FR2894092A1 - Rotor rotation detection device for e.g. generator, has three Hall effect sensors fixed on support integrated to stator, where support has five housings and is made of plastic or non-magnetic or metallic material with high Ohmic resistance - Google Patents

Abstract

The device has Hall effect sensors (40-u, 40-v, 40-w) associated to respective phases (U, V, W) of an electric rotating machine e.g. generator, and fixed on a support (30) integrated to a stator (2) of the machine. The support has housings (51 - 55) to position the sensors. The housings (51 - 54) are placed around a longitudinal axis (X) with an angular spacing of 40 degrees. The number of housings is greater than that of the sensors. The support is made of plastic or non-magnetic or metallic material with high Ohmic resistance.

Description

The present invention relates to rotating electrical machines. The

  US Patent 6,683,397 discloses a machine having a permanent magnet rotor and a stator having three Hall effect probes for detecting rotation of the rotor.

  In an exemplary implementation disclosed in this patent, the Hall effect probes are attached to the stator teeth and are engaged within the stator coils. Such an arrangement has the disadvantage that the Hall effect probes are exposed to the heat generated by the coils during operation of the machine, which may limit the operating temperature thereof to a value less than that which could be withstood by the machine. machine in the absence of Hall effect probes. In addition, the probes are arranged on three consecutive teeth of the stator. Depending on the polarity of the machine, the angular interval between two consecutive teeth may be relatively small, for example being 360 / (3xp) for a three-phase machine, where p is the number of pairs of poles. Thus, in the case of a machine with twelve poles, the angular difference is only 20. A small gap may complicate the placement of the probes. US Pat. No. 6,025,665 discloses a machine comprising three Hall effect probes arranged on a support comprising three corresponding housings. Japanese Patent Application 07-107707 discloses an electrical machine having three Hall effect probes disposed on the stator teeth. US Patent 5,864,192 discloses a three-phase four-pole machine having Hall effect probes disposed on a printed circuit with an angular gap of 52 between them. European patent application EP 1 010 660 A1 discloses a motor comprising three Hall effect probes arranged with an angular gap which is one-third of that existing between two poles of the rotor. There is a need to benefit from an electrical machine of easy construction, reliable and able to operate at a relatively high temperature if necessary. The invention aims in particular to meet this need.

  According to one of its aspects, the invention relates to a polyphase rotating electrical machine comprising: - a rotor, - a stator having a plurality of phases arranged circumferentially with a first angular difference between two phases, - a plurality of sensors magnetic sensors, in particular Hall effect probes, associated with the stator, at least two adjacent sensors being angularly spaced apart by a second angular interval, greater than the first. Such an arrangement of magnetic sensors facilitates their mounting on the machine. The machine may comprise a magnetic device associated with the rotor, interacting magnetically with the Hall effect probes. This magnetic device can have as many poles as the rotor. The magnetic device may include a pole wheel, which may be attached to a spacer carried by the rotor shaft. The magnetic device may comprise at least one mark materializing the location of a pole or a boundary between poles. The magnetic device may comprise as many pins as poles. The rotor may comprise four poles, the first angular difference being substantially 60 and the second angular difference substantially of 120. The rotor may comprise eight poles, the first angular difference being substantially 30 and the second angular difference being substantially 120. The rotor may comprise twelve poles, the first angular difference being substantially 20 and the second angular difference substantially of 40. The Hall effect probes are advantageously arranged on an attached support on the stator. Due to their mounting on a support mounted on the stator, the probes are not exposed directly to the heat generated by the stator coils, which may allow them, for example, to reach a temperature greater than 130.degree. for example between 130 C and 155 C. Moreover, the signals emitted by the probes are less likely to be parasitized by the leakage fluxes of the stator coil heads. The mounting of the probes does not require a stator having asymmetrical coils.

