DE3016837A1 - Annular piston pump with inner and outer cylinder - has three induction coils, energisable in phase shift mode, distributed in outer cylinder to give compact energy source - Google Patents

Abstract

The inner and outer cylinders are concentrically arranged and form between them a working chamber (2), closed on the front sides by lateral parts. Between the two cylinders is provided a radial separating strip. The piston is C-shaped (11) and of the same axial width as the operational chamber, in which it is movably mounted in such manner that the separating strip penetrates through the opening of the C. Between the piston and the two cylinders are formed two compression chambers. In the outer cylinder are mounted at least three induction coils, distributed uniformly over its periphery and energisable in a phase shift mode. The annular piston consists, at least partly of a dipolar magnet. The open ends of the piston, freely movable in the chamber abut the separating strip. The pistons are made of non-magnetic material. The coils provide a compact source of electrically supply esp. for lighting.

Description

Rotary piston machine

The invention relates to a rotary piston machine, in particular a rotary piston pump, with an inner cylinder and one of these concentrically spaced surrounding outer cylinder, with a working chamber between the inner and outer cylinder is formed, which is closed at its end faces by side panels with a radially between the inner and outer cylinder arranged separating web, with an approximately C-shaped annular piston about the same axial width as the working chamber, which is in the working chamber is arranged movably, such that through the opening of the C of Separating web protrudes and between the annular piston and outer cylinder and between the annular piston and inner cylinder an outer resp.

an inner displacement chamber is formed, with a pressure medium inlet and a pressure medium outlet, each on one side thereof in the region of the separating web open into the working chamber.

In such a known rotary piston pump, two crank pins protrude axially in corresponding bores of the Ring piston. Are driven the crank pin in such a way that it has a circular motion in the plane of the annular piston carry out. In doing so, they inevitably take the annular piston to a circular sliding movement with. During this forced movement, the annular piston always moves with the sealing strips its outer contour on the inner contour of the outer cylinder and with its inner contour along the outer contour of the inner cylinder. The one in this way between the annular piston and the inner cylinder and the outer cylinder formed crescent-shaped inner and outer displacement chambers promote it on one side of the separating web through the pressure medium inlet in the working chamber pressure medium on the other side of the separator to the pressure medium outlet.

Since the ring piston is forcibly guided by the crank pin, between Ring piston and inner cylinder as well as outer cylinder always have a clearance, otherwise there may be jamming between these parts. The resulting Pressure medium short circuit from the pressure medium inlet to the outlet is caused by the above-described elaborate and expensive sealing strips achieved.

Due to the friction of these sealing strips on their contact contours disadvantageously also energy losses.

Furthermore, there are sealing problems due to the from the outside into the Working chamber protruding drive shafts of the crank pin. It is also laborious to do this Drive drive shafts.

Another disadvantage is that the many moving items this known pump lead to relatively high operating noise.

It is therefore an object of the invention to provide a rotary piston machine according to the To create a generic term that has as few moving parts as possible and is independent can be arranged at any point by a rotary actuator.

This object is achieved according to the invention in that in the outer cylinder at least three phase-shifted, evenly distributed around the circumference, to controllable induction coils are arranged, the annular piston at least partially from a 2-pole magnet and the open ends of the ring piston, which is freely movable in the working chamber are attached to the divider. Due to this design, the annular piston pump has its own simple drive and can therefore, apart from the connection cables for power supply, independently at any point without feeding a Rotary actuator can be installed. This is especially true when installing in motor vehicles of importance because there is only little installation space available here.

In an advantageous embodiment of the invention, in the outer cylinder three induction coils offset by 120 degrees and the induction coils in the ring piston assigned three magnetic pole offset by 120 degrees to each other be arranged. This training is particularly advantageous when installed in motor vehicles, because here three-phase current is already generated by the alternator.

The annular piston can either be made of a non-magnetizable material consist, in the magnets are inserted or completely made of magnetizable material exist.

So that the contact surfaces of the annular piston for guidance on the separating web they are advantageous when the circular sliding movement cannot jam Roof-shaped and thus only have line contact with the separator.

A reduction in the number of components can be achieved by that the outer cylinder and the inner cylinder with one side part as a one-piece Housing part are formed and the axially directed opening of the working chamber is closed by a cover part. These parts are also easily molded by injection molding can be produced from plastic.

Is the separator as a separate one, with its ends in recesses formed on the inner and outer cylinder insertable component, it can consist of one Compared to the inner cylinder and the outer cylinder made of more wear-resistant material be. This is advantageous because the contact surfaces of the annular piston during operation of the rotary piston machine slide permanently along the separating web.

Are the recesses in the outer cylinder to accommodate the induction coils open towards one end face of the outer cylinder, so the induction coils can be and are easily installed from the side after attachment the side parts are held securely in their installation position. The same applies to the magnets, if the recesses in the annular piston in which they are received, after one end face of the annular piston are open.

A simple design of the rotary piston machine according to the invention consists in that pressure medium inlet and pressure medium outlet are arranged in a side part, are formed axially opening into the working chamber. This training enables it in a simple way with injection molded side parts pressure medium inlet and pressure medium outlet to be obtained in one operation with the manufacture of the side panels.

An embodiment of the invention is shown in the drawing. FIG. 1 shows a rotary piston pump according to the invention in section along the line I-I in Figure 2, Figure 2, the rotary piston pump according to Figure 1 in section along the Line II-II, Figure 3 the housing part of the rotary piston pump according to Figure 1 in section, FIG. 4 shows a lamellar plate of the annular piston pump according to FIG 5 the cover part of the rotary piston pump according to Figure 1 in view, figure 6 shows the cover part according to FIG. 5 in section, FIG. 7 shows a movement diagram of the annular piston.

