NO120036B - - Google Patents

Description

Oscillating compressor with vibrating gaze and with electromagnetically maintained movement.

The present invention relates to pumps or compressors with electromagnetically maintained oscillating motion.

More particularly, it applies to such designs

where the natural frequency of the vibrating devices is lower than the frequency of the feeding alternating current in order to provide a self-regulation of the mode of operation as a function of load variations such as those that occur when these compressors are used in refrigeration equipment where the effect varies considerably with the ambient temperature .

Devices of this nature already have

been produced industrially. In particular, there are known compressors whose magnetic circuit has four poles formed by the ends of two symmetrical, U-shaped elements which are placed opposite each other so that they border two air gaps in which one and the other of two sets of permanent magnets which have parallel axes, but of opposite polarity, so that one magnet in each set is attracted in the air gap for each half period of the alternating current feeding the coils of the two U-shaped elements of the magnetic circuit. This device is of interest in that it is possible to allow the flexible sheet which is arranged to carry each magnet set to be displaced in mutually opposite directions, whereby by allowing these sheets to carry compressor members, a balanced movement can be achieved which prevents the transmission of vibrations to the compressor capsule. However, this design has the disadvantage that one of the magnets in each set comes slightly outside the magnetic circuit during each half-cycle of current

but even then is not exploited. In addition, it happens - which is much more serious - that the magnet in question is partially demagnetized by magnetic scattering fields that occur in the event of an overvoltage or when the amplitude of movement is small, especially in the case of a weak load. This demagnetization is due to the fact that the lines of force that pass through the air gap, at the moment in question, have the opposite direction to those that emanate from the magnet that is to emerge from the air gap. This disadvantage has led to another design where the elements of the magnetic circuit form three poles placed respectively at the ends and in the middle and formed by a permanent magnet with the same polarity in the outer poles. In this latter device, the armature consists of a magnetic core which extends between the two outer poles, and through which the lines of force from the magnets join in two separate circuits. During operation, the lines of force in the alternating field produced by the feeding alternating current will alternate for each half-period of the current through the central poles of the permanent magnets and soon one soon the other outer pole, as this alternating field is superimposed on the field from the magnets, which are always passed by lines of force with same direction as their own field. This means that there is no risk of demagnetization.

However, with this design, it is necessary to give the armature a sufficient length so that it overlaps the two outer poles, whereby its mass is increased and the practical design of the device is complicated to an appreciable degree. Moreover, it is no longer possible to let the two anchors work in opposite directions to achieve balanced work as in the first device. Furthermore, it has been observed that the magnetic losses were significant.

The problem that remained to be solved thus primarily consisted in providing an apparatus where the anchors carried by the flexible organs, e.g. pliable eyes, only have a small mass and do not run the risk of being taken to positions where there is a risk of demagnetization during work. In addition, the device should allow for mutual movement of the anchors with the aim of having the same effect as with the first device mentioned above.

This task is completely solved by the device according to the invention.

The present compressor comprises two vibrating faces which are connected to compressor pistons which are intended to move in the cylinders and each carries a polarized armature, placed in an air gap limited by two identical elements of a magnetic circuit, which according to the invention comprises eight poles arranged so that each armature in rest position is located between four poles, in order for the lines of force from the polarization field to join through the two elements of the magnetic circuit, and for an alternating field from coils fed directly with alternating current to join along two separate paths that pass through the respective different poles of the magnetic circuit and through the polarized armatures, which are displaced to correspond at all times with the poles of the magnetic circuit which are currently traversed by lines of force from the alternating field in the same direction as the lines of force in the constant polarization field.

Various other features of the object of the invention will also be apparent from the following detailed description.

Embodiments of the compressor according to the invention are shown as non-limiting examples in the drawing. Fig. 1 is a vertical longitudinal section taken along the line I—I in fig. 3 and shows the main parts of the compressor according to the invention. Fig. 2 is an elevation seen at right angles to fig. 1. Fig. 3 shows a section largely along the line III—III in fig. 1. Fig. 4 is a section similar to fig. 3, but on a larger scale, and shows an embodiment variant. Fig. 5 is a circuit diagram showing the electrical connections between the different coils shown in fig. 4. Fig. 6 is a schematic partial elevation

of another embodiment of the compressor's magnetic circuit.

Fig. 7 is a section similar to fig. 3 off

another embodiment.

As can be seen in particular from fig. 1, the compressor shown in the drawing comprises a carrier 1, which e.g. consists of a metal plate, and which is preferably suspended in the interior of a sealed container or bell, not shown, through which lines for the supply and discharge of fluid to be compressed, as well as electrical lines for feeding the drive device, are led, which will be described in the following.

