FR3064134A1 - ELECTRICAL POWER COMPRESSOR WITH MAGNET HOLDER - Google Patents

Abstract

The present invention relates to an electric supercharger comprising: - a wheel for compressing air, - an electric motor driving the wheel in rotation via a shaft (3), the electric motor comprising a rotor (9) mounted on the shaft (3) and a stator in which is housed the rotor (9), - a first balancing means (11) of the shaft positioned downstream of the rotor (9), - a device electronic, the shaft (3) being rotated relative to the electronic device about an axis of rotation (A), and - a Hall effect sensor comprising a Hall effect probe positioned on the electronic device and a magnet fixed around a lower end portion (8) of the shaft (3), the magnet being positioned facing the Hall effect probe. According to the invention, the compressor comprises a magnet support (10) in which the magnet is housed. The magnet support (10) forms a second balancing means of the shaft positioned upstream of the rotor (9).

Description

Holder (s): VALEO MOTOR CONTROL SYSTEMS Simplified joint-stock company.

Extension request (s)

Agent (s): VALEO MOTOR CONTROL SYSTEMS.

ELECTRIC BOOSTER COMPRESSOR WITH MAGNET SUPPORT.

FR 3 064 134 - A1 (6 /) The subject of the present invention is an electric supercharging compressor comprising:

- a wheel to compress air,

- an electric motor driving the rotating wheel via a shaft (3), the electric motor comprising a rotor (9) mounted on the shaft (3) and a stator in which the rotor (9) is housed ,

a first balancing means (11) of the shaft positioned downstream of the rotor (9),

an electronic device, the shaft (3) being in rotation relative to the electronic device about an axis of rotation (A), and

- a Hall effect sensor comprising a Hall effect probe positioned on the electronic device and a magnet fixed around a lower end part (8) of the shaft (3), the magnet being positioned opposite the Hall effect probe.

According to the invention, the compressor comprises a magnet support (10) in which the magnet is housed. The magnet support (10) forms a second means for balancing the shaft positioned upstream of the rotor (9).

Electric supercharger with magnet holder

The present invention relates to an electric supercharger, and more particularly to an electric supercharger for a motor vehicle.

It is known to use an electric supercharger in an air supply circuit for an internal combustion engine of a motor vehicle.

Such an electric supercharging compressor is conventionally implemented in the air intake line of a thermal combustion engine of a motor vehicle, upstream or downstream of a turbocharger. As a variant, as described in the French patent application published under the number FR 2 991 725, such a compressor can be implemented on an exhaust gas recirculation line of the internal combustion engine.

The electric supercharging compressor conventionally comprises a wheel intended to compress the air entering the compressor and an electric motor to drive the wheel in rotation.

The electric motor is conventionally an electric motor comprising a stator and a rotor positioned inside the stator. The rotor is intended to drive the wheel through a shaft rotating around a shaft.

The electric supercharger also includes an electronic device supporting the shaft. The shaft is rotated relative to the electronic device. The electronic device is connected to an electronic module managing the speed of rotation of the electric supercharging compressor.

For this, it is necessary to know the angular position of the tree. A Hall effect sensor is usually used, comprising a Hall effect probe positioned on the electronic device and a magnet fixed around the shaft.

The magnet is positioned opposite the Hall effect probe and includes several magnetic poles.

The rotation of the magnet causes a variation in magnetic flux around the Hall effect probe, which is an image of the position of the rotor of the rotating machine.

The electric supercharger also includes balancing means for balancing the rotor including a first balancing disc positioned upstream of the rotor and a second balancing disc positioned downstream of the rotor.

These first and second balancing discs are positioned on each side of the rotor, and fixed on the shaft. To balance the rotor or more precisely the shaft, rotor and bearings assembly, material can be removed from the discs by machining.

These balancing discs are two separate parts which can be fitted, glued or riveted to the shaft during the manufacturing process, requiring two operations and therefore a significant assembly time.

In addition, the presence of these discs leads to high inertia, increasing the response time of the electric supercharger.

The invention therefore aims to overcome these drawbacks of the prior art by proposing a simpler electric supercharger, comprising fewer elements and making it possible to reduce the manufacturing time.

The invention relates to an electric supercharger comprising:

a wheel for compressing air, an electric motor driving the wheel in rotation via a shaft, the electric motor comprising a rotor mounted on the shaft and a stator in which the rotor is housed, a first means for balancing the shaft positioned downstream of the rotor, an electronic device, the shaft being in rotation relative to the electronic device about an axis of rotation A, and a sensor comprising a probe positioned on the electronic device and a magnet fixed around a lower end part of the shaft, the magnet being positioned opposite the probe.

According to an embodiment of the invention, the second part of the magnet support comprises at least one recess for balancing the shaft.

According to one embodiment of the invention, the first balancing means comprises at least one recess for balancing the shaft.

