Abstract: In order to alleviate a user's burden of maintenance, the present invention calculates an actual lifetime of a cable, which is the intrinsic lifetime of the cable, and extends cable replacement cycles. Provided is a lifetime prediction device for a cable used in an industrial machine, the lifetime prediction device being provided with: a motion amount analysis unit that analyzes a motion amount of a motion axis of the industrial machine on the basis of a motion program for operating the industrial machine; and a lifetime calculation unit that calculates a predicted value of a lifetime of the cable by applying to the motion amount a relational expression between the motion amount and the lifetime of the cable based on the Eyring model.

Abstract: A method for producing a magnet plate for a linear motor is provided. The magnet plate comprises a base plate and a plurality of magnets juxtaposed to one another on a surface of the base plate. The method comprises providing the plurality of magnets on a surface of the base plate at a certain interval, placing the base plate into a mold, supplying a resin material into the mold, so as to form a resin molding covering the plurality of magnets on the surface of the base plate by means of injection molding, and magnetizing the plurality of magnets.

Abstract: A production adjustment system includes a cell including a plurality of machines, a cell control device which is communicably connected to the cell, to control the cell, and a higher-level management controller which is communicably connected to the cell control device, to acquire disaster information. The cell control device includes a command unit for issuing commands to the plurality of machines based on state information of the cell, which is acquired from the at least one sensor of the cell, and disaster information acquired from the higher-level management controller.

Abstract: A magnet plate includes a regulating member which is adapted to be press-fitted to a blind hole of a base plate. The regulating member protrudes from the surface of the base plate at one end, and prevents a permanent magnet from moving in a transverse direction. The regulating member has a narrower portion having a width smaller than the blind hole. Upon press-fitting of the regulating member, the base plate undergoes plastic deformation and the deformed portion moves into a space between the narrower portion and the inner wall of the blind hole.

Abstract: A machine control device includes a command unit that outputs individual operation commands to respective manufacturing machines; a power excess/shortage decision unit that decides whether time-series data on total power consumption of the manufacturing machines associated with the operation commands has maximum peak power larger than a power supply capacity of the power facility; and an operation command adjustment unit that adjusts the operation commands to the manufacturing machines from the command unit so as to adjust the maximum peak power to the power supply capacity of the power facility or less and maximize a production amount of the manufacturing machines.

Abstract: A production adjustment system includes a cell including a plurality of machines, a cell control device which is communicably connected to the cell, to control the cell, and a higher-level management controller which is communicably connected to the cell control device, to acquire disaster information. The cell control device includes a command unit for issuing commands to the plurality of machines based on state information of the cell, which is acquired from the at least one sensor of the cell, and disaster information acquired from the higher-level management controller.

Abstract: A fixture which secures a temperature detection element to a winding provided around a stator core of a motor, includes a main body to be inserted into a gap between the stator core and the winding, and an engagement portion formed on one end side of the main body on one side of the main body to engage with the rim of the opening of the winding. On the one side of the main body a recess is formed to house a temperature sensitive part of the temperature detection element. The depth of the recess is less than the maximum thickness of the temperature sensitive part of the temperature detection element.

Abstract: A fixture which secures a temperature detection element to a winding provided around a stator core of a motor, includes a main body to be inserted into a gap between the stator core and the winding, and an engagement portion formed on one end side of the main body on one side of the main body to engage with the rim of the opening of the winding. On the one side of the main body a recess is formed to house a temperature sensitive part of the temperature detection element. The depth of the recess is less than the maximum thickness of the temperature sensitive part of the temperature detection element.

Abstract: A method for producing a magnet plate for a linear motor is provided. The magnet plate comprises a base plate and a plurality of magnets juxtaposed to one another on a surface of the base plate. The method comprises providing the plurality of magnets on a surface of the base plate at a certain interval, placing the base plate into a mold, supplying a resin material into the mold, so as to form a resin molding covering the plurality of magnets on the surface of the base plate by means of injection molding, and magnetizing the plurality of magnets.

Abstract: A method for producing a magnet plate for a linear motor is provided. The magnet plate comprises a base plate and a plurality of magnets juxtaposed to one another on a surface of the base plate. The method comprises providing the plurality of magnets on a surface of the base plate at a certain interval, placing the base plate into a mold, supplying a resin material into the mold, so as to form a resin molding covering the plurality of magnets on the surface of the base plate by means of injection molding, and magnetizing the plurality of magnets.

Abstract: An electric motor includes a rotor including an iron core and a plurality of windings, and a stator including a plurality of permanent magnets forming a plurality of poles. The iron core has a plurality of primary teeth around each of which a winding is wound and a plurality of secondary teeth around each of which no winding is wound. The primary teeth and the secondary teeth are formed alternately with each other. The electric motor is configured such that a ratio between the number of poles formed by the permanent magnets of the stator and the number of phases formed by the windings of the rotor is 4m:3n (m and n are any natural numbers, excluding the case where m:n=2:3 is satisfied).

