DE1148349B - Electromagnetically operated compression and pumping device - Google Patents

Description

Electromagnetically operated compression and pumping device Die The invention relates to an electromagnetically operated compression and pumping device with a fixed ring-shaped magnetic circuit as a stator and a corresponding one cylindrical rotor that has an elastic member with the fixed part of the Device is connected in such a way that it has a certain rotational oscillation frequency is granted.

In a known compressor of this type, there is the elastic member made of a rod spring subjected to torsion. Located at the free end of the same a rotor, the two diametrically opposite pole pieces of which in the Rest position of the oscillating system only partially with the corresponding poles of the Stator are in cover. The difficulty arises that only in the a direction of rotation through the magnetic field lines a torque on the armature is exercised, but in the other direction of rotation the swinging back of the rotor caused only by the elastic force of the bar spring. Otherwise results there is a relatively high oscillation frequency for the oscillating system Two torsional oscillations of the armature are carried out per oscillation period of the mains voltage will.

According to the invention, the stator is radial, interconnected Equipped magnetic poles, which are present in an even number and their mutual Distance is essentially equal to the width of the pole pieces with which the horseshoe-shaped or arcuate permanent magnets of the rotor are equipped, their Number half the number of poles of the stator, being the permanent magnets of the rotor into a non-magnetic, but electrically conductive material are embedded and in the rest position of the rotor between two neighboring Poles of the stator are located. The advantage of this arrangement is that it is small Oscillation frequency of the rotor, as there is a single oscillation per period of the mains voltage of the rotor takes place. In addition, the rotor is moved from the zero position in which the Pole pieces of the rotor are located between two adjacent pole pieces of the stator, deflected both in one and in the other direction by the magnetic field. The permanent magnets of the rotor carry, apart from the definition of the direction the deflection, contributes significantly to the amplification of the deflection force. The non-magnetic but electrically conductive material that surrounds the permanent magnets of the rotor, finally accelerates the reversal of motion of the oscillating system. As far as you can has already used permanent magnets in the armature of a refrigerant compressor, were the same at the free end of an elastic and pendulum motion Vibrating rod attached. However, this design is less suitable for cooling units high performance, since the elastic rod must be chosen quite long, what leads to a bulky construction. One must also focus on the construction of this use the elastic rod with particular care. By attaching the permanent magnets In a rotatably mounted rotor, above all, this results in a very crowded one Design allows that instead of a reciprocating oscillating rod, an elastic one Organ, for example in the form of a curved leaf spring, can be used.

In another known design, an anchor is also present, which can perform a certain torsional vibration. However, this is of secondary importance Significance because the main aim is to have a longitudinal oscillation of the armature.

The rotor is expediently about running essentially transversely to the axis Arms connected to the compression organs by sliding in fixed cylinders Pistons are formed and are arranged such that with each torsional vibration at least one in one direction or the other Piston his Intake stroke - and at least one piston makes its compression stroke. Through this this results in a particularly uniform operation of the compressor.

Further details of the invention emerge from the subclaims.

Exemplary embodiments of the invention are shown in the drawings.

Fig. 1 is a sectional elevation of one embodiment of the compression direction; Fig. 1 a is a section along the line I a-1 a in Fig. 1; Fig. 2 is a section along the line 11-II in Fig. 1; Fig. 3 is a section along the line III-III in Fig.1; Fig. 4 is a section similar to Fig. 3, but shows a modification the arrangement; Fig. 5 is an elevation in section of a variant similar to Fig. 1.

FIG. 5 a is a section along the line V a-V a in FIG. 5.

In the embodiments according to FIGS. 1 to 5 is the Compaction device within a casing 45, closed by a cover 46, on which the device by means of the elastic organs 47, for example in a number of three, is suspended.

The body of the compression device consists of an annular Housing 48 which carries in its center the bearings 49 and 50, the latter can be either smooth bearing bushes or needle bearings or other roller bearings. The bearings 49 and 50 carry a shaft 51, of which the end 51a is firmly connected with a leaf spring 52, which is essentially wound in a spiral and with its free end to an anchoring piece 53 (Fig.2), which is attached to your: the body the device forming housing 48 is attached, is attached.

On the other end 51b of the shaft 51, a lever 54 is keyed, preferably with the two legs 55 and 56, the ends of which engage the piston rods 57 of the piston 57a , the latter moving in the cylinders 58, which are also attached to the housing 48 are attached. The pistons 57 a are carried along by the piston rod 57 so that they can slide in the cylinders, the bore of which is shaped like a space concentric to the shaft 51 (FIG. 1 a). These cylinders are at one end with the interior of the jacket 45 in connection and are separated from the pressure or delivery chambers 58 a in the cylinder 58 by the valves 57 b, which have a similar shape to the pistons 57 a and just like the latter are provided with deformable elastic seals. The shaft 51 carries in its center a cylindrical part 59 made of a non-magnetic, but electrically conductive metal, hereinafter referred to as the rotor, in which the permanent magnets 60; 61, 62 and 63 are embedded. As can be seen in particular from FIGS. 3 and 4, these permanent magnets have essentially the shape of an arc of a circle.

The rotor 59 also carries the cheeks or pole pieces 64 from one magnetic metal attached to the ends of each of the permanent magnets Cover 60 to 63 and protrude a little beyond the circumference of the rotor 59.

As can be seen from the drawing, the outside has the pole pieces 64 also has the shape of an arc concentric to the rotor 59. The permanent magnets 60 to 63 as well as their pole pieces form a polarized anchor that allows for cooperation with a magnetic circuit 65 carried by the housing 48 is determined.