The annular piston pump shown in the figures has a cylindrical Housing part 1 with a pot-shaped recess which forms a working chamber 2. An inner cylinder 3 protrudes concentrically into the working chamber 2. The outer one the radially circumferential part of the housing part 1 forms an outer cylinder 4. The working chamber 2 is closed at its opening by a cover part 5 in such a way that the cover part 5 both on the face of the inner and outer cylinders facing it 3 and 4 is attached.

Between the inner cylinder 3 and the outer cylinder Q is a radial formed as a separate part separating web 6 arranged. With its free ends it is inserted into recesses 7 and 8 on the inner and outer cylinders 3 and 4.

Where and behind the separating web 6 opens a pressure medium inlet 9 or a pressure medium outlet 10 axially into the working chamber 2.

An approximately C-shaped annular piston 11 is in such a way in the working chamber 2 arranged that there is radial play between the inner and outer cylinder 3 and 4, but with its end faces on the bottom of the working chamber 2 or on the cover part 5 is attached. The open ends of the annular piston 11 are in contact with the separating web 6, their contact surfaces 12, 12 'are roof-shaped so that the annular piston 11 unhindered within the working chamber 2 around the separator 6 can pivot.

On the annular piston 11 there are three recesses that are axially open to one side 13 offset by 120 degrees to each other.

formed, in which magnets 14 are arranged.

Three of these magnets 14 are also offset from one another by 120 degrees Induction coils inserted in recesses -15 closed towards the working chamber 2 16 assigned.

The cores 17 of the induction coils 16 consist of stacked one on top of the other Lamellar plates 18, a single part of which is shown in FIG. In your radially outer area are the lamellae -18 by a radially circumferential Ring 19 connected so that the laminated laminations 18 of all induction coils 16 form a package, on whose parts forming the cores 17 the coil windings 20 are attached.

Since the recesses 15 in the outer cylinder 4 with the cover part removed 5 are open axially to one side, can be in the package of lamellas 18 with the coil windings 20 as a structural unit simply into the recesses 15 axially can be used.

Between the parts of the lamellar plates 18 forming the cores 17 are on the rings 19 radially inwards into corresponding bulges 21 of the outer cylinder 4 protruding tabs 22 formed.

Through holes in the area of the tabs 22 in the housing part 1, cover part 5 and lamellar plates 18 are screws 23 passed through the the annular piston pump is held together.

The function of the rotary piston pump is as follows: To the three induction coils 16 three-phase current is applied so that a rotating field is created inside the rotary piston pump, which acts on the annular piston 11. As a result, the annular piston 11 performs a circular sliding movement as shown schematically in FIG. The migrates between Inner cylinder 3 and annular piston 11 formed sickle-shaped displacement chamber 24 and the sickle-shaped outer displacement chamber formed between the annular piston 11 and the outer cylinder 4 25 in a circle around the inner cylinder 3 and thus promotes pressure medium from the pressure medium inlet 9 to the pressure medium outlet 10.

Claims (10)

Claims 1. A rotary piston machine, in particular a rotary piston pump; with an inner cylinder and one concentrically enclosing this at a distance Outer cylinder, a working chamber being formed between the inner and outer cylinders is, which is closed at its end faces by side parts, with a radial between the inner and outer cylinder arranged separating web, with an approximately C-shaped The annular piston has approximately the same axial width as the working chamber that is in the working chamber is movably arranged in such a way that the separating web protrudes through the opening of the C. and between the annular piston and the outer cylinder and between the annular piston and the inner cylinder an outer or an inner displacement chamber is formed, with a pressure medium inlet and a pressure medium outlet, each on one side thereof in the region of the separating web Open into the working chamber, characterized in that in the outer cylinder at least three phase-shifted controllable induction coils evenly distributed around the circumference are arranged, the annular piston at least partially from a 2-pole magnet and the open ends of the ring piston, which is freely movable in the working chamber are attached to the divider. 2. Rotary piston machine according to claim 1, characterized in that in the outer cylinder three induction coils offset by 120 degrees and in the Ring pistons assigned to the induction coil are three offset from one another by 120 degrees magnetic poles are arranged. 3. Rotary piston machine according to one of the preceding claims, characterized characterized in that the annular piston is made of non-magnetizable material, in which magnets are inserted. 4. Rotary piston machine according to one of claims 1 and Z, characterized in that that the annular piston consists entirely of magnetizable material. 5. Rotary piston machine according to one of the preceding claims, characterized characterized in that the abutment surfaces (12, 12 ') of the separating web (6) Ring piston (11) are roof-shaped. 6. Rotary piston machine according to one of the preceding claims, characterized characterized in that the outer cylinder (4) and the inner cylinder (3) with the one Side part are designed as a one-piece housing part (1) and the axially directed Opening of the working chamber (2) is closed by a cover part (5). 7. Rotary piston machine according to one of the preceding claims, characterized characterized in that the separating web (6) as a separate one with its ends in recesses (7) is formed on the inner and outer cylinder (3 and 4) insertable component. 8. Rotary piston machine according to one of the preceding claims, characterized q indicates that the recesses (15) in the outer cylinder (4) for receiving the Induction coils (16) after a forehead side of the outer cylinder (4) are open. 9. Rotary piston machine according to claim 3, characterized in that the recesses (13) in the ring. piston (11) for receiving the magnets (14) to one end of the The annular piston (11) are open. 10. Rotary piston machine according to one of the preceding claims, characterized characterized in that pressure medium inlet (9) and pressure medium outlet (10) in a side part are designed to open axially into the working chamber (2).