DE3017045A1 - Flowmeter with spiral rotor - has rotor supported in stator by pairs of magnets in end plates to eliminate friction of bearings - Google Patents

Abstract

The meter has a casing (12) with a spiral passage (18) through it. The inlet (15) is tangential to the spiral and the outlet (17) is at right angles to it at the centre. A spiral rotor (25) within the passage touches the outer wall (21) of the passage at one point and the inner wall (22) at another. Permanent magnets (30, 31, 32, 33) are embedded in the end plates of the casing at regular intervals round it. Permanent magnets (41, 42, 43, 44) are embedded in the ends of the rotor at corresponding points. The magnetic forces locate the rotor radially and the flow of fluid displaces it against these forces in proportion to the flow.

Description

Rotary piston machine and use of the same.

The invention relates to a rotary piston machine with a circular piston or as a spiral-shaped circular piston runner, which is in a corresponding curved to the runner, leading from an inlet to an outlet and between two flat, parallel frontal winds running channel is supported, whereby the Runner rests sealingly on the end walls and both the concave and the convex Inner wall of the channel along each touching surface line touched, so that after According to an essentially circular movement of the rotor, a flow rate of a Medium comes about through the channel.

In known machines of this type, the rotor is attached to a mechanical one Leadership coupled so that it is in operation for rotary piston machines with rotary pistons typical pendulum-circling (with circular pistons) or purely circling (with spiral-shaped annular piston) can perform movement. This mechanical guide defines the trajectory of the Runner exactly. On the other hand is With rotary piston machines it is important that the rotor is along the contact surface lines sealingly rests against both the concave and the convex inner wall of the channel. It is therefore imperative that the mechanical guidance of the rotor and the The shape of the runner and the channel are precisely matched to one another.

However, the more precise this coordination, the greater the friction between the runner and the channel and, accordingly, the wear and tear. In addition in known machines of this type the rotor tends to block if in the medium, that penetrates the machine, there are solid particles and between the rotor on the one hand and the concave or convex channel inner wall are clamped.

To remedy this disadvantage is with a rotary piston machine with a spiral runner has already been proposed, the runner itself from a Produce flexible elastic band or with a resilient mechanical guide to be provided so that the runner under the presence of a solid particle local deflection (or by giving way) to a certain extent over the solid particle shifts. But if the runner is made of an elastically deformable material, or provided with a flexible bearing, then its shape accuracy and thus the volumetric throughput challenged by the machine.

It is therefore a purpose of the invention to provide a machine of the type mentioned in the opening paragraph Creation of a type in which no-mechanical guidance of the rotor is required which furthermore the runner can be made comparatively stiff, with also no blocking is to be feared in the presence of solid particles and Finally, the runner is constantly yielding to both the concave as well as being pressed against the convex inner wall of the canal without any increase Friction would have to be accepted.

According to the invention, this purpose is achieved in the proposed rotary piston machine achieved in that the runner by at least one pair of cooperating, in Direction of the axis of the circular motion more repulsive and in with respect to each other with staggered axes arranged magnetic elements stored in the channel is.

Features of preferred embodiments are defined in the dependent claims refer to. In addition, according to the invention, this rotary piston machine can also be used Proposed as a flow meter, with a in the area of one of the magnetic elements inductive signal generator is arranged.

The invention is given below purely by way of example the Drawing explained in more detail.

It shows: FIG. 1 a schematic section along the line I-I of FIG FIG. 2 through a flow meter, and FIG. 2 shows a section along the line II-II of Fig. 1.

The machine shown in FIGS. 1 and 2 is - as mentioned - to a flow meter 10. This has a housing 11, which in turn has only two parts, namely a main part 12 which is provided with a flat lid 13 is sealed. The main part 12, as can be seen from the hatching can be made of a plastic or another, non-magnetic material can, has an outlet nozzle 14, and an inlet nozzle 15, one of which Wall, as can be seen from FIG. 2, is formed by the cover 13.

The outlet nozzle 14 leads via a bend 16 to the actual Machine outlet 17 from which a spiral channel 18 of constant width extends. The channel 18 is, as can be seen in FIG. 2, by two flat end walls 19, 20 limited, the end wall 19 by part of the inside of the lid 13 is formed, while the end wall 20 is formed in the main part 12 is.

