlet opening for the medium. At the end of the piston directed towards the top outlet opening of the guide member, the cylindrical part widens uniformly conically and ends at the outlet opening, which has a small cross section.

The piston is also conical, but its cone angle is larger than that of the conically widening part of the guide member.

At the bottom, the float consists of a connecting part and a ferromagnetic sleeve, which are connected to the piston in this order. Of course, the floating body is supported in the rest position on a screw connection forming the bottom of the guide member.

Immediately above the ferromagnetic sleeve, the guide member has on the circumference a field coil coaxial with the axis of displacement of the floating body, the length of which corresponds approximately to that of the ferromagnetic sleeve. The field coil is connected to a bridge circuit, which is fed by an electrical generator.

Flow rate measuring devices of this type have the disadvantages that the lateral inlet opening in the control-effective area of the guide element creates a great deal of turbulence, which impairs the measurement results. In addition, the described embodiment takes up a relatively large amount of space, which makes installation in existing systems particularly difficult in the vertical direction. At the same time, the production of such a device is relatively complex and expensive due to the diverse parts.

The object of the invention is therefore to remedy the evils described and to create a flow rate measuring device which is suitable for dynamic measuring processes, provides a measurement result which is independent of the viscosity of the flow medium and which, due to its compact design, takes up little space.

The flow rate measuring device of the type mentioned at the outset is characterized in that the

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Control spool and the interior of the guide body in their control-effective area dependent on the fluid flow have a conical shape tapering parallel to the inlet opening and that a part of the control spool formed of ferromagnetic material is at least partially in the field coil arranged on the guide body when flowing through the medium.

In an advantageous embodiment, the control slide is formed in its entirety from ferromagnetic material. 10th

Further embodiments of the invention are discussed in more detail in the following description.

Details and mode of operation of the invention are explained, for example, with reference to the following description and the drawing. It shows: 15

1 shows a longitudinal section through a flow meter.

FIG. 2 shows the control slide in a stereometric representation according to FIG. 1.

FIG. 3 shows a longitudinal section through a further embodiment of a flow rate measuring device.

4 shows a longitudinal section through a further embodiment of a flow rate measuring device.

5 shows a cross section through a flow rate measuring device along the line V-V in FIG. 4. 25

6 shows a longitudinal section through a further embodiment of a flow rate measuring device.

7 shows a cross section through a flow rate measuring device along the line VII-VII in FIG. 6.

A flow meter for 30 liquid and gaseous media designated by 1 according to FIG. 1 has a guide body 2 made of non-ferromagnetic material, which has an inlet 3 and outlet opening 4 for the medium and a control slide 5 arranged between these openings. The inlet line 6 is formed from a tubular connection piece 7 which is connected to the pressure line of a pump via a hose (not shown).

The inlet line 6 opens into the control chamber 8, which widens conically 40 into a cylindrical chamber 9 in the direction of flow of the medium. The outlet line 10, which consists of a removable cylindrical outlet connection 11, to which a hose for connecting the medium 45 is connected, connects directly to the cylindrical space 9 of the control chamber 8. The outlet port is held in place by the screw indicated by dash-dotted lines 15. An annular groove 12 with a sealing ring 13 seals the control chamber 8 against a leak. A field coil 14 is attached to the circumference of the guide body 2, preferably in the area of the conical control chamber 8. For this purpose, a shoulder 6 is provided on the guide body 2, on the basis of which the field coil 14 can be positioned precisely in the longitudinal direction. The field coil is in turn protected by a protective sleeve 22 made of plastic or another, preferably insulating material, 55 from external influences. The sleeve can be fastened to the circumference of the shoulder 16 by means of screws 17 (shown as dash-dotted lines in FIG. 1).

The control spool 5 made of ferromagnetic material has a conical shape parallel to the control chamber 8, so that 60 in the event of flow interruption, the outer surfaces of the control chamber 8 and the control spool 5 fit tightly. When using the flow rate measuring device in the vertical position shown, the dead weight of the control slide 5 generates a force which acts counter to the flow and which 65 makes the control slide act as a floating body, i.e. The flow meter can be controlled without additional force being exerted on the control slide.

To improve the inertia properties of a free-floating control spool, the latter is loaded with a compression spring 18, which has a small spring constant but a large preload. This compression spring 18 is installed between the outlet connection 11 and the control slide 5 in such a way that it is slightly pretensioned when the flow rate measuring device 1 is out of operation. For better guidance of the compression spring 18, the control slide 5 and also the outlet connection 11 contain sack-shaped bores 19 and 20. For the sake of completeness, reference should also be made to the undercut annular groove 21, which represents a production-dependent measure. The arrows indicate the direction of flow of the medium.

