An electromagnetic rotating motor system that comprise of a grooved wheel with one or more permanent magnets tangentially embedded in a horse-shoe pattern within the groove around the wheel rim with similar poles pointing in the same direction and wherein induction coils or electromagnets are positioned to fit tangentially between the permanent magnet(s) in the groove with the pole axis of the electromagnet parallel to that of the permanent magnets and with the coiling and powering made such that it generates magnetic poles that are similarly aligned to the poles of the permanent magnets such that when current is passed through the coil, the poles of the electromagnet and the permanent magnet repel each other forcing the wheel holding the magnets to rotate away from the coil.

An electromagnetic rotating motor system that comprise of a grooved wheel with one or more permanent magnets tangentially embedded in a horse-shoe pattern within the groove around the wheel rim with similar poles pointing in the same direction and wherein induction coils or electromagnets are positioned to fit tangentially between the permanent magnet(s) in the groove with the pole axis of the electromagnet parallel to that of the permanent magnets and with the coiling and powering made such that it generates magnetic poles that are similarly aligned to the poles of the permanent magnets such that when current is passed through the coil, the poles of the electromagnet and the permanent magnet repel each other forcing the wheel holding the magnets to rotate away from the coil.

An encoder includes: a magnet rotatably supported; a control board including a magnetic field sensor that detects a magnetic field produced by the magnet and outputs a signal, and an arithmetic unit that detects rotation of the magnet on the basis of the output of the magnetic field sensor; a magnetic shielding cover made of a soft magnetic material; an encoder bracket used to fix the magnetic shielding cover; a protective cover fixed with being sandwiched between the magnetic shielding cover and the encoder bracket to cover the magnet and the control board to prevent entry of foreign substances; and a sealing member sandwiched between the protective cover and the encoder bracket. The magnetic shielding cover covers the magnet, the control board, and the protective cover, and the sealing member is compressed between the encoder bracket and the protective cover.

An encoder includes: a magnet rotatably supported; a control board including a magnetic field sensor that detects a magnetic field produced by the magnet and outputs a signal, and an arithmetic unit that detects rotation of the magnet on the basis of the output of the magnetic field sensor; a magnetic shielding cover made of a soft magnetic material; an encoder bracket used to fix the magnetic shielding cover; a protective cover fixed with being sandwiched between the magnetic shielding cover and the encoder bracket to cover the magnet and the control board to prevent entry of foreign substances; and a sealing member sandwiched between the protective cover and the encoder bracket. The magnetic shielding cover covers the magnet, the control board, and the protective cover, and the sealing member is compressed between the encoder bracket and the protective cover.

Sensor bearing unit providing at least two bearings stacked one relative to the other and each having an inner ring and an outer ring, the sensor bearing unit having a sleeve radially surrounding the bearings and having a radial projection in axial contact with one of the bearings, an annular flange having a radial portion in axial contact with the other bearing and an axial portion radially surrounding the sleeve and connected to the sleeve, and a wire carrier configured to support at least one wire and at least one connector, the wire carrier includes at least one fastening element mounted on the bearing.

A position detecting purpose permanent magnet 51 constituting a position detection sensor is installed at an opposite side to an output side of a rotational shaft 45 of a rotor housed within a motor housing 11A. A GMR element 56 which constitutes the position detection sensor and a position detection circuit thereof are installed on a side of a motor cover 48 on which a position detection purpose permanent magnet 51 is arranged. GMR element 56 is arranged on a position opposed against the position detection purpose permanent magnet. Thus, since the GMR element and the position detection purpose permanent magnet is installed, a mutually positioning assembly (attachment) accuracy can be improved. In addition, since the electric power conversion circuit and both of the GMR element and its position detection circuit are kept away, such an effect that an accurate detection signal can be obtained can be achieved.

The Spiral Helix Electromagnetic Linear Pulse Motor is based on the three dimensional operational design Helix Rotation Concept, where the basic helix rotation concept, is a linear axis parallel electromagnetic pulse, or wave, created by the sequential activation, deactivation, and polarity reversal, of electromagnetic constructs arranged in a linear row, forming a linear array, parallel to the driveshaft axis, with a 360 degree spiral helix magnetic construct array around/along the length of the driveshaft, magnetically interacting with the electromagnetic pulse/wave created by the linear electromagnetic array. As a result of the electromagnetic wave/pulse traversing parallel to the axis across the linear electromagnetic array and synchronizing with the spiral helix magnetic array in a sequential linear manner, the device converts electromagnetic energy into continuous useful rotational mechanical energy.

The Spiral Helix Electromagnetic Linear Pulse Motor is based on the three dimensional operational design Helix Rotation Concept, where the basic helix rotation concept, is a linear axis parallel electromagnetic pulse, or wave, created by the sequential activation, deactivation, and polarity reversal, of electromagnetic constructs arranged in a linear row, forming a linear array, parallel to the driveshaft axis, with a 360 degree spiral helix magnetic construct array around/along the length of the driveshaft, magnetically interacting with the electromagnetic pulse/wave created by the linear electromagnetic array. As a result of the electromagnetic wave/pulse traversing parallel to the axis across the linear electromagnetic array and synchronizing with the spiral helix magnetic array in a sequential linear manner, the device converts electromagnetic energy into continuous useful rotational mechanical energy.

A motor includes a shaft member in which at least a part of an outer peripheral surface is made of metal, a magnet unit which is configured by integrating a plurality of magnets and in which a press-fit hole into which the shaft member is press-fitted is formed, a substrate which is disposed at a predetermined distance from the magnet unit in an extending direction of the shaft member and to which electric power is supplied, and a protective member in which a through-hole into which the shaft member is inserted is formed and which is disposed between the magnet unit and the substrate in the extending direction of the shaft member. In the motor, the protective member is in contact with at least a part of the outer peripheral surface of the shaft member.

A motor includes a shaft member in which at least a part of an outer peripheral surface is made of metal, a magnet unit which is configured by integrating a plurality of magnets and in which a press-fit hole into which the shaft member is press-fitted is formed, a substrate which is disposed at a predetermined distance from the magnet unit in an extending direction of the shaft member and to which electric power is supplied, and a protective member in which a through-hole into which the shaft member is inserted is formed and which is disposed between the magnet unit and the substrate in the extending direction of the shaft member. In the motor, the protective member is in contact with at least a part of the outer peripheral surface of the shaft member.