The present disclosure relates to systems and methods for identifying a magnetic mover.
Motion stages (e.g. XY tables and rotary tables) are widely used in various manufacturing, inspection, and assembling processes. A common solution currently in use achieves XY motion by stacking together two linear stages (e.g. an X-stage and a Y-stage) via connecting bearings. A more desirable solution involves having a single moving stage capable of XY motion, eliminating the need for additional bearings. It might also be desirable for such a moving stage to be able to provide at least some Z motion. Attempts have been made to design such displacement devices using the interaction between current-carrying coils and permanent magnets. For example, a magnetic mover may be displaced relative to stator operable to generate one or more magnetic fields.
One problem with such systems, however, is that it may be difficult for a controller of the stator to distinguish one mover on the stator from other movers on the stator.
Generally, according to embodiments of the disclosure, there is described a system comprising one or more magnetic movers and one or more stators. A stator defines a work surface, for example a 2D planar work surface, and comprises an actuation coil assembly for driving movement of the one or more magnetic movers over the work surface. The stator comprises at least one stator identification device which in some embodiments is a first magnetically responsive unit (1st MRU). A magnetic mover comprises at least one mover identification device, which in some embodiments is a second magnetically responsive unit (2nd MRU). The 1st and 2nd MRUs, and more generally the stator identification device and the mover identification device, are operable to interact with one another, for example through magnetic induction. According to some embodiments, rather than using magnetic induction, interaction between the stator identification device and the mover identification device may be active rather than passive. For example, the stator identification device may initiate communication with the mover identification device and request that the mover identification device transmit identification or other information to the stator identification device. Alternatively, the mover identification device may periodically transmit identification or other information to the stator identification device, for example.
The system may further comprise one or more sensors for sensing a position of the magnetic mover. Based on the position of the magnetic mover, a controller may control one or more stator driving circuits to drive the actuation coil assembly to thereby move the magnetic mover over the work surface. In particular, the actuation coil assembly may interact with one or more magnetic components (such as one or more magnet arrays) on the mover to cause movement of the mover over the work surface. The movement may be in at least two or more degrees of freedom, for example in the x and y directions.
According to a first aspect of the disclosure, there is provided a system comprising: at least one magnetic mover including a first magnetic mover, wherein the first magnetic mover comprises at least one mover identification device; a stator defining a work surface and comprising: an actuation coil assembly comprising a plurality of actuation coils; and at least one stator identification device operable to interact with the at least one mover identification device; one or more sensors for sensing a position of the first magnetic mover; and one or more stator driving circuits for driving the actuation coil assembly to thereby move the first magnetic mover over the work surface, wherein the first magnetic mover comprises one or more magnetic components positioned such that interaction of one or more magnetic fields emitted by the one or more magnetic components with one or more magnetic fields generated by the actuation coil assembly when driven by the one or more stator driving circuits enables movement of the first magnetic mover in at least two degrees of freedom.
The work surface may separate the first magnetic mover from one or more of the actuation coil assembly and the at least one stator identification device.
The at least two degrees of freedom may comprise orthogonal x-axis and y-axis degrees of freedom.
The work surface may extend in an x-y plane.
The one or more magnetic components may be a first magnetically responsive unit.
The at least one stator identification device may be a stator coupling coil assembly.
The at least one mover identification device may be a second magnetically responsive unit.
The at least one mover identification device may comprise at least one mover inductive coil.
The at least one stator identification device may comprise at least one stator coupling coil.
The stator further may comprise one or more coupling coil driving circuits for driving the at least one stator coupling coil.
One or more of a shape and a geometry of the at least one stator coupling coil may be different from a respective one or more of a shape and a geometry of the plurality of actuation coils.
When a current is driven through the at least one stator coupling coil, the at least one stator coupling coil may be configured to magnetically couple with at least one mover inductive coil of the at least one mover identification device.
The one or more stator driving circuits may be operable to drive the plurality of actuation coils at one or more frequencies different from one or more frequencies used to operate the at least one stator identification device, for reducing interference between the plurality of actuation coils and the at least one stator identification device.
The at least two degrees of freedom may comprise orthogonal x-axis, y-axis, and z-axis degrees of freedom, and respective rotational degrees of freedom about the x-axis, the y-axis, and the z-axis.
The at least one mover identification device may comprise a plurality of mover identification devices.
The system may further comprise a controller communicatively coupled to the one or more sensors and operable to perform a method comprising: activating the one or more stator driving circuits to drive the actuation coil assembly so as to move the first magnetic mover over the work surface to a sensing position associated with a stator identification device of the at least one stator identification device; and activating the stator identification device for enabling interaction between the stator identification device and the at least one mover identification device.
The method may further comprise, after activating the stator identification device, identifying the first magnetic mover based on identification information transmitted from the at least one mover identification device to the stator identification device.
