FR2588133A1 - Multiphase electric motor with variable reluctance - Google Patents

Abstract

The electric motor can be of the linear or rotary type. It includes a stator provided with n windings 34, 36, 38 for creating magnetic flux in the direction of displacement of the movable core and a source 40, 42 enabling the windings to be supplied out of phase, each winding being associated with its own ferromagnetic circuit closing up through the core, characterised in that the core includes several ferromagnetic strips 18 parallel to the direction of displacement and each divided up in the longitudinal direction into contacts 20 with a specified pitch p and in that the ferromagnetic circuit of each winding also includes overlapping strips alternating with those of the core and also divided up into contacts 14 with the same pitch p. The core includes several ferromagnetic strips parallel to the direction of displacement and each divided up in the longitudinal direction into contacts with a specified pitch p and in that the ferromagnetic circuit of each winding also includes strips alternating with those of the core and also divided up into contacts with the same pitch p as that of the contacts of the core.

Description

Variable reluctance two-phase electric motor.

 The present invention relates to polyphase variable reluctance electric motors comprising a movable ferromagnetic core in a stator provided with m windings (m being at least equal to 3) allowing each to create a magnetic flux in the direction of movement of the movable core and a source allowing the windings to be supplied with a phase shift of 2w / m, each winding being associated with a clean ferromagnetic circuit closing by the core. It finds a particularly important application, although not exclusive, constituted by the linear actuators providing a high thrust. The invention aims in particular to provide such an electric motor making it possible to obtain a specific force, that is to say per unit mass of ferromagnetic material, greater than in existing electromagnetic devices.

 To this end, the invention provides an electric motor of the type defined above, the core of which comprises several thin ferromagnetic blades, parallel to the direction of movement, and each divided in longitudinal direction into studs with a determined pitch 2 and in that that the ferromagnetic circuit of each winding also comprises several thin blades alternating with those of the core and also split into studs at the same step 2 as that of the studs of the core.

 In the application of the invention to a linear electric motor, various constitutions of the blades are possible. In a first embodiment, the blades are carried by a common core of non-ferromagnetic material, for example stainless steel, constituting a pusher; the windings are each associated with a set of ferromagnetic blades of the stator, the blades of a set having an offset of p / m with respect to another set. In another embodiment, advantageous from the point of view of manufacturing, each blade is made up of alternating ferromagnetic metal and non-magnetic metal. It is possible in particular to use an alternation of tracks made of silicon steel, or failing that made of soft iron, and of stainless steel. The manufacture of identical blades can be carried out by brazing under vacuum, at a temperature of the order of 550., alternating studs made of silicon steel and ferromagnetic materials. Then the bar thus formed is cut longitudinally to give blades whose thickness can easily be reduced to about 1 mm.

 In the application of the invention to the production of a rotary machine, the windings can be provided to be traversed by an alternating current only (case of a rotary actuator). The coils can also be divided into two groups, one traversed by direct current, the other by alternating current or even the two currents can be superimposed in the same windings.

The invention will be better understood on reading the following description of a particular embodiment, given by way of non-limiting example. The description refers to the accompanying drawings, in which
FIG. t is a block diagram showing the fixed and mobile pads of a linear actuator constituting a first embodiment of the invention,
- Figures 2 and 3 are diagrams showing two balance arrangements that the blades can take in the device,
FIG. 4 is a simplified view, in elevation and in partial section, showing the overall constitution of a linear actuator constituted according to the principle shown in Fiv.1,
FIG. 5 is a perspective view of a fraction of an actuator of the type shown in FIG. 4,
FIG. 6 is a schematic view of a fraction of a rotary actuator according to another embodiment of the invention, in section along a plane passing through the axis,
- Figure 7 is a section along the line
VII-VII of Fig. 6,
FIG. 8 shows, in section along a plane passing through the axis of displacement, the main parts of a linear actuator constituting a variant of that of FIG. 4,
FIG. 9 is a sectional view along line IX-IX of FIG. 8,
- Figure 10 shows a stator blade usable in the actuator of Figure 8, in cross section.

 Figure 1 schematically shows the ferromagnetic elements, capable of relative displacement, of a linear actuator constituting a particular embodiment of an electric motor with variable reluctance according to the invention. The stator of this actuator comprises a large number of parallel stator blades 10, secured to each other by support means 12 of non-ferromagnetic material.

Only three blades 10 are shown in Fig.l but in practice the number will be significantly higher.

Each of the blades 10 is divided into independent pads 14 distributed at regular intervals, with a repeating step 2. Insulating zones 16 will generally be provided between the pads to improve the mechanical strength of the blade and these areas will be shorter than the pads in the direction of travel.

