A position sensor is configured to use a Wiegand wire, position magnet(s) and a reset magnet in which changes in polarization of the Wiegand wire caused by the position magnet(s) can be reset by the reset magnet. The position magnet(s), which can move in relation to the Wiegand wire, can have relatively stronger magnetic flux densities, and the reset magnet, which can be fixed in relation to the Wiegand wire, can have a relatively weaker magnetic flux density. When the position magnet(s) are proximal the Wiegand wire, the relatively stronger position magnet(s) overcome the reset magnet to cause a change in polarization of the Wiegand wire which produces an electrical pulse which can be counted. However, when the position magnet(s) become distal to the Wiegand wire, the relatively weaker reset magnet can reset the polarization of the Wiegand wire to prepare for a next count. As a result, the total number of magnets required in the system can be reduced, and the probability of failing to reset the Wiegand wire can be lowered.

The magnetic sensing portion 30 of the rotation sensing device comprises three magnetic sensors 31-33 and a substrate 45 for mounting these magnetic sensors, with each magnetic sensor comprising a magnetic wire 34 generating large Barkhausen effects, a coil 35, and a bobbin 36. The magnetic sensors are disposed on the substrate 45 such that the directions of extension of the magnetic wires 34 are parallel to the substrate 45, the magnetic sensing portion 30 is disposed on the outer periphery of the trackway of the magnetic field forming portions such that the directions of extension of the magnetic wires 34 are parallel to the axial direction of the rotary shaft 3, and the location of the magnetic wire installation portion 38 in the bobbin 36 of each magnetic sensor is configured such that the respective magnetic wires 34 of the three magnetic sensors are respectively equidistant from the rotary shaft 3.

A battery-free rotation detecting device includes a rotating carrier, a first magnetic element, a second magnetic element and at least one detection coil set. The rotating carrier can be assembled with a rotating element. The first magnetic element is disposed to the rotating carrier, and the second magnetic element is also disposed to the rotating carrier but spaced from the first magnetic element. The at least one detection coil set is located between the first magnetic element and the second magnetic element. The rotating carrier can be driven by the rotating element so as further to rotate the first magnetic element and the second magnetic element synchronously. The at least one detection coil set generates an electrical signal upon when a change of the magnetic field between the first magnetic element and the second magnetic element is detected.

A magnet-based rotary angle sensor system for detecting a shaft rotation. The magnet-based rotary angle sensor system includes a rotatable excitation unit which is mounted to a shaft for rotation therewith, and a static sensor unit. The rotatable excitation unit includes at least one excitation magnet. The static sensor unit detects an excitation-magnetic field generated by the at least one excitation magnet. The static sensor unit includes a first Wiegand sensor module and a second Wiegand sensor module which are arranged in a cross-shaped manner and axially spaced from each other.

A magnetic sensor configured to detect a rotation of an object includes at least one sensor element configured to generate at least one sensor signal based on a magnetic field that is modulated by the rotation of the object; a sensor circuit configured to generate a data transmission signal based on the at least one sensor signal, wherein the data transmission signal comprises a plurality of data transmission blocks; and a memory configured to store transmission block status information indicative of whether or not one of the plurality of data transmission blocks has been triggered for transmission. The sensor circuit is configured to detect an interrupt event that disrupts the transmission of the data transmission signal and avoid a complete loss of a data transmission block due to the detected interrupt event based on the transmission block status information present at a time the interrupt event is detected.

A motor according to an embodiment includes a motor body, a rotating body, and a magnetic field sensor. The motor body rotates a shaft about the axis line thereof. The rotating body includes a permanent magnet and rotates along with the rotation of the shaft. The magnetic field sensor includes a magnet body having a large Barkhausen effect with the long direction thereof serving as the easy magnetization direction and is positioned to face the permanent magnet when the rotational position of the rotating body is at a given rotational position. The easy magnetization direction of the magnetic body is in a direction along a plane orthogonal to the rotation center line of the rotating body.

A method assesses the rotational speed of a machine, and more particularly the rotational speed of a rotating equipment prime mover controlled by a governor. Such machines include turbo machinery and relate to a measurement device for measuring speed. The method measures a number of pulses during a measurement interval, determines a portion of a pulse pattern, determines an integration period, and calculates the rotational speed based on the portion of the pulse pattern.

A magnetic-field sensor device includes at least two impulse wires, a coil assembly which radially surrounds the at least two impulse wires, the coil assembly defining a sensor element and a feedback element which generates an auxiliary magnetic field, an energy storage which is electrically connected to the coil assembly, a switching element which is electrically connected to the energy storage and to the feedback element, and a control unit which electrically controls the switching element.

Position sensor for determining the number of repeating courses of movement of an object and of the precise posture of the object in relation to a reference posture, wherein the position sensor has the following: a Wiegand module, which is composed of a Wiegand wire having a coil that surrounds the Wiegand wire; a magnetic temporary storage, which is in addition to the Wiegand module; a first sensor element and a second sensor element; a processing electronic circuit, which is configured to evaluate or to determine an output signal that is output by the sensor elements and an information that is stored in the magnetic temporary storage; and a permanent magnet arrangement, which is movable relatively to the Wiegand module in one direction as well as in a direction that is opposite to said one direction, wherein the permanent magnet arrangement is configured to be arranged at the object such that the permanent magnet arrangement performs the repeating courses of movement together with the object; wherein: upon movement of the permanent magnet arrangement in said one direction, the coil of the Wiegand module produces a voltage impulse, if a north pole or a south pole of the permanent magnet arrangement is located at a first position, and, upon movement of the permanent magnet arrangement in said opposite direction, the coil of the Wiegand module produces the voltage impulse, if the north pole or the south pole of the permanent magnet arrangement is located at a second position that is different from the first position; upon movement of the permanent magnet arrangement, the magnetic poles of the permanent magnet arrangement come to pass the magnetic temporary storage such that the magnetic temporary storage stores the information, which indicates, whether the north pole or the south pole of the permanent magnet arrangement has lastly come to pass the magnetic temporary storage; in an autonomous mode, in which the position sensor is not supplied with outside energy, the processing electronic circuit is supplied with energy, which is provided by the Wiegand module; the processing electronic circuit is configured to, after the determining of the voltage impulse, which is output from the Wiegand module, to determine a value, which corresponds to a number of repeating courses of movement of the permanent magnet arrangement, namely by the evaluation of the output signal of the first sensor element; in a non-autonomous mode, in which the position sensor is supplied with outside energy, the processing electronic circuit is further configured to continuously receive posture information about the precise posture of the permanent magnet arrangement in relation to the ref

The invention relates to a counting sensor for counting the number of rotations or of linear displacements of an object, wherein the counting sensor comprises: one single Wiegand module; at least one sensor element; a processing electronic circuit, which is connected to the sensor element; and a permanent magnet arrangement, which is movable relatively to the Wiegand module; wherein the processing electronic circuit is configured to obtain direction information, whether the permanent magnet arrangement moves in said one direction or in an opposite direction, and (ii) to obtain magnetic pole information; and a data storage for storing a value, which indicates the number of the rotations or of the linear displacements; wherein: the processing electronic circuit is configured (i) to determine, on the basis of the direction information and the magnetic pole information, the number of the rotations or of the linear displacements of the object and to store the corresponding value in the data storage, (ii) to perform, on the basis of a sequence of the direction informations and of the magnetic pole informations, an error detection to the effect whether one of the rotations or one of the linear displacements of the object has not been recognized partially or completely, and (iii) to determine an according correction and to correct the value upon detection of an error.