FR3028613A1 - MAGNETIC TARGET - Google Patents

Abstract

The invention relates to a magnetic target (3) in particular arranged to be mounted on a component (2) capable of sliding along an axis (X), this component being notably a piston, this target comprising: - two magnets (10, 11) separated by non-magnetic space (12).

Description

The present invention relates to a magnetic target in particular arranged to be mounted on a slidable component. The aim of the invention is to improve this type of magnetic target. The invention thus particularly relates to a magnetic target in particular arranged to be mounted on a component capable of sliding along an axis, this component being in particular a piston, this target comprising: - two magnets separated by nonmagnetic space. Thanks to the invention, having the two separate magnets reduces the magnetic field in the space between the magnets, which allows to have a more intense magnetic field near the axial ends of the target. Due to these higher fields in the useful areas, the target and an associated sensor are less susceptible to external magnetic interference. Moreover, the amount of magnet to be used is reduced, which makes it possible to be more economical. In addition, the invention makes it possible to have a strong magnetic slope, which is favorable in the case of commutation or "switch" by allowing a better precision of the commutation. The invention can thus allow to have a single type of magnets for two types of applications, namely in linear and switching. In addition, two short magnets are generally easier to manufacture than a long magnet. In an exemplary implementation of the invention, the magnets are arranged to produce a magnetic field at least a portion of the field lines is perpendicular to the axis of sliding of the component.

Advantageously, one of the magnets is arranged to produce a magnetic field with a first sense of magnetization and the other magnet is arranged to produce a magnetic field with a second sense of magnetization opposite to the first direction of magnetization, the first and second second sense of magnetization being in particular parallel and opposite. At least one of the magnets preferably has a radially outer wall substantially in a portion of a cylinder, in particular in a portion of a cylinder of revolution.

The magnets may have identical shapes and dimensions. The accumulated magnetic field advantageously produced by the two magnets has a minimum amplitude in a space between the two magnets.

For example, this minimum amplitude is between 20 milliTesla and 30mT, especially between 20 mT and 25 mT. The magnetic field advantageously has two maxima each associated with one of the magnets. These maxima are notably substantially equal.

In an exemplary implementation of the invention, one of the maxima is between 30 mT and 35 mT. Advantageously, the magnetic field has minimum values at the ends and in the middle of the sliding component stroke. The minimum values at the ends of the stroke can make it possible to optimize the volume of the magnets and thus to reduce the cost. The target may include a spacer arranged in the nonmagnetic space. For example, the spacer is made of plastic. The spacer advantageously has a wall portion of 30 cylinder.

3028613 3 Where appropriate the spacer has an outer wall in the extension of the outer walls of the magnets. Alternatively, the space between the two magnets is formed by air.

If desired, at least one of the magnets has a cylindrical shape, in particular of revolution, with an axis parallel to the axis of sliding. At least one of the magnets may have a semi-cylindrical shape of revolution, with an axis parallel to the axis of sliding.

In an exemplary implementation of the invention, the at least one of the magnets comprises a plane face in particular parallel to the sliding axis, in particular two parallel plane faces. Advantageously at least one of magnets is made of ferrite. Alternatively, at least one magnet is made of rare earth.

If desired, the target comprises at least three magnets including substantially aligned. The invention also relates to a component capable of sliding along a sliding axis comprising a target as described above.

The component advantageously forms a piston. This piston is in particular able to move on a predetermined stroke. The target is for example at least partially inserted into a piston body.

The piston is advantageously arranged to operate with a clutch system, in particular operating by hydraulic pressure. The invention also relates to a system, in particular for a motor vehicle, comprising: a component as described above, a sensor arranged to be sensitive to the magnetic field generated by the target, in particular to provide a 3028613 4 information representative of the position or speed of the sliding component. The position or speed could be replaced by another parameter of the sliding component.

Thanks to the invention, the magnetic field produced by the magnets is maximum at the ends of the race of the sliding component, in places where a measurement by the sensor must be made accurately. The sensor is for example Hall effect. Preferably, the sensor and the target are associated with a clutch system 10, in particular by hydraulic pressure, with a brake pedal, a turbo actuator or a valve, in particular an exhaust gas recirculation valve. The invention will be better understood and other details, features and advantages of the invention will become apparent on reading the following description given by way of non-limiting example with reference to the appended drawing in which: FIG. schematic and partial sectional view of a system according to an exemplary embodiment of the invention, - Figure 2 shows, schematically and partially, a target of the system of Figure 1, and - Figure 3 illustrates the variation. the magnetic field produced by the target of Figure 2 as a function of the sliding component stroke.

FIG. 1 shows a system 1 for a motor vehicle, comprising: a component 2 capable of sliding along an axis of sliding X and comprising a magnetic target 3, a sensor 4 arranged to be sensitive to the magnetic field generated by the target 3, so as to provide information representative of the position or velocity of the sliding component 2. The component 2 is a piston capable of moving on a predetermined path S.