  The reliability of the operation of the machine is improved, regardless of its size. The support may comprise reliefs for positioning the Hall effect probes, each relief enabling the positioning of a probe in a predefined angular position on the support, the number of predefined angular positions being greater than the number of probes. This allows the use of the same support on machines with different polarities, which ensures an economy of scale. The reliefs may be housings, which may be recessed on a radially inner surface of the support. The machine may comprise a printed circuit associated with the support, having conductive tracks terminating in a plurality of connection pad groups, each array comprising at least as many pellets as the Hall effect probe has connection tabs to the printed circuit, the number of 15 groups being greater than that of the probes, each group being associated with a positioning relief of the probes on the support. The rotor may be permanent magnets. The machine may be a motor, the latter being for example capable of operating with a winding temperature greater than 130.degree. C. The invention also aims, independently or in combination with the foregoing, to facilitate the mounting of magnetic sensors. in particular Hall effect probes or inductive sensors, on an electric rotary machine. The object of the invention is therefore, according to another of its aspects, a device for detecting the rotation of the rotor of a rotating electrical machine, comprising: at least one magnetic device associated with the rotor, at least one associated support to the stator, a plurality of magnetic sensors, in particular Hall effect probes, which can be fixed on the support, the support comprising reliefs for positioning the magnetic sensors, each relief being associated with a predefined angular position on the support, the number of predefined angular positions being greater than the number of magnetic sensors.

  The reliefs may comprise housings in which the magnetic sensors may be arranged. The reliefs can be made hollow on a radially inner surface of the support.

  The number of predefined angular positions may be greater than 3, being for example 5. The angular difference between the predefined positions may be 40 or 120, in the case of a three-phase machine. The device may comprise a printed circuit associated with the support, having conductive tracks terminating in a plurality of connection pad groups, each array comprising at least as many pellets as the magnetic sensor has connection tabs to the printed circuit, the number of groups being greater than that of the sensors, each group being associated with a positioning relief of the sensors on the support.

  The electric machine can be two poles, the sensors being arranged on the support with an angular spacing of substantially 120 between them. The rotor may comprise four poles, the sensors being disposed on the support with an angular spacing between them of substantially 120. The rotor may comprise eight poles, the sensors being arranged on the support 20 with an angular spacing between them of substantially 120. The rotor may comprise six poles, the sensors being arranged on the support with an angular difference between them of substantially 40. The rotor may comprise twelve poles, the sensors being disposed on the support with an angular difference between them of substantially 40. The magnetic device may comprise a pole wheel, which may be multipolar, being magnetized radially or axially. The device may comprise a spacer arranged to be fixed at the end of the shaft and receiving the pole wheel. The invention will be better understood on reading the detailed description which will follow and on examining the appended drawing, in which: FIG. 1 is a partial and diagrammatic representation, in exploded perspective, of a machine produced in accordance with FIG. an example of implementation of the invention, - Figure 2 is a longitudinal section, partial and schematic, of the machine of Figure 1; - Figure 3 represents, in perspective, the support of the Hall effect probes; FIG. 4 is a perspective view of the polar wheel, FIG. 5 is a top view of the polar wheel, and FIGS. 6 to 10 illustrate examples of positioning of the probes for different polarities of a polar wheel. FIG. three-phase machine. FIGS. 1 and 2 show diagrammatically an electric machine 1, for example a synchronous machine with permanent magnets, for example a motor. The machine 1 comprises a stator 2 and a rotor 3, partially shown. The rotor 3 comprises a shaft 4 rotating around a longitudinal axis X. The stator 2 comprises at least one flange 6 housing a bearing 7 supporting the shaft 4. The machine 1 is for example a three-phase machine and the rotor comprises by example 2, 4, 6, 8 or 12 poles. The stator 2 may be distributed winding or concentrated winding. The machine 1 comprises a rotation detector 10 which comprises, on the one hand, a rotating magnetic device 11 associated with the rotor 4 and, on the other hand, a static detection device 12, associated with the stator 2. In the example shown, the rotating magnetic device 11 comprises a pole wheel 14 which is fixed on the shaft 4 by means of a spacer 15, which is for example retained on the shaft 4 by a screw 17 engaged in a housing 18 located at the end shaft. The spacer 15 comprises a housing 19 in which is fitted the end of the shaft 4 having passed through the bearing 7, the shaft 4 coming axially bearing against the bottom of this housing 19.