Furthermore, the channel 18 is through a concave inner wall 21 and through a convex inner wall 22 delimits. Both interior walls span a little more than 360, with the concave inner wall 21 partly from the inside of the wall of the main part 12 is formed, while the convex inner wall 22 for the most part by the outer Side of a spiral-shaped which is integrally formed in the main part 12 around the machine outlet 17 Rib 23 is formed. The channel 18 ends in the actual machine inlet 24 which the already mentioned inlet connection 15 connects.

0 In the channel 18 is a spiral, also about 360 spanning Runner 25 (open annular piston) arranged, which over its entire length a rectangular Has cross section. With its narrow sides, the runner 25 touches the sealing two flat end walls 19, 20, and otherwise he is dimensioned such that he concave and convex inner wall 21 and 22 of the channel 18 always on a contact surface line touched. These contact surface lines are in the position shown in FIG. 1 of the runner at the level of the section line II-II and denoted by 26 and 27, respectively.

The runner 25, which is also made of plastic or another, can be amagnetic substance, has at its outer end one at its one Molded on the narrow side th, short pin 28 (in Fig. 1 on the Side facing away from the viewer), which loosely in a circular, in the end wall 20 formed recess 29 engages, the diameter of which corresponds to the width of the channel 18 is equivalent to. This measure prevents the runner 25 - depending on Direction of flow of the medium - turns further into channel 18 or turns out of this.

In the end wall 20 of the main part 12, as well as in that from the inside of the cover 13 formed end wall 19 0 - each at an angular distance of about 90 from each other and about in the middle of the channel 18 - four permanent ones 30-33 and 34-37, respectively, with the permanent magnets 35, 37 only in with respect to their position in Fig. 2 are indicated. The direction in which the permanent 30-37 are magnetized, is indicated in Fig. 2 with arrows.

Each of the permanent magnets 30 - 37 fixed to the housing is one in the rotor 25 associated with a permanent magnet embedded in its narrow side. With the permanent magnets 30-33, the permanent 38-41 work together in the runner, and with the permanent magnets 34 - 37 the permanent magnets 42 - 45.

The direction in which the permanent magnets 38-45 are magnetized is also indicated in Fig. 2 with arrows.

This means that the permanent magnets of a interacting Pairs are magnetized in opposite directions, i.e. each other repel.

But since this repulsion is not in the axial direction of the rotor 25 Can be effective, the rotor 25 is urged radially in that direction in which the magnets of the rotor are offset against the magnets fixed to the housing are located. In Fig. 1, the runner 25 is therefore pushed to the left, i.e. towards the surface lines of contact 26, 27 out.

If a medium is now fed to the inlet port 15, and this to the When the outlet connection 14 is removed again, the runner 25 becomes a circular movement caused in the direction of arrow 46, with a practically pulsation-free flow comes about through the channel 18. The rotor magnets 38 - 45 each rotate. around the associated magnets of the magnets 30 - 37 fixed to the housing and the BE guiding envelope lines migrate counterclockwise towards outlet 17. (It goes without saying that if a medium is fed to the machine at 14 and removed again at 15, the circular Movement of the rotor takes place in clockwise direction).

While the housing-fixed magnets 30-37 on the one hand and the rotor magnets 38 - 45, on the other hand, are each arranged in pairs on the same axis, it goes without saying goes without saying that this is not a mandatory requirement. So can the housing-proof Magnets 30-33 and the rotor magnets 38-31 on the other hand, each by a certain one Angle in relation to the magnets 34 - 37 or 42 - 45 arranged rotated be.

In another embodiment, instead of the magnet pairs 38/42, 39/43, 40/44 and 41/45, a continuous, soft magnetic rod is also provided be. In this case the magnets are those that interact with these bars, Magnet pairs 30/34, 31/35, 32/36 and 33/37 fixed to the housing in any case in opposite directions Direction to magnetize and coaxially arrange.