The target 3 is carried by a body 6 of the piston 2. The piston 2 is, in the example described, arranged to operate with a clutch system operating by hydraulic pressure. The sensor 4 is mounted on a printed circuit board 7, for example by welding. The sensor 4 is Hall effect. This sensor may be a linear or switching sensor ("Switch"). Instead of a Hall effect sensor, it is possible to provide a magnetoresistance sensor. The magnetic target 3 comprises two magnets 10 and 11 separated by non-magnetic space 12.

The sensor 4 is positioned centrally, in a direction perpendicular to the X axis, with respect to the magnets 10 and 11. In the example described, the magnets 10 and 11 are arranged to produce a magnetic field M whose lines of field are perpendicular to the axis of sliding X of the piston 2.

Alternatively, field lines make an angle with the X axis greater or smaller than 90 °. As illustrated in FIG. 2, the magnet 10 is arranged to produce a magnetic field with a first magnetization direction and the other magnet 11 is arranged to produce a magnetic field with a second sense of magnetization opposite the first sense of magnetization. , the first and second sense of magnetization being in particular parallel and opposite. As can be seen in FIG. 3 with the curve C1, having the two magnets 10 and 11 separated makes it possible to reduce the magnetic field in the space between the magnets 10 and 11, which makes it possible to have a more intense magnetic field near the axial ends 14 and 3028613 of the target 3. Thanks to these higher fields in the useful zones, the target 3 and the associated sensor 4 are less sensitive to external magnetic interference and the measurements are more precise. In the example described, the cumulative magnetic field produced by the two magnets 10 and 11 has a minimum amplitude in a space 12 between the two magnets, as visible on the curve C1. This minimum amplitude is between 20 mT and 25 mT. The magnetic field has two maxima on both sides of this minima.

These maxima are in particular substantially equal and are between 30 mT and 35 mT. It can be seen in FIG. 3 with the curve C2 which is representative of the case where the space 12 is filled with a magnet, that the invention makes it possible to avoid an area of strong magnetic field where it is not possible. The invention notably makes it possible to reduce the volume of the magnets with respect to the case of curve C2 with a long single magnet. In the example described, the magnets 10 and 11 each have a radially outer wall 20 substantially in the form of a 20-revolution cylinder portion. Magnets 10 and 11 have identical shapes and dimensions. The target 3 comprises a spacer 22 arranged in the non-magnetic space 12.

The spacer 22 is made of plastic material and has a cylindrical portion wall 23 in the extension of outer walls 24 of the magnets 10 and 11. The magnets 10 and 11 have a semi-cylindrical shape of revolution, of parallel axis to the sliding axis X.

The magnets 10 and 11 are made of ferrite.

3028613 7 The piston can be equipped with an anti-rotation system, if necessary. 5

Claims (14)

REVENDICATIONS1. Magnetic target (3) in particular arranged to be mounted on a component (2) capable of sliding along an axis (X), this component notably being a piston, this target comprising: two magnets (10, 11) separated by non-magnetic space ( 12). 2. Target according to the preceding claim, characterized in that the magnets are arranged to produce a magnetic field at least part of the field lines (M) is perpendicular to the axis of sliding of the component. 3. Target according to one of the preceding claims, characterized in that one of the magnets (10, 11) is arranged to produce a magnetic field with a first direction of magnetization and the other magnet is arranged to produce a field magnet with a second sense of magnetization opposite the first direction of magnetization, the first and second sense of magnetization being in particular parallel and opposite. 4. Target according to one of the preceding claims, characterized in that at least one of the magnets has a radially outer wall (20) substantially in a portion of a cylinder, in particular in a portion of a cylinder of revolution. 5. Target according to one of the preceding claims, characterized in that the cumulative magnetic field (M) produced by the two magnets has a minimum amplitude in a space between the two magnets. 3028613 9 6. Target according to the preceding claim, characterized in that this minimum amplitude is between 20 milliTesla and 30mT, in particular between 20 mT and 25 mT. 5 7. Target according to one of the preceding claims, characterized in that the magnetic field has two maxima each associated with one of the magnets. 10 8. Target according to the preceding claim, characterized in that one of the maxima is between 30 mT and 35 mT. 9. Target according to one of the preceding claims, characterized in that it comprises a spacer (22) disposed in the nonmagnetic space. 10. Target according to the preceding claim, the spacer (22) being made of plastic. 20 11. Component capable of sliding along a sliding axis comprising a target according to one of the preceding claims. 12. Component according to the preceding claim, forming a piston. 13. Component according to claim 12, the piston being arranged to operate with a clutch system, in particular by hydraulic pressure. 14. System, in particular for a motor vehicle, comprising: - a component according to one of claims 11 to 13, a sensor arranged to be sensitive to the magnetic field generated by the target, in particular to provide representative information the position or speed of the sliding component. 5 10