The method may further comprise determining an orientation of the first magnetic mover based on the transmitted identification information. The orientation may be an Rz orientation range.
The sensing position may comprise a position that is sufficiently close to the stator identification device so as to permit, for at least one orientation of the first magnetic mover, data transfer between the at least one mover identification device and the stator identification device.
Activating the stator identification device for enabling interaction between the stator identification device and the at least one mover identification device may comprise: activating the stator identification device; thereafter, determining whether identification information has been transferred from the at least one mover identification device to the stator identification device; and if not, then adjusting a position of the first magnetic mover.
Adjusting the position of the first magnetic mover may comprise translating the first magnetic mover to a new sensing position associated with the stator identification device.
The method may further comprise determining an orientation of the first magnetic mover based on identification information transmitted from the at least one mover identification device to the stator identification device, and based on the adjusted position of the first magnetic mover.
The at least one mover identification device may comprise a plurality of mover identification devices, each mover identification device being associated with unique identification information for the first magnetic mover, and the method may further comprise: determining an orientation of the first magnetic mover based on identification information transmitted from at least one mover identification device of the plurality of mover identification devices to the stator identification device.
The at least one mover identification device may comprise a plurality of mover identification devices positioned such that, when the first magnetic mover is in a sensing position associated with a stator identification device of the at least one stator identification device, at least one mover identification device of the plurality of mover identification devices is sufficiently close to the stator identification device so as to permit data transfer between the at least one mover identification device and the stator identification device.
The at least one stator identification device may comprise a plurality of stator identification devices positioned such that, when the first magnetic mover is in a sensing position associated with a stator identification device of the plurality of stator identification devices, the at least one mover identification device is sufficiently close to the stator identification device so as to permit data transfer between the at least one mover identification device and the stator identification device.
The at least one mover identification device may be associated with identification information uniquely identifying the first magnetic mover.
A center of the at least one mover identification device may be offset from a center of the one or more magnetic components of the first magnetic mover.
The at least one stator identification device may have a size such that, for at least one position of the first magnetic mover on or over the work surface, at least a portion of the at least one mover identification device overlaps with at least a portion of the at least one stator identification device.
The one or more magnetic components may comprise multiple magnet arrays, each magnet array comprising multiple linearly elongated magnetization segments defining a direction of elongation, and an axial direction of a magnetic core of the at least one mover identification device may be aligned with the direction of elongation defined by the linearly elongated magnetization segment closest to the at least one mover identification device.
Each magnetization segment may have a magnetization direction, and the axial direction of the magnetic core of the at least one mover identification device may be orthogonal to the magnetization direction of the magnetization segment closest to the magnetic core.
The at least one mover identification device may comprise a magnetic core, the one or more magnetic components may comprise multiple magnet arrays comprising a plurality of linearly elongated magnetization segments, the linearly elongated magnetization segment closest to the at least one mover identification device may have first and second ends, and: a distance separating the first end from a center of the magnetic core in an axial direction of the magnetic core may be greater than a length of the magnetic core; and a distance separating the second end from the center of the magnetic core in the axial direction of the magnetic core may be greater than the length of the magnetic core.
The at least one mover identification device may comprise a magnetic core, the one or more magnetic components may comprise multiple magnet arrays comprising a plurality of linearly elongated magnetization segments, the linearly elongated magnetization segment closest to the at least one mover identification device may have first and second ends, and: a distance separating the first end from a center of the magnetic core in an axial direction of the magnetic core may be greater than about ⅓ of a distance separating the first end from the second end; and a distance separating the second end from the center of the magnetic core in the axial direction of the magnetic core may be greater than about ⅓ of the distance separating the first end from the second end.
The first magnetic mover may comprise a magnetic robotic device carrying a workpiece, and the at least one mover identification device may be comprised in the workpiece.
The one or more magnetic components may comprise multiple magnet arrays surrounding the at least one mover identification device.
The at least one mover identification device may comprise an inductive coil wound about a magnetic core.
The at least one mover identification device may comprise a storage component storing identification information identifying the first magnetic mover.
According to a further aspect of the disclosure, there is provided a method comprising: providing a system comprising: at least one magnetic mover comprising a first magnetic mover, wherein the first magnetic mover comprises at least one mover identification device; a stator defining a work surface and comprising: an actuation coil assembly comprising a plurality of actuation coils; and at least one stator identification device; and one or more stator driving circuits for driving the actuation coil assembly; transferring identification information from the at least one mover identification device to the at least one stator identification device; and identifying the first magnetic mover based on the identification information, wherein the first magnetic mover comprises one or more magnetic components positioned such that interaction of one or more magnetic fields emitted by the one or more magnetic components with one or more magnetic fields generated by the actuation coil assembly when driven by the one or more stator driving circuits enables movement of the first magnetic mover in at least two degrees of freedom.