To cease mutual repulsion and therefore the force with which the rotor 25 is pushed against the concave and convex inner walls 21 and 22, respectively can - apart from a corresponding choice of the remanence of the permanent magnets - various measures are taken. For example, you can use the magnets fixed to the housing on one side of the runner 25, e.g. that in the cover 13, not directly in arrange this, but take hold of an adjusting screw 47, and this more or less screw deep in the direction of the rotor 25 into the housing or cover, as indicated in Fig. 2 at the top right. On the other hand, you can have the housing fixed Magnets at least on one side of the rotor 25 as electromagnets 36 ' form a winding 48, and this winding with a variable voltage dine, e.g.

as indicated in Fig. 2 top right, via a potentiometer 49 and a voltage source 50.

As already mentioned, in the drawing there is a volumetric working Flow meter shown. Each revolution of the rotor 25 thus corresponds to a specific one Throughput volume. In order to record this, every turn of the runner is therefore also necessary 25 to capture. Since every mechanical coupling of the rotor to a transmission link would bring additional friction with it, especially at very low flow rates is not negligible, the movement of the rotor is detected without contact. In principle, this could be done photoelectrically, which is a transparent one Housing requires. But there are pairs of each other in the flow meter shown repulsive magnets are present, displaced magnetic fields inevitably occur which circle in the same direction but in opposite direction to the runner. With the present flow meter the circulating, displaced magnetic fields are generated by an inductive one in the housing 11 built-in or attached to this signal transmitter 51 detected, e.g. via a Amplifier 52 can be coupled to a counter 53.

From what has been said so far it is clear that the "magnetic "Suspension" of the rotor 25 in the housing 11 of the flow meter described is insensitive against any solid particles that may be carried along. There are also wear and tear on the concave and convex walls of both rotor 25 and channel 18 automatically compensated, even if this wear and tear is not regularly lengthways the whole spiral should be. The runner has 25 no bearing friction to overcome.

In a test model it was also found that the The flow meter described is suitable for measuring ranges of 1: 500 and more. this compared to conventional rotary piston meters (with a measuring range of in practice hardly more than 1: 100), to the conventional impeller meters (in the Practically no more 1:50) or even to the oval wheel counters (measuring range 1:10) quite a lot considerable expansion of the measuring range. This expansion is extraordinary especially at small flow rates of a few liters / hour of importance, those of the described Flow meter still flawless thanks to its practically non-existent starting torque are recorded.

Claims (8)

PATENT CLAIMS Rotary piston machine with an as circular or as a spiral I (rice piston designed rotor, which is in a corresponding curved to the runner, leading from an inlet to an outlet and between two flat, parallel end walls running channel is mounted, the runner sealingly rests against the end walls and both the concave and the convex Inner wall of the channel along each touching surface line touched, so that after Given a substantially circular movement of the rotor, a flow rate of a Medium comes about through the channel, characterized in that the runner by at least one pair of cooperating, in the direction of the axis of the orbiting Movement of mutually repulsive and with respect to each other with staggered axes arranged magnetic elements is stored in the channel. 2. Rotary piston machine according to claim 1, characterized in that that in each end wall at least one magnet net is let in, to which an oppositely magnetized magnet embedded in the rotor is assigned is. 3. Rotary piston machine according to claim 2, with a spiral Runner and a spiral channel, characterized in that in both end walls at regular intervals along the spiral several magnets are embedded, which interact with a magnet embedded in the runner. 4. Rotary piston machine according to claim 2, characterized in that the distance between those embedded in the end walls and those embedded in the runner Magnets adjustable and lockable. 5. Rotary piston machine according to one of the claims 1 - 4, thereby characterized in that the magnetic elements are at least partially made up of permanent magnets are formed. 6. Rotary piston machine according to one of claims 1 - 4, characterized in that that the magnetic elements are at least partially formed by electromagnets. 7. Rotary piston machine according to claim 1, characterized in that that at least one magnet is embedded in one and the other end wall is, these two magnets arranged coaxially and magnetized in opposite directions are, and with one in the runner let soft magnetic Work together element. 8. Use of the rotary piston machine according to claim 1 as a flow meter, characterized in that an inductive one in the area of one of the magnetic elements Signal transmitter is arranged.