  The spacer 15 is shouldered externally so as to accommodate the pole wheel 14 which is located axially for example substantially at the free end of the shaft 4. The pole wheel 14 is for example glued to the spacer 15.

  In the example considered, the pole wheel 14 has as many poles as the rotor 3, in this case eight poles in the example shown in FIGS. 4 and 5. The pole wheel 14 is for example made of ferrite and has a magnetization radial, with alternating N and S poles in the circumferential direction. The pole wheel 14 may also be made of ferrite, plasto-ferrite, NdFeBr, plasto-NdFeBr or SmCo. The polar wheel 14 has, in the example under consideration, marks 20 which embody the separation of the poles as well as polarizers 21 which make it possible to mount the polar wheel 14 on the spacer 15 with a predefined orientation. The polarizers 21 are for example notches opening on an axial face 22 of the pole wheel 14 and the pins 20 are for example grooves oriented axially and extending on the radially outer face of the pole wheel 14 between the axial faces. The static detection device 12 comprises a support 30 secured to the stator, being for example fixed on the flange 6 in an angularly adjustable manner, for example by means of two diametrically opposite screws 33, as illustrated in FIG. comprises in the example considered an annular rib 70, of axis X, which is engaged in the flange 6 and which makes it possible to rotate the support 30 on itself about the axis X before tightening the screws 33, which come press while tightening on a peripheral flange 72 of the support 30.

  In the example illustrated, the machine being three-phase, the detection device comprises three probes 40 ,,, 40, and 40, Hall effect, respectively associated with the phases U, V and W of the machine. Probes 40 ,,, 40, and 40w are exposed to the magnetic field of the pole wheel 14, which rotates opposite the probes being separated from them by a radial air gap. The support 30 comprises positioning reliefs of the probes, composed of recesses 51 to 55 of shape adapted to that of the probes.

  The support is for example made of a plastic material or any other non-magnetic material or a magnetic or non-magnetic metal, laminated or high ohmic resistivity to avoid losses due to eddy currents. In the example under consideration, these housings 51 to 55 are made recessed on the radially inner surface of the support, and each comprise two opposite ribs 57 for retaining the probes. The housings 51 to 54 are arranged around the X axis with an angular distance of 40 between them and the housing 55 is disposed with an angular spacing of 120 relative to each of the housing 51 and 54. The presence of housing 51 to 55 in number greater than the probes 40 ,,, 40, and 40, to position the latter in a configuration adapted to the polarity of the rotor. For example, in the case of a two-pole rotor, the three probes can be positioned respectively in the housings 51, 54 and 55, which corresponds to an angular difference of 120 between two adjacent probes, as illustrated in FIG. In the case of a four-pole rotor, the probes 40 ,,, 40, and 40, can be arranged at 120 from each other as illustrated in Figure 7, while the angular difference 13 between the phases of the stator is 60. FIG. 8 illustrates the case of a six-pole rotor, for which the angular difference between the probes 40, 40, and 40 is 40, the probes being arranged in the consecutive housings 51 to 53 of FIG. support 30, for example. For an eight-pole rotor, as illustrated in FIG. 9, the probes 40, 40, 40 and 40W can be arranged at 120 from one another while the angular difference 13 between the phases of the stator is 30. FIG. 10 illustrates the case of a twelve-pole rotor, for which the probes 40, 40, and 40 are arranged with an angular spacing of 40 between them, the probe 40 being arranged between the probes 40 and 40 ,. The angular difference 13 between phases is 20. The detection device 12 comprises a printed circuit 60 which is perforated at its center to provide access to the screw 17 and which comprises conductive tracks 30 leading to clusters of pellets 61 for receiving the connecting tabs of the probes.

