A linear motor system that can extend the stroke of a linear motor, with power saving and at a low cost, is provided. In a linear motor system, constituted by a linear motor 100, a controller 7 for supplying a variable voltage, a winding switching device 6, for opening and closing phase windings 5 o
A linear motor system that can extend the stroke of a linear motor, with power saving and at a low cost, is provided. In a linear motor system, constituted by a linear motor 100, a controller 7 for supplying a variable voltage, a winding switching device 6, for opening and closing phase windings 5 of individual phases that form a plurality of winding groups 4 that are separated in a stroke direction, the winding switching device 6 is constituted by a three-phase rectifying member, a semiconductor switch, which is located at both ends on the direct-current output side of the three-phase rectifying member, and a resistor and a capacitor, connected in parallel to the semiconductor switch. For each of the phase windings, which form the plurality of winding groups 4, separated in the stroke direction, one end is connected to the output end of the controller 7 and the other end is connected to an alternating-current input side of the three-phase rectifying member of the winding switching device 6. And by opening or closing the semiconductor switch included in the winding switching device 6, of the plurality of winding groups 4 separated in the stroke direction, only a desired winding group 4 is excited.
대표청구항▼
The invention claimed is: 1. A linear motor system, comprising: a linear motor, wherein a moving element, which includes magnetic loading member formed of permanent magnets, and a stator, which includes magnetic loading member formed of windings having winding faces opposite the permanent magnets,
The invention claimed is: 1. A linear motor system, comprising: a linear motor, wherein a moving element, which includes magnetic loading member formed of permanent magnets, and a stator, which includes magnetic loading member formed of windings having winding faces opposite the permanent magnets, are positioned opposite each other, separated by a gap, and wherein the stator is formed of a plurality of winding groups separated in a stroke direction, and phase windings of individual phases that form each winding group, to include a winding start terminal and a winding end terminal; a controller, for supplying a variable voltage having a variable frequency to the linear motor; and a winding switching device, for closing or opening, as needed, the phase windings for the individual phases that form the plurality of winding groups separated in the stroke direction, wherein the winding switching device includes; a three-phase rectifying member, a semiconductor switch located on both direct-current output sides of the three-phase rectifying member and a resistor and a capacitor connected in parallel to the semiconductor switch, one end of each of the phase windings, which form the plurality of winding groups separated in the stroke direction, is connected to an output end of the controller, and the other end is connected to an alternating-current input side of the three-phase rectifying member of the winding switching device, and the semiconductor switch included in the winding switching device is opened or closed to excite only a desired winding group of the plurality of winding groups separated in the stroke direction. 2. The linear motor system according to claim 1, wherein for the winding groups that form the stator, at least a sensor, for detecting at least one moving element or more that is opposite, is provided in the stroke direction; and based on a signal from the sensor, the semiconductor switch of the winding switching device connected to a winding group, which is opposite the moving element, is closed. 3. The linear motor system according to claim 1, wherein when Lc denotes a length, in the stroke direction, of a winding group forming the stator, and Lml denotes a length of the moving element, in the stroke direction, determining Lc and Lml in order to establish the relationship Lml=n×Lc n: an integer of two or greater, and exciting only a winding group entirely opposite the moving element in the stroke direction. 4. The linear motor system according to claim 1, wherein when Lc denotes a length in the stroke direction of a winding group forming the stator, and Lms denotes a length of the moving element in the stroke direction, arranging, in the stroke direction, a plurality of moving elements for which the relationship Lms=Lc/n n: an integer of two or greater is established, attaching the moving elements to a fixed plate at a moving element arrangement pitch Lmp to establish the relationship Lmp=Lms×(n+1), and exciting only winding groups that the moving elements are entirely opposite to in the stroke direction. 5. The linear motor system according to claim 1, wherein the winding groups that serve as the electricity loading member, the detection sensor for detecting the moving element and a processing circuit for processing a sensor from the detection sensor are respectively mounted on substrates on which a pattern is formed; and a plurality of the substrates are coupled by connectors to form the stator. 