 The movable part of the actuator consists of a core also having several parallel blades 18, nested with the stator blades 10 and also made up of separate pads 20, distributed with the same pitch 2 as the pads 14. The blades 18 are joined by means not shown and their length must be greater than that of the blades 10, the excess length fixing the possible amplitude of movement of the blades. The clearances between adjacent blades 18 and 10 are as small as possible.

The assembly consisting of the stator and the core has two positions of equilibrium in a field B directed in the direction of the blades. One of them, shown in
Fig.2, is a position in conjunction with unstable equilibrium and corresponds to the maximum reluctance of the magnetic circuit traversed by the lines of force of a field created by an external winding not shown.

The second equilibrium position (Fig. 3) is stable and corresponds to a staggered arrangement of the studs 14 and 20.

If the magnetic field B is applied while the studs 14 have slightly exceeded the unstable equilibrium position where they are in conjunction (Fig. 2) to arrive for example in the arrangement shown in
Fig.1, the magnetic induction tends to bring the studs into the position of maximum flux shown in Fig.3: the blades 18 of the core then move until the studs are in the staggered position, or opposition shown in Fig. 3. If the induction field B is then cut, the blade remains in the new position.

 When it is desired to exert a propulsion force on the permanent core and to be able to control the direction of displacement of the core, it suffices to provide a number n, greater than or equal to 3, of successive modules such as module 22 which has just been described . The different modules can be placed in series or in parallel.

In Fig.1 has been represented a fraction of a second module 24, in series with the first. The winding creation windings will be supplied by excitation currents phase-shifted by T / n, T being the period of the supply current. And the pads 14 of two successive stators will be shifted by p / n.

 By giving the studs 14 a strip shape whose height is clearly greater (generally at least an order of magnitude) than the thickness, a polyphase machine is formed having a large number of active surfaces. The numerical calculation carried out by finite element decomposition shows that the electromagnetic forces generated per unit of useful surface are of the same order of magnitude as those obtained in variable reluctance devices of other type. Consequently, one can, by multiplying the number of blades and studs to have a large useful surface, arrive at specific thrusts (per unit mass of ferromagnetic material) markedly increased and arrive, at equal weight, comparable to those of fluid pressure devices.

 Fig.4 shows a possible constitution of a three-phase linear actuator corresponding to the diagram in Fiv.1. For this reason, the members of Fig.4 already shown in Fig.1 are designated by the same reference number.

 The movable core of the actuator comprises a non-magnetic core 12, for example made of stainless steel, which carries two series of blades 18, each series having for example five blades. The blades have a small thickness, advantageously of the order of a millimeter. They are made of magnetic material and permanently fixed to the core 12, for example by embedding and silver soldering. The blades are cut into regularly spaced pads 20, the pads of the two series facing each other. The distribution pitch of the pads 20 (length along the direction of movement increased by the interval between two successive pads) will generally be between 0.5 and 4 times the thickness of the blade. It can be seen that the studs thus take the form of thin strips. The intervals between successive lamellae can be filled with insulation.

 The stator comprises two parts symmetrical with respect to the axis of the pusher with three modules 22, 24, and 26. These modules being identical, only the module 22 will be described. In the module 22, each part of the stator comprises a support piece 28 made of non-magnetic material on which the corresponding studs 14 are brazed. The length of the supports 28 determines the useful area of the actuator. The blades provided in the three useful zones are separated by additional blades 30 also fixed but not split into studs. These blades 30 make it possible to complete the magnetic circuit of a carcass 32 on which are wound windings 34, 36 and 38 belonging respectively to modules 22, 24, and 26. All the sheets constituting the carcass 32 are made of ferromagnetic material. out of two protrudes in the interval between two successive blades belonging to the stator and comes to an end in the immediate vicinity of the blade of the corresponding core. We see that this arrangement allows to use the entire cross section of the carcass to transmit the flow, while only a fraction of the space at the stator blades is used to transmit the flow. This arrangement makes it possible to significantly reduce the size of the carcass.

 The stator plates of module 24 are offset by p / n with respect to those of module 22 and module 26.

 The windings 34, 36 and 38 are associated with a supply circuit which may include a source 40 of direct current and a chopper 42 supplying the windings with cyclic pulses at regular intervals. This chopper can be controlled by a core displacement sensor.

 Fig.5 shows a single inductor winding 34 carried by the closing circuit of the excitation field, constituted by a carcass 32 made of stacked sheets. These sheets have a thickness corresponding to that of the blades and nest in the uncut blades 30 belonging to the stator to ensure better circulation of the flux. The blades 30 therefore have a height greater than those of the blades 14. Finally, the carcass is mounted in a frame (not shown) carrying guide rails for the core.