As can be seen from Fig. 3, the magnetic circuit consists of a continuous yoke 66, for example from a stack of magnetic sheets, which the main poles 67, 68, 69 and 70 and the secondary or secondary poles 71, 72, 73 and 74 forms, which latter are located between the main poles and so arranged are that in the rest position the pole pieces 64 of the permanent magnets 60 to 63 each cover the entire free space between a main and a secondary pole. To this Way can the permanent magnetic field generated by the various permanent magnets be closed through the magnetic circuit.

As an example, it should be mentioned here that those emanating from the permanent magnet 60 Lines of force partly through the main pole 70 and partly through the two secondary poles 73 and 74 can pass through, obviously the least of them being the lanes track magnetic reluctance.

The main poles 67 to 70 are with the windings 75 and 76, 77 and 78 provided, which can be fed directly with alternating current.

The magnetic field generated at a first half-wave of the alternating current for supplying the windings obviously tends to close through the permanent magnets 60 to 63, so that the latter are subjected to a displacement by which the rotor 59 is rotated, namely in the Sense of rotation in which the permanent magnets 60 to 63 strive to assume a position in which the flux of lines of force reaches a maximum value.

In the following half-wave, the movement of the rotor is apparently reversed, so that the rotor carries out constant continuous oscillations. The leaf spring 52 connected to the shaft 51 and thus also to the rotor is thus subjected to vibrations by the latter. The natural frequency for the idling of the assembly of moving parts, consisting of the rotor 59, the shaft 51, the various parts seated on the shaft and the leaf spring 52, is selected in a manner known per se, so that this natural frequency - is noticeably lower than that of the alternating current for supplying the windings, so that the oscillating movement obtained, even if it is synchronous with the supply current, does not come into resonance with it. An approach to the resonance occurs only in the normal operations of the apparatus reached, ie, when the located by sliding in the cylinders 58 piston 57 a compressed Fludium in such a state that the thereby resulting elastic forces sufficient to reduce the natural vibration frequency of the movable To increase the aggregate so that the latter approaches a value which is a little lower than the frequency of the alternating current for feeding the windings. As will be easily understood when considering FIG. 1 a, one of the pistons 57a is just performing its suction stroke when the other piston is performing its compression stroke. It follows that the strokes of the two pistons on both sides of the equilibrium position which they assume in the rest position of the device are exactly the same. Fig. 4 illustrates a slight modification, as a result of which the secondary poles 71 to 74 shown in Fig. 3 are replaced by the main poles 71 a, 72 a, 73 a and 74 a, which with the windings 75 a to 78 a, similar to the Windings 75 to 78 are provided.

The more convenient execution of the magnetic circuit, it is according to the 4, the yoke 66a of this magnetic circuit is preferable as shown here is to train, d. H. so in the form of a ring.

The operation of the modified embodiment of FIG. 4 is evident the same as that described with reference to Fig. 3, however, becomes it is possible with the same power output by the device, the external dimensions of the device and thus also the overall space requirement of the compacting device, which is beneficial in numerous cases.

The Fig.5 shows a variant in which you have both the magnetic circuit according to FIG. 3 as well as that according to FIG.

In this variant, the leaf spring 52 is omitted and is replaced by a torsion bar 79, the end 79 a of which is anchored in a rigid holder 80; the latter is carried by that part of the housing 48 to which the bearing 49 also belongs, in which a hollow shaft 511 carrying the rotor 59 rotates. This hollow shaft 511 also rests in the bearing 50 and protrudes below from the housing 48, where it is then firmly connected to the free end 79 b of the torsion bar 79. The hollow shaft 511 also carries, and in the same way as the shaft 51 in Fig. 1, a lever 54a with the two legs 55a and 56a, the ends of which are attached to the piston rods 81 and 81a and 82 and 82a of the four pistons 57a are connected; the latter move in the four cylinders 58 of the same construction as the cylinders of Fig. 1a. This arrangement with four cylinders allows the forces transmitted to the pistons to be balanced, and consequently no harmful reaction is transmitted to the hollow shaft 511, which is particularly advantageous in order to avoid any wear on the bearing 50. In addition, with this arrangement it becomes possible to construct a multi-stage compressor in which the transmitted forces are also completely balanced.

Claims (4)

PATENT CLAIMS: 1. Electromagnetically operated compression and Pump device with a fixed ring-shaped magnetic circuit as a stator and a corresponding cylindrical rotor which is connected to the fixed part of the device is connected in such a way that it has a certain Rotational oscillation frequency is given, characterized in that the stator is equipped with radial, interconnected magnetic poles, which are in a straight line Number are present and their mutual spacing is essentially equal to the width is the pole piece with which the horseshoe-shaped or arcuately curved Permanent magnets of the rotor are equipped, the number of which is half as large as the number is the pole of the stator, whereby the permanent magnets of the rotor are converted into a non-magnetic, However, the electrical current conductive material are embedded and in the Rest position of the rotor between two adjacent poles of the stator. 2. Device according to claim 1, characterized in that those poles of the stator with magnetic coils are equipped, which are in the rest position of the rotor between the shoes each a permanent magnet. 3. Device according to claim 1, characterized in that that each pole of the stator is equipped with a magnetic coil. 4. Device according to one of claims 1 to 3, characterized in that the rotor over im essentially transverse to the axis arms connected to the compression organs which are formed by pistons sliding in stationary cylinders and such are arranged that with each torsional vibration in one direction or the other at least one piston is its intake stroke and at least one piston is its compression stroke undertakes. Documents considered: German Patent No. 720111; German explanatory documents No. 1028 595, 1034 666.