6. A linear motor system, comprising: a linear motor wherein a moving element, which includes magnetic loading member, formed of permanent magnets, and a stator, which includes magnetic loading member formed of windings having winding faces opposite the permanent magnets, are positioned opposite each other, across a gap, wherein the stator is formed of a plurality of winding groups separated in a stroke direction, and phase windings of individual phases, which form each winding group, include a winding start terminal and a winding end terminal, and wherein sensors, for detecting that the moving element is entirely opposite, are respectively provided for the windings in the stroke direction; a controller for supplying a variable voltage variable frequency; and a winding switching device that includes; a three-phase rectifying member, a semiconductor switch, located on both direct-current output sides of the three-phase rectifying member, and a resistor and a capacitor, arranged in parallel to the semiconductor switch, wherein the winding start terminal of each of the phase windings, which form the plurality of winding groups separated in the stroke direction, is connected to an output terminal of the controller, and the other end is connected to an alternating-current input side of the three-phase rectifying member, of the winding switching device, and the semiconductor switch included in the winding switching device is closed, to excite the plurality of winding groups separated in the stroke direction, when Lc denotes a length of each of the winding groups in the stroke direction, and Lm denotes a length of the moving element in the stroke direction, determining Lc and Lm to establish the relationship Lm=n×Lc n: 2 or 3; and providing, for each of the winding groups, a signal preparation circuit that employs a signal from a sensor prepared for a winding group and a signal from a sensor prepared for at least one of the winding groups adjacent to that winding group, and prepares a signal for opening and closing the winding switching device that is connected to the winding groups. 7. The linear motor system according to claim 6, wherein the signal preparation circuits output signals to always set n-1 winding groups in an excited state. 8. The linear motor system according to claim 7, wherein each of the signal preparation circuits is constituted by a logic circuit, for outputting a signal that is obtained by performing an AND process for a signal output by a sensor arranged for a winding group for which the signal preparation circuit is provided, and an inverted signal of a signal output by a sensor arranged for one of winding groups adjacent to the winding group. 9. The linear motor system according to claim 7, wherein each of the signal preparation circuits is constituted by a logical circuit, which employs, as an output signal, the results obtained by performing an AND process for a signal output by a sensor arranged for a winding group for which the signal preparation circuit is provided, and a signal that is obtained by performing an AND process for signals output by two sensors arranged for both winding groups adjacent to the winding group and by inverting the resultant signal. 10. A linear motor system, wherein a plurality of stator blocks, each of which includes a linear motor stator and armature windings having a plurality of phases, are arranged linearly, and wherein an armature element side is constituted by a set of permanent magnets and a secondary conductor, comprising: a winding switching circuit, wherein one terminal of each of the armature windings in each of the plurality of stator blocks is connected to each phase line of one linear motor driving servo amplifier, and the other terminal of the armature winding is connected to a middle point of a diode bridge having a plurality of phases, a semiconductor switch device is connected between a positive common terminal and a negative common terminal of the diode bridge, a series circuit, formed of a first reflux diode, a discharge resistor and a second reflux diode, is connected in parallel to the semiconductor switch, and a smoothing capacitor is connected in parallel to the discharge resistor, and when the semiconductor switch is sequentially turned on or off, based on a position signal from a moving element position sensor that is arranged on the linear motor stator side, the armature windings having a plurality of phases are switched between an excited state and an unexcited state. 11. The linear motor system according to claim 10, wherein the same number of winding switching circuits as the plurality of stator blocks are provided. 12. The linear motor system according to claim 10, wherein the moving element position sensor generates a drive signal for the semiconductor switch device to sequentially switch the plurality of stator blocks.
Hoffmann Bernhard (Starnberg DEX) Nipper Bernhard (Brunswick DEX) Wolff Dieter (Goslar DEX), Method for switching current to successive sections of the stator of a long linear motor.
Hommes William J. (Hockessin DE) Keegan ; Jr. John J. (Wilmington DE), System useful for controlling multiple synchronous secondaries of a linear motor along an elongated path.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.