Above, plate 1 carries blocks 2 and 3, on the outer side of which, e.g. by screws and

nuts 4 are attached to two equally vibrating eyes 5 and 6.

Looks 5 and 6, which e.g. is made of spring steel, carries underneath pieces 8, which are

attached to them by screws and nuts 7, and which are non-magnetic, but nevertheless preferably made of electrically conductive metal to allow the circulation of induced currents which may be produced during the operation of the compressor device, as will be described later.

The pieces 8 are shaped so that they at least partially enclose the permanent magnets 9 and 10, to which they are connected by hoop-shaped clamps 11, which have threaded ends for tightening nuts 12. 13 denotes wedges of non-magnetic metal inserted between the magnets 9 and the yoke part of the hoops 11. The magnets 9 and 10 can, according to an embodiment that is not shown, be embedded in a sleeve of non-magnetic metal, which possibly serves to connect the magnets with the cans 5 and 6.

The pieces 8 are connected at their lower end by rods 14 to pistons 15, arranged to be displaced in the interior of cylinders 16, which with their yoke parts 17 are fixed: on either side of an opening 18 in the plate 1. This opening can be placed in connection with the interior of the cylinders 16 by means of valves 19 to serve as compression chambers.

The pieces 8 also carry at bolts 20 tare masses 21 intended to communicate

the vibrating systems consisting of the tins 5, 6, the pieces 8, the magnets 9, 10 and the pistons 15, a desired correct vibration frequency.

The plate 1 carries, by means of connecting means not shown, a magnetic circuit which consists of two mutually identical elements 22 and 23. These two elements constitute e.g. of

stacks of mutually insulated magnetic tins and form two magnetic yokes, each of which is

synt with four pole pieces 24, 25, 26 and 27, resp. 24a, 25a, 26a and 27a.

The elements 22 and 23 are positioned so that their pole pieces 24, 25 and 24a, 25a on the one hand and the pole pieces 26, 27 and 26a, 27a on the other hand are at the height of the permanent magnets 9 and 10 respectively, which are carried by the cans 5 and 6.

The distance between the pole pieces 24—27 and the pole pieces 24a—27a is very close to the length of the magnets 9 and 10 so that the separating air gap is as small as possible, and these magnets are placed in such a way and have thus chosen thickness that in the rest position, where the flexible tins 5 and 6 stand vertically, at the edges facing the innermost parts of the pole pieces 24, 25, 24a, 25a resp. 26, 27, 26a, 27a. As can be seen in particular from fig. 3, each of the magnets 9 and 10 on the surfaces facing the pole pieces of the magnetic circuit are provided with flanges or end pieces 28 and 29, which consist of magnetisable metal, e.g. soft iron.

Thanks to the special arrangement of the magnets and pole pieces in the magnetic circuit, the magnetic field emanating from the magnets, when the device is at rest (in the position shown in the drawing), will connect through the magnetic circuit's two elements 22 and 23, as that these magnets do not run the risk of being demagnetized, which is essential to ensure a lasting undisturbed operation of the device.

In the embodiment shown in fig. 3, the pole pieces 25, 26, 25a, 26a of the magnetic circuit carry coils 30, 31 and 32, 33 respectively, which e.g. is connected in series and connected to an alternating current source with a fixed frequency, for example 50 periods which is most common.

It is assumed that the permanent magnets 9 and 10 have the polarities indicated in fig. 3, i.e. are arranged so that they have opposite polarity, the coils 30-33 produce at a given time t e.g. a south pole at 25 and consequently a north pole at 24. Pole 25a is the north pole, and pole 24a is the south pole, pole 26 is the north pole, and pole 27 is the south pole, pole 26a is the south pole, and pole 27a is the north pole.

The permanent magnets 9 and 10 therefore seek to move apart, so that the magnetic field joins through them via the poles 24, 27, 27a and 24a. At a time t + Y2 period, the pole pieces 24-27a have the opposite polarity to that shown in the drawing, but as the polarity of the magnets is unchanged, these seek to approach each other. The magnetic field therefore joins through the magnets and through the poles 25, 26, 26a and 25a.

At time t + 1 period, mag-

the pole pieces of the mains circuit again have the same polarity as shown in the drawing, and the magnets therefore move away from each other again, etc.

