The invention pertains to a multipolar magnetic ring constructed to be mounted on a rotating member for the purpose of generating an alternating magnetic signal. It is known that magnetic field sensors, such as those used in roller bearings have an encoder consisting of a multipolar magnetic ring which moves in front of a pulse counting sensor as the member rotates. This type of ring requires additional means of assembly and positioning.

Multipolar magnetic rings are known which have a magnetized ferromagnetic ring, the circumference of which consists of multiple segments with magnetic poles, each of which has a North pole and a South pole, located, respectively, between two poles of the opposite polarity. Such a ring requires the use of a ferromagnetic support and the application of a specific magnetizing procedure before assembly. The procedure is so difficult to use that the segments must be reduced in length if the magnetic material is to be saturated over the total thickness of the ring.

To obtain a high degree of precision in measuring of position or angular displacement, the ring must have a large number of poles. Moreover, when the encoder and the sensor are far apart, the encoder must generate a powerful magnetic field, either by the use of large quantities of magnetic material or by the use of specific materials such as rare earths, which offer high coercive fields but require a significant amount of magnetizing energy, which is incompatible with multipolar magnetization.

An object of the invention is a composite multipolar magnetic ring, the construction of which does not require any specific or complex magnetizing process, each part being subjected to bipolar magnetization before assembly.

Briefly described, the multipolar magnetic ring comprises a first ring having circumferentially spaced teeth. The teeth form identical magnetic poles. The multipolar magnetic ring has a coaxial second ring with circumferentially spaced teeth, with the teeth of the second ring forming identical magnetic poles. The magnetic poles of the first ring are located between the magnetic poles of the opposite polarity of the second ring.

The invention, as well as its many advantages, may be further understood by the reference to the following detailed description and drawings in which:

FIG. 1 is a preferred embodiment of the invention;

FIG. 2 shows the two rings in position ready for assembly;

FIG. 3 is a perspective view of one of the rings; and

FIG. 4 is a view taken along line x--x of FIG. 3.

Referring to the drawings and more particularly to FIG. 3, a bipolar ring 4 consists of an annular support 1, which holds teeth 2 pointing radially inward toward the center 0. Teeth 2 are equally spaced apart around the inside perimeter of the annular support, separated by spaces 3. Each tooth is magnetized to provide a North-South magnet.

By way of example, annular support 1 and teeth 2 can be produced simultaneously by a molding process, but teeth 2 can also be cast onto the support, whether or not the support is magnetic.

The multipolar magnetic ring 10 shown in FIG. 2 consists of two identical bipolar magnetic rings 4, 4,, each with the same geometry and magnetic characteristics. As shown in FIG. 3 and FIG. 4, the radially extending axial end surfaces 12 of the teeth 2 are axially spaced from the radially extending axial end surface 14 of annular support 1. As shown in FIG. 1 when assembled, the radially extending axial end surfaces of each ring extend along the same radial plane as the corresponding radially extending axial end surfaces of the other ring. The magnetic poles of each ring are embedded between the magnetic poles of the opposite polarity of the other ring.

Without going beyond the scope of the invention, it is possible for teeth like teeth 2 to face radially outwardly from the outside perimeter of annular support 1.