FIG. 2 shows in a stereometric representation the control slide 5 designed as a truncated cone with a bag-shaped bore 19 serving to receive the compression spring 18. Of course, the compression spring can have approximately the diameter of the cylindrical space 9 in order to be guided thereby. If the control movement of the control slide 5 takes place without the action of a compression spring, the larger end face of the control slide is advantageously designed without a bore 19. The smaller bore adjoining the end of the bore 19 is required to produce an annular surface which is flat for the compression spring 18.

If the flow rate measuring device 1 is used with flow media, the maximum and minimum throughput of which are relatively far apart, then the control slide must move over a longer distance.

In this case, the control slide 5 according to FIG. 3 has a bore 25 on its larger end face, in which a sleeve 26 is firmly inserted. Sleeve 26 contains on its circumference a number of passages 27 which connect the cylindrical part 28 of the guide body 2 and the interior of the sleeve 26.

Corresponding to the throughput quantity, the cylindrical space 28 advantageously has a larger cross-sectional area than the maximally enlarged conical part 30 of the control space 8. Outlet connector 11 is firmly connected to the guide body 2 by means of screws 12 or a thread, not shown. The sealing device 29 ensures that the medium flowing through cannot escape.

Outlet nozzle 11 has a bore 31, from which the sleeve 26 is slidably received. The bore 31 is advantageously lined with a sleeve 32 so that there is no excessive friction when the control slide 5 is displaced. Sleeve 26 and sleeve 32 may have a mutual play, which corresponds to a light running fit. This ensures that the control slide 5 rests more or less tightly on the conical outer surface of the control chamber 8 in the idle state of the flow rate measuring device 1 and thus does not form a leak compared to low flow rates. This embodiment can also advantageously have a compression spring 18 with a low spring constant. For the sake of completeness, reference is made here to the dash-dotted lines 33, 34, the position of which shows the control slide 5 in the rest position. From this it can be seen that the length of the control slide 5 and that of the field coil 14 coincide in the rest position. As in FIG. 1, protective sleeve 17 forms the end of the device.

According to FIG. 4, a further exemplary embodiment of a flow rate measuring device is shown, which essentially has a modified control slide 5 compared to FIG.

In contrast to FIG. 3, the conical part 35 of the control slide 5 widens into a cylindrical part which is guided in the cylindrical space 9 of the guide body 2.

In this version, too, the sliding and guiding bodies may lie within a light running fit, so that they are full

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constant tightness of the conical part 35 in the guide body is not in question.

On the circumference, the cylindrical part of the control slide 6 contains channel-shaped channels 37 which extend over the length of the cylindrical part and emerge on the circumference of the conical part 35. Figure 5 shows these trough-shaped channels 37, the size and number of which depend on the volume of the media to be enforced. Of course, the construction of the flow rate measuring device shown in FIG. 4 can contain a compression spring (not shown) which can be inserted between the outlet connection 11 and the control slide 5. This compression spring can advantageously bear against the cylindrical part 35 of the guide body 2.

FIG. 6 shows a further variant of an object falling under the generic term mentioned at the beginning. In contrast to the flow quantity measuring devices 1 described so far, the guide body 2 here has a cylindrical shape about its longitudinal axis, which has different diameters due to the structural design of the device. In the area of the medium inlet and outlet, nothing has changed compared to the previously discussed embodiments, in that inlet and outlet connections 11 and 7 are still used for fastening a hose with clips. A screw connection would also serve the purpose, but it is more complex due to the production, the required tightness and susceptibility to wear (smashing). The control chamber 8 of the guide body 2 widens in the direction of flow of the medium into a cylindrical space 38. This cylindrical space 38 serves for the sliding guidance of the cylinder 40 indirectly adjoining the conical part 39 of the control slide 5. The control slide has between the conical part 39 and cylinder 40 5 an annular groove 41, the bottom 42 of which contains one or more bores 43 which are in line connection with the coaxial cylinder bore 44. The cylinder bore 44 opens into the cylindrical space 38, which communicates with the outlet line 10. After entering the control chamber 8, the medium flows through the bores 43 and cylinder bore 44 into the cylindrical space 38, from where it leaves the device through the outlet line 10. As an alternative possibility, the cylinder 40 can have channel-shaped channels on its circumference, which extend over its entire length to the annular groove 42 and are connected to this line. This configuration of the cylinder 40 means that the bores 43 and cylinder bore 44 can be dispensed with. See Figure 7.