In the embodiment shown in fig. 4 and 5, the poles 24, 24a and 27, 27a are also equipped with coils 34, 35, 36 and 37 respectively. These coils are also connected to the previously mentioned coils 30-33, e.g. as shown in fig. 5, so that the polarities of the poles 24-27a when supplied with alternating current are the same as those shown in fig. 4, whereby the permanent magnets 9, 10 are to be placed in the same way as in fig. 3, and the device has a mode of operation corresponding to that already described.

In order for the compressor described above to work satisfactorily, and especially when it is used for cooling fluid in a refrigeration system, it is advantageous that the natural frequency of the vibrating systems which are formed by the cans 5 and 6, the pieces 8, the permanent magnets and the pistons, is slightly below the frequency of the alternating current the coils are fed with, due to the compressor, which of course works in synchronism with the frequency of the alternating current, is nevertheless not in resonance with this, which would cause the system's swinging movements to have an excessively large amplitude, which would especially threaten the pistons with destruction . This precaution also offers the advantage that the compressor will work closer to the resonance point the more the back pressure of the compressed fluid rises, which particularly occurs in a cooling apparatus when the ambient temperature rises and the resulting pressure rise in the condenser.

According to the embodiment shown schematically in fig. 6, the magnetic circuit comprises branches 22 and 23, which are made in the same way as in fig. 3, i.e. with two coils 32 and 33 on each branch.

In addition, a third coil 38 is placed between the cores 25a and 26a. This coil is connected in such a way in relation to the other coils that the lines of force at a given moment proceed as shown by the arrows in fig. 6, from which it appears that this last coil's flux constantly seeks to increase the magnetization of the magnets in view of the fact that the magnets are moved as explained above with reference to fig. 3.

Fig. 7 shows yet another variant, after which the permanent magnets 9 and 10, which form the anchors, are looped and replaced with lamella packs 39, 40 or possibly iron pieces, which here constitute the anchors carried by the cans. Before the magnetic circuit and the armatures are to be polarized anyway, permanent magnets are inserted into the yokes 22 and 23 of the magnetic circuit, respectively

9a and 10a, so that the field that is produced

of the coils 30, 31, 32, 33 (resp. 30, 31, 32, 33,

34, 35, 36, 37 by a device which in fig.

4), for each half period of the alternating current

alternately adds and withdraws

the flux of the permanent magnets.

Claims (6)

1. Oscillating compressor whose movement maintained between electromagnets, and comprising two vibrating eyes (5, 6) which are connected to compressor pistons (15) which are displaced in mutual opposition in cylinders (16), each carrying a polarized armature (9, 10—39, 40) arranged to to be displaced in an air gap limited by two equal elements (22, 23) of a magnetic circuit, characterized in that the magnetic circuit comprises eight poles arranged so that each armature (9, 10— 39, 40) in its rest position is placed between four poles, for the lines of force from the polarization field must join through the two elements of the magnetic circuit, and for an alternating field from coils fed directly with alternating current to join "along two separate paths passing through the respective different poles of the magnetic circuit and through the polarized armatures (9, 10— 39, 40), which is shifted to correspond at all times with the poles of the magnetic circuit which are currently traversed by lines of force from the alternating field in the same direction as the lines of force in the constant te polarization field. 2. Compressor as stated in claim 1, characterized in that the size of the polarized armatures (9, 10—39, 40) which are known per se are chosen so that they overlap edge portions of the four poles (24, 25, 24a, 25a—26, 27, 26a, 27a) that they face, before the lines of force from the permanent polarization field passing these poles must pass through the magnetic circuit and join through the two polarized armatures, which have mutually opposite polarity. 3. Compressor as stated in claims 1 and 2, characterized in that the polarized armatures (39, 40), which are carried by the cans (5 and 6), are made up of pieces of magnetisable metal, while the permanent magnets (9a, 10a) are inserted in the middle parts of the equal elements (22, 23) of the magnetic circuit. 4. Compressor as stated in claims 1 and 2, characterized in that the polarized armatures (39, 40), which are carried by the cans (5 and 6), are made up of pieces of magnetisable metal, while polarization coils (38) which are fed with direct current or rectified current, is placed in the middle part of the equal elements (22, 23) of the magnetic circuit. 5. Compressor as stated in claims 1-4, characterized in that the magnetic circuit comprises four coils (30, 31, 32, 33), which are fed in a manner known per se with alternating current and are placed on two and two of the four poles which faces each polarized anchor (9, 10—39, 40). 6. Compensator as stated in claims 1-4, characterized in that each pole in the magnetic circuit, which is known in and of itself, is provided with an inducing coil, which is fed directly with alternating current, and which is connected so that opposite poles of the two equal elements (22, 23) of the magnetic circuit always have opposite polarity.