According to the invention, the electric supercharger includes a magnet support in which the magnet is housed. The magnet support forms a second means of balancing the shaft positioned upstream of the rotor.

Alternatively, the magnet holder is fixed around the shaft.

According to another variant, the magnet support has a cylindrical shape and comprises a first part in which the magnet is housed and a second part forming the second balancing means.

According to another variant, the recesses are distributed around a peripheral surface of the second part of the magnet support.

As a variant, the first part of the magnet support surrounds and at least partially compresses the external peripheral surface of the magnet.

The invention thus provides a simpler electric supercharging compressor, comprising fewer elements, making it possible to reduce the manufacturing time.

The second balancing disc used according to the prior art and positioned between the rotor and the magnet, is eliminated.

This simplifies parts management.

The invention also makes it possible to simplify the manufacturing process by reducing the number of manufacturing steps since a step of fitting a second balancing disc onto the shaft is eliminated.

In addition, the inertia of the rotor mounted on the shaft is reduced. The removal of a part on the shaft makes it possible to lighten the assembly and to obtain a lower inertia compared to a shaft comprising two balancing discs. The response time of the compressor is therefore reduced.

The imbalance value is also better distributed over the two bearings compared to a shaft comprising two balancing discs creating a greater imbalance on the front bearing. Balancing is therefore more efficient.

The magnet holder also makes it possible to maintain the magnet on the shaft in order to avoid any parasitic movement which could adversely affect the position measurement and therefore the accuracy.

The characteristics of the invention will be described in more detail with reference to Figures 1 to 3 in which:

Figure 1 is a schematic representation of an electric supercharger;

FIG. 2 is a schematic representation of a shaft provided with a magnet support according to an embodiment of the invention a) before balancing, b) after balancing;

The present invention relates to an electric compressor 1.

In the context of the invention, the expression electric compressor 1 means an air compressor, volumetric or not and for example centrifugal or radial, driven by an electric motor, with the aim of supercharging a heat engine. According to one embodiment of the invention, the electric motor is an asynchronous DC or alternating current motor, or any type of electric motor of the same type.

More specifically, according to one embodiment of the invention, the electric motor is a variable reluctance motor (also called SRM machine for Switched Reluctance Motor according to English terminology).

According to another embodiment of the invention, the motor is a permanent magnet motor.

FIG. 1 represents an electric supercharging compressor 1 comprising a wheel 2 for compressing air. The wheel is a paddle wheel 2, and comprises several blades 15.

The electric supercharger 1 comprises an electric motor driving the wheel 2 by means of a shaft 3 rotating about an axis of rotation A.

The electric motor comprises a rotor 9 mounted on the shaft 3 and a stator (not shown), in which the rotor 9 is housed.

The wheel 2 is mounted at one end 16 of the shaft 3.

The shaft 3 is rotated relative to the electronic device 4 around the axis of rotation A.

More specifically, the electronic device 4 comprises a support 17 on which the shaft 3 is mounted and an electrical connector 18 for connecting it to an electronic module (not shown).

The electric supercharger 1 includes one or more bearings.

The electric supercharger 1 comprises a sensor 5 comprising at least one probe 6 positioned on the support 17 of the electronic device 4. And for example, the compressor comprises three probes.

According to an embodiment of the invention, the sensor is a Hall effect sensor 5 and the probe is a Hall effect sensor 6.

The electric supercharger 1 comprises a magnet fixed around a lower end part 8 of the shaft 3.

The magnet is positioned opposite the Hall effect probe 6 and has an outer peripheral surface of circular section. The magnet is a permanent magnet comprising several magnetic poles.

An air gap is formed between the magnet and the probe 6.

The rotation of the magnet causes a variation in magnetic flux around the probe 6, which is an image of the position of the rotor 9 of the electric supercharging compressor 1.

For a "Switch Hall" type sensor, the accuracy of the measurement is directly linked to the magnetic slope from the change from one polarity to the other of the magnet. With a multipolar magnet, the counting of the polarity jumps makes it possible to produce a position sensor.

The magnet has a cylindrical shape with a circular section. It completely surrounds the lower end part 8 of the shaft 3.

As illustrated in FIG. 2a, the electric supercharger 1 comprises a magnet support 10 in which the magnet is housed.

The magnet support 10 prevents the magnet from being deformed and maintains the magnet on the shaft 3 in order to avoid any parasitic movement which could adversely affect the position measurement and therefore the accuracy.

According to one embodiment, the magnet support 10 is for example metallic and consists of a non-magnetic material.

According to one embodiment, the magnet is held in place by gluing.

The electric supercharging compressor 1 in FIG. 1 comprises means for balancing the conventional shaft 3 / rotor 9 assembly comprising a first balancing disc (not shown in FIG. 1) positioned downstream of the rotor 9 and a second balancing disc 19 positioned upstream of the rotor 9.