(The dash-dotted lines in FIGS. 6 and 7 show an alternative embodiment of the cylinder 40.)

On the circumference of the part of the guide body 2 which has the largest cross section, two grooves 45 of equal size are screwed in, which are distributed at regular intervals over the areas of the cylinder 40 of the control slide 5 which is in the rest position. A field coil 46 is wound in each of the grooves 45, which together form a differential coil when excited by means of alternating current and are connected to an electrical power source via a measuring bridge.

Instead of a differential coil, a simple field coil can be attached to the circumference of the guide body, which preferably has the same length as the cylinder 40 of the control slide 5 and coincides with this in the rest position of the control slide 5.

To protect the electrical equipment, the field coils are each covered by a protective sleeve 22. So that the device can be installed in any position, a compression spring with a low spring constant is inserted into the cylindrical space 38.

When the flow rate measuring device 1 is started up, the control slide 5 lifts out of its rest position, as a result of which the current or voltage conditions in the field coils connected to a current source change. The changed values are read off on a quantity value scale that is proportional to the current or voltage values.

In the case of a differential coil on the guide body, as described in the lines above, when the medium flows through, the control slide 5 is opened in such a way that

that the cylinder 40 dips out of the field coil 46 deeper into the other. With the change in position of the cylinder 40, the impedances in the field coils change and thus cause a voltage change which, in conjunction with a measuring bridge, gives a current or voltage display which is proportional to the path of the control slide 5 and which, as a flow quantity, e.g. is displayed directly in 1 / min.

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4 sheets of drawings

Claims (13)

639 198 PATENT CLAIMS 1.Flow rate measuring device for liquid and gaseous media, with a guide body enclosing a cavity on all sides and made of non-ferromagnetic material, which has an inlet 5 and an outlet opening for the medium at a distance from one another and a control slide arranged between these openings, which at least partially made of ferromagnetic material and which can be displaced towards the inlet opening by a force acting counter to the flow and through the flow towards the outlet opening and with at least one field coil arranged on the circumference of the guide body in the direction of movement of the control slide, which is connected to an electrical circuit and connected to a display device, characterized in that the control slide and the interior of the guide body in their control-effective area dependent on the fluid flow have a conical shape tapering parallel to the inlet opening and in that a part of the Control slide is at least partially in the field coil arranged on the guide body when flowing through the medium. 2. Flow rate measuring device according to claim 1, characterized in that the control slide is formed from ferromagnetic material. 25th 3. Flow rate measuring device according to claim 1, characterized in that the part of the control slide formed from ferromagnetic material and the field coil have the same length. 4. Flow rate measuring device according to claim 1, 3 "characterized in that the length of the ferromagnetic part of the control slide and that of the field coil coincide in the non-operating state. 5. Flow rate measuring device according to one of the preceding claims, characterized in that the field coil is arranged on the guide body in the region of the control slide and interior tapering parallel to the inlet opening. 6. Flow rate measuring device according to one of claims 3, 4 or 5, characterized in that the field coil 40 has a winding parallel to the control-effective area of the control slide. 7. Flow rate measuring device according to claim 1 or 2, characterized in that the guide body has a differential coil consisting of two field coils on its circumference. 8. Flow rate measuring device according to claim 7, characterized in that the part of the control slide consisting of ferromagnetic material is in the non-operating state symmetrically between the field coils. so 9. Flow rate measuring device according to claim 1 or 2, characterized in that the control slide is formed in its tax-effective area from non-ferromagnetic material. 10. Flow rate measuring device according to claim 9, characterized in that the ferromagnetic part of the control slide facing the outlet opening is cylindrical. 11. Flow rate measuring device according to claim 10, characterized in that a cylindrical guide part of the control spool has longitudinal channels on the circumference, which extend over the cylindrical part and open into the interior of the guide body. 12. Flow rate measuring device according to claim 10, characterized in that a cylindrical guide part of the control spool 65 has longitudinal channels which through one between the control-effective area of the control spool and its guide part in one to the axis of the Control slide open concentric annular gap, which communicates with the interior of the guide body when flowing through the medium. 13. Flow rate measuring device according to claim 1 or 2, characterized in that a compression spring is arranged between the end face of the control slide facing the exit side and the exit-side inner surface of the guide body.