Abstract: A magnet plate includes a regulating member which is adapted to be press-fitted to a blind hole of a base plate. The regulating member protrudes from the surface of the base plate at one end, and prevents a permanent magnet from moving in a transverse direction. The regulating member has a narrower portion having a width smaller than the blind hole. Upon press-fitting of the regulating member, the base plate undergoes plastic deformation and the deformed portion moves into a space between the narrower portion and the inner wall of the blind hole.

Abstract: A method for producing a magnet plate for a linear motor is provided. The magnet plate comprises a base plate and a plurality of magnets juxtaposed to one another on a surface of the base plate. The method comprises providing the plurality of magnets on a surface of the base plate at a certain interval, placing the base plate into a mold, supplying a resin material into the mold, so as to form a resin molding covering the plurality of magnets on the surface of the base plate by means of injection molding, and magnetizing the plurality of magnets.

Abstract: A magnetic plate for a linear motor, a linear motor having the magnetic plate, and a method of manufacturing the magnetic plate, wherein the strength of a portion where the thickness of a resin layer is small is improved, while maintaining desired thrust force of the motor. A woven cloth such as a glass woven cloth or a carbon fiber woven cloth is attached on a surface of a plurality of permanent magnets, wherein N-poles and S-poles of the permanent magnets are alternately positioned. Then, a resin protecting layer is formed on the woven cloth by resin molding.

Abstract: The cooling means of the linear motor is formed of an assembly of plate parts adapted to dimensions of linear motor stator element plates on which magnets are disposed, piping, and bonding material for securing the plate parts and the piping to each other. Opposite ends of the plate parts are bent to form piping housing portions. The stator element plates and the plate parts are mounted to the machine while overlaid on each other. The piping is passed through the piping housing portions at the opposite ends of the plate parts. Thus, mounting of the cooling means is completed.

Abstract: An electric motor (10) comprising a stator core (11) in which slots (12) are formed, and a coil (20) is inserted in the slots. The slots are filled with an insulating resin (3), and the surface of the coil is coated with a coating layer, such as a phenol type epoxy powdery coating material or a phenol type varnish material. This prevents the insulating layer of the coil from being corroded by a strong alkaline liquid. The coating layer may have a thickness nearly equal to the thickness of an insulating paper. Further, the coating layer may have a thickness nearly equal to, or larger than, the thickness of the insulating paper.

Abstract: A linear motor (10) comprises a field portion (20) and an armature (15) arranged in predetermined spaced relation with the field portion and adapted to linearly move along the field portion. The field portion includes a plate (21), a plurality of permanent magnets (24) arranged adjacently to each other so as to arrange different polarities alternately on the plate, and mechanical fixing units (30) for fixing the permanent magnets mechanically on the plate. The permanent magnets are thus prevented from being separated under an external force which may be applied thereto. Each mechanical fixing unit each may include a cover portion (31) to cover the exposed surfaces of the permanent magnets. The mechanical fixing units are preferably formed of a non-or slightly-magnetic material.

Abstract: A linear driving device that reduces a cogging force with a simple structure as opposed to a drive mechanism having an existing structure, deals with a plurality of cogging waveforms having different periods, and suppresses not only the cogging force but also pitching that is vertical oscillation. The device has a structure provided with a plurality of magnet arrays in which permanent magnets having different polarities are alternately and rectilinearly arranged in the same direction, and a plurality of coil modules having a plurality of teeth and slots fitted with armature coils. The arrangement distance between the coil modules disposed along the displacing direction of each of the magnet arrays equals the sum or remainder of the length corresponding to a half of any one of periods possessed by the cogging force generated when the coil modules move by one magnetic pole and an integer multiple of the length of a magnetic pole pair.

Abstract: A field yoke (2) on which permanent magnets are mounted is fixed to a stationary member (1) of a machine. An armature (3) composed of coils is attached to a surface of a table (4), which is guided to move by a rectilinear movement guide (5), opposed to the field yoke (2). The field yoke (2) and the armature (3) constitute a linear motor. A compressed air feeding means (b) is mounted to the table (4). Compressed air jetting ports (6c) of the compressed air feeding means (6) are disposed ahead of and behind the table (4). While moving the table (4), compressed air is jetted to a movement surface, on which the table (4) moves, in order to remove foreign matter. Thus, as the movement surface on which the moving member (table (4)) of the linear motor moves is cleaned to remove the foreign matter, the movement of the table (4) is smooth. Moreover, the linear motor will not be damaged. This results in the linear motor capable of cleaning the movement surface on which the movable member of the linear motor moves.