  These groups 61 are arranged on the printed circuit 60 as the housing of the support 30. The printed circuit 60 has at its periphery a notch 63 intended to receive a tooth 66 of the support 30.

  Fixing the printed circuit 60 on the support 30 can be effected by means of a screw 67, as shown in FIG. 2. The printed circuit 60 can also support an electronic circuit for shaping the signals delivered by the probes 40, , 40, and 40, and, if appropriate, processing these signals.

  The processing of the signals emitted by the probes can be done taking into account the fact that, depending on the polarity of the machine, the probes located in some of the housing of the support can correspond to different phases. To mount the detection device 12, the support 30 is fixed in the flange 6 of the machine, without tightening the screws 33. Then, it is possible to feed the phases of the stator so that the rotor is in front of the phase U of the stator. The support 30 can then be rotated relative to the stator in order to have the probe 40a facing a corresponding pole of the pole wheel 14, with the aid of the marks 20. The support 30 can then be locked in position by tightening the screws 33. Of course, the invention is not limited to the illustrated example.

  The machine can be a generator. The detection device 10 can be mounted on the inside of a flange of the machine. The processing of the signals emitted by the probes can be carried out in a drive controlling the machine and not in an electronic circuit associated with the printed circuit or, alternatively, partially in such an electronic circuit and partially in the drive. The gap between the polar wheel and the probes may be axial, in a variant not illustrated. The machine may have a number of phases other than three.

  The Hall effect probes can be replaced by other magnetic sensors, for example induction.

  The expression containing one must be understood as being synonymous with at least one, unless the opposite is specified.

Claims (13)

  1. Device (10) for detecting the rotation of the rotor of a rotating electrical machine, comprising: - at least one magnetic device (11) associated with the rotor, - at least one support (30) associated with the stator, - a plurality magnetic sensors, in particular Hall effect probes (40u, 40 ,, 40w), which can be fixed on the support, the support comprising reliefs for positioning the magnetic sensors, each relief being associated with a predefined angular position on the support , the number of predefined angular positions being greater than the number of magnetic sensors.   2. Device according to the preceding claim, wherein the reliefs comprise housings in which can be arranged the magnetic sensors.   3. Device according to the preceding claim, the reliefs being made recessed on a radially inner surface of the support.   4. Device according to any one of the preceding claims, the number of predefined angular positions being greater than 3.   5. Device according to any one of the preceding claims, the angular difference between the predefined positions being 40 or 120.   6. Device according to any one of the preceding claims, comprising a printed circuit (60) associated with the support, having conductive tracks resulting in a plurality of sets of connection pads, each group comprising at least as many pellets as the probe. the Hall effect comprises conductors connecting to the printed circuit, the number of connection pad groups being greater than that of the probes, each group being associated with a positioning relief of the probes on the support.   7. Device according to any one of the preceding claims, the electric machine being two poles, the sensors being disposed on the support with an angular distance between them of 120.   8. Device according to any one of claims 1 to 6, the rotor having four poles, the sensors being disposed on the support with an angular distance between them of 120.   9. Device according to any one of claims 1 to 6, the rotor having eight poles, the sensors being disposed on the support with an angular spacing between them of 120.   10. Device according to any one of claims 1 to 6, the rotor having six poles, the sensors being disposed on the support with an angular distance between them of 40.   11. Device according to any one of claims 1 to 6, the rotor having twelve poles, the sensors being disposed on the support with an angular distance between them of 40.   12. Device according to claim 11, the magnetic device comprising a pole wheel (14).   13. Device according to any one of the preceding claims, comprising a spacer (15) arranged to be fixed at the end of the shaft and receiving the pole wheel.