 We see that we can make the range of movement as large as desired, simply by increasing the length of the blades 18. To avoid arriving at lengths reducing rigidity, we can also have several actuators end to end or in parallel.

The invention also makes it possible to produce rotating machines with an azimuth field, simply by closing the linear structure which has just been described. Figs 6 and 7 show a possible constitution of such a machine. The blades then take the form of parallel metal discs. Fig.6 shows such blades 10 belonging to the stator, alternating with blades 18, also disc-shaped, belonging to the core, formed by a rotor. The return circuit also consists of a carcass 32. Fig.7 shows the shape taken by the field lines B when the pads of the blades are in conjunction in the circumferential development zone i where the reluctance variations occur. This provision, like the previous one, can be modified to have an effect
Vernier. In the embodiments described above, the lamellae are separated by non-magnetic zones formed by air. If from an electromagnetic point of view we arrive at a completely satisfactory structure, manufacturing is complex. We will now describe, with reference to FIGS. 8 to 10, a linear actuator constituting a variant, the stator and rotor blades of which have a simpler constitution to manufacture.

 We see in Figures 8 and 9, where the organs corresponding to those of Figures 4 to 6 are designated by the same reference numbers, that the core blades are formed by alternating ferroma gnetic strips (in silicon iron for example ) and non-magnetic strips (in stainless steel for example) which replace the intervals occupied by air in the previous embodiment. The ferromagnetic lamellae will generally have a length in the direction of movement approximately twice the length of the nonmagnetic lamellae. The thickness of the strips will generally be of the same order as the length of the non-magnetic strips.

The manufacture of the blades can be as follows: an alternating stack of ferromagnetic and non-magnetic plates is made. All the plates are joined together under vacuum, staying below the point of
Curia, for example by silver brazing or electron beam welding. The stack is then cut to the desired thickness for the blades.

 The assembly of the blades can then be carried out in an absolutely conventional manner, by clamping between stirrups.

 The stator blades can have the same constitution as those which have just been described, by providing spacers having an increased length in the direction of movement to correspond to the interval between the coils. These spacers are made of ferromagnetic material and must have a size such that they allow the flow of flux during operation without reaching saturation.

 This same constitution of the blades can be used in the case of a rotary machine. In this case, the intervals separating the blades, shown in FIG. 7, will be occupied by a non-ferromagnetic metallic material such as stainless steel and all the lamellae will be joined in the form of an annular disc having alternating sectors, for example ferrosilicon and stainless steel. This arrangement, like the previous one, can be modified to obtain a Vernier effect.

 The invention is obviously not limited to the particular embodiments which have been shown and described and it should be understood that the scope of the present patent extends to any variant remaining within the framework of equivalences.

Claims (7)

 1. Polyphase variable reluctance electric motor, comprising a movable ferromagnetic core in a stator provided with m windings (34, 36, 38) for creating magnetic flux in the direction of displacement of the movable core and a source t40, 42) allowing d '' feeding the windings with a phase shift, each winding being associated with its own ferromagnetic circuit closing by the core, characterized in that the core comprises several thin ferromagnetic blades (18), parallel to the direction of movement and each split in the longitudinal direction in studs (20) with a determined pitch D and in that the ferromagnetic circuit of each winding also comprises several blades alternating with those of the core, nested with them and also split into studs (14) in step with the studs of the core.  2. Electric motor according to claim 1, characterized in that the studs (14,20) are in the form of strips having a height significantly greater than their thickness.  3. Electric motor according to claim 1 or 2, characterized in that the studs have a length significantly greater than the interval between successive studs.  4. Linear electric motor according to claim 1, 2 or 3, characterized in that the blades are carried by a common core of non-ferromagnetic material, for example stainless steel, constituting a pusher and in that the windings (34, 36 , 38) are each associated with a set of ferromagnetic blades of the stator, the blades of a set having an offset of p / m with respect to another set.  5. Electric motor according to claim 4, characterized in that the movable core comprises a non-magnetic core (12) carrying two opposite series of blades (18) each cooperating with one of two series of stator blades (10) for each winding , and in that the windings are carried by a magnetic flux closing carcass comprising additional blades (30) separating the series of blades directly associated with different windings.  6. Electric motor according to claim 4, characterized in that the movable core comprises adjacent blades each consisting of alternating ferromagnetic metal and non-magnetic metal,  7. A rotating electric motor according to claim 1, 2 or 3, characterized in that the windings are associated with means for circulating an alternating current and a direct current therein.