The downstream (rear) and upstream (front) are defined with respect to direction B, but according to another embodiment of the invention, are also defined with respect to a reverse direction of B.

Tree 3 extends in direction B.

In the compressor part according to the invention illustrated in FIGS. 2 a, before balancing and 2 b after balancing, the magnet support 10 forms a second balancing means positioned upstream of the rotor 9, replacing the second disc. balancing as used in the prior art.

The electric supercharging compressor 1 comprises a first balancing means 11 for the shaft positioned downstream of the rotor 9.

The first balancing means 11 is fixed around the shaft 3 and is integral with the rotor 9.

For example, the first balancing means 11 has a disc shape and includes a central orifice for its introduction around the shaft 3.

The magnet support 10 is distant from the rotor 9. The rotor 9 is positioned between the first balancing means 11 and the magnet support 10.

The magnet support 10 has a cylindrical shape and comprises a first part 12 in which the magnet is housed and a second part 13 forming the second means for balancing the shaft.

The magnet support 10 includes a central hole 24 through which the shaft 3 is inserted.

The first part 12 of the magnet support 10 is positioned opposite the probe 6.

According to one embodiment, the second part 13 of the magnet support 10 has a disc shape with a smaller diameter than the first part 12 which also has a disc shape.

In this embodiment, the electric supercharging compressor 1 comprises two bearings 20, 21 including a first bearing 20 positioned at the lower end portion 8 of the shaft 3, upstream of the magnet support 10 and a second bearing 21 positioned at the upper end 16 of the shaft 3, downstream of the rotor 9.

The first bearing 20 is positioned near the magnet support 10.

The second bearing 21 is positioned near the rotor 9.

The first balancing means 11 is positioned between the rotor 9 and the second bearing 21.

FIG. 2b illustrates a part of the compressor after balancing in which the second part 13 of the magnet support 10 comprises at least one recess 14 for balancing the rotor 9.

The recesses 14 are distributed over the peripheral surface 22 of the second part 13 of the magnet support 10.

According to one embodiment of the invention, the first balancing means 11 comprises at least one recess 23 on its peripheral surface to balance the shaft 3 and the rotor 9.

The balancing of the rotor 9 is carried out for an electric supercharging compressor 5 1 fully assembled (shaft + rotor + bearings + wheel ...).

The geometry of the first 11 and second balancing means (second part 13 of the magnet support 10) is defined according to unbalance calculations of the assembled rotor (calculation of the different unbalances of each part of the assembled rotor) and according to inertia calculations of the assembled rotor.

More precisely, in the context of the invention, balancing consists in measuring two unbalances generally on the running surfaces.

Depending on this measurement, the recesses are placed on the balancing means. The corrections consist of recesses.

The unbalances have an angular level and phase (vector representation 15 in the two planes). The level and phase will determine where the recesses will be made.

Thus, the recesses of the balancing means are made after mounting of various elements of the compressor: shaft, stator, wheel ...

The magnet support 10 therefore has two functions including a function of clamping / supporting the magnet and a function of balancing the shaft.

Claims (8)

1. Electric supercharger (1) comprising: - a wheel (2) for compressing air, - an electric motor driving the wheel (2) in rotation via a shaft (3), the electric motor comprising a rotor (9) mounted on the shaft (3) and a stator in which the rotor is housed (9), - a first balancing means (11) of the shaft positioned downstream of the rotor (9), - an electronic device (4), the shaft (3) being in rotation relative to the electronic device (4) about an axis of rotation (A), and - a sensor (5) comprising a probe (6) positioned on the electronic device (4) and a magnet fixed around a lower end part (8) of the shaft (3), the magnet being positioned in manhole of the probe (6), characterized in that it comprises: - a magnet support (10) in which the magnet is housed, said magnet support (10) forming a second means for balancing the shaft positioned upstream of the rotor (9). 2. An electric supercharger (1) according to claim 1, comprising a second part (13) of the magnet support (10) comprising at least one recess (14) for balancing the shaft (9). 3. Electric supercharger (1) according to one of claims 1 or 2, in which the first balancing means (11) comprises at least one recess (23) for balancing the shaft (9). 4. Electric supercharger (1) according to one of claims 1 to 3, in which the sensor (5) is a hall effect sensor and the probe (6) is a hall effect sensor. 5. Electric supercharger (1) according to one of claims 1 to 4, wherein the magnet support (10) is fixed around the shaft (3). 6. Electric supercharger (1) according to one of & of claims 2 to 5, wherein the magnet support (10) has a cylindrical shape and comprises a first part (12) in which is housed the magnet and a second part (13) forming the second balancing means. 5 7. An electric supercharger (1) according to claim 6, in which the recesses (14) are distributed around a peripheral surface (22) of the second part (13) of the magnet support (10). 8. An electric supercharger (1) according to claim 7, wherein the first part (12) of the magnet support (10) surrounds and at least partially compresses the external peripheral surface of the magnet.