The method may further comprise determining with one or more sensors a position of the first magnetic mover.
The work surface may separate the first magnetic mover from one or more of the actuation coil assembly and the at least one stator identification device.
The at least one mover identification device may comprise at least one mover inductive coil, and the at least one stator identification device may comprise at least one stator coupling coil.
When a current is driven through the at least one stator coupling coil and/or at least one mover inductive coil of the at least one mover identification device, the one or more stator driving circuits may not drive a current through the plurality of actuation coils, in order to minimize interference from the plurality of actuation coils with the at least one stator coupling coil and/or the at least one mover inductive coil.
Transferring the identification information may comprise transferring the identification information using electromagnetic induction.
The stator may further comprise one or more coupling coil driving circuits for driving the at least one stator coupling coil.
The method may further comprise, prior to identifying the first magnetic mover, activating the one or more stator driving circuits to drive the actuation coil assembly so as to move the first magnetic mover over the work surface to a sensing position associated with a stator identification device of the at least one stator identification device; and activating the stator identification device for enabling interaction between the stator identification device and the at least one mover identification device.
The method may further comprise determining an orientation of the first magnetic mover based on the transmitted identification information.
Activating the stator identification device for enabling interaction between the stator identification device and the at least one mover identification device may comprise: activating the stator identification device; thereafter, determining whether the identification information has been transferred from the at least one mover identification device to the stator identification device; and if not, then adjusting a position of the first magnetic mover.
Adjusting the position of the first magnetic mover may comprise translating the first magnetic mover to a new sensing position associated with the stator identification device.
The method may further comprise determining an orientation of the first magnetic mover based on the identification information transmitted between the at least one mover identification device and the stator identification device, and based on the adjusted position of the first magnetic mover.
The at least one mover identification device may comprise a plurality of mover identification devices, each mover identification device being associated with unique identification information for the first magnetic mover, and the method may further comprise: determining an orientation of the first magnetic mover based on identification information transmitted from at least one mover identification device of the plurality of mover identification devices to the stator identification device.
The first magnetic mover may comprise a magnetic robotic device carrying a workpiece, the at least one mover identification device may be comprised in the workpiece, and identifying the first magnetic mover comprises identifying the workpiece may be based on the identification information.
The method may further comprise, when the at least one stator identification device is used to communicate with the at least one mover identification device, optimizing a Z-direction distance between the first magnetic mover and the work surface to strengthen a coupling between the at least one mover identification device and the at least one stator identification device, wherein the Z-direction distance may include a nil distance.
According to a further aspect of the disclosure, there is provided a computer-readable medium comprising computer program code configured when executed by one or more processors to cause the one or more processors to perform any of the herein-described methods.
According to a further aspect of the disclosure, there is provided a magnetic mover comprising: at least one identification device associated with identification information identifying the magnetic mover, the at least one identification device comprising at least one magnetic core; and magnet arrays comprising linearly elongated magnetization segments defining respective directions of elongation, wherein an axial direction of the at least one magnetic core is aligned with the direction of elongation defined by the linearly elongated magnetization segment closest to the at least one identification device.
The linearly elongated magnetization segment closest to the at least one identification device may have first and second ends, and: a distance separating the first end from a center of the at least one magnetic core in an axial direction of the at least one magnetic core may be greater than a length of the at least one magnetic core; and a distance separating the second end from the center of the at least one magnetic core in the axial direction of the at least one magnetic core may be greater than the length of the at least one magnetic core.
A center of the at least one identification device may be offset from a center of the magnetic mover.
The magnet arrays may surround the at least one identification device.
An axial direction of principal magnetic flux generated by the at least one identification device when a current is driving the at least one identification device may be orthogonal to magnetic fields at a center of the identification device emitted by the magnet array closest to the identification device.
The at least one identification device may comprise an inductive coil wound about the magnetic core.
The at least one identification device may comprise a storage component storing the identification information.
According to a further aspect of the disclosure, there is provided a stator comprising, positioned on a side of a work surface defined by the stator: an actuation coil assembly comprising a plurality of actuation coils; at least one coupling coil having one or more of a shape and a geometry different from a respective one or more of a shape and a geometry of the actuation coils; one or more stator driving circuits for driving the actuation coil assembly; and one or more coupling coil driving circuits for driving the at least one coupling coil.
The one or more stator driving circuits may be operable to drive the plurality of actuation coils at one or more frequencies different from one or more frequencies used by the one or more coupling coil driving circuits to drive the at least one coupling coil, for reducing interference between the plurality of actuation coils and the at least one coupling coil.
It will be appreciated that there are multiple applications where it may be desirable (e.g. for efficiency or any other suitable reason) why it might be advantageous to be able to achieve improved traceability and detect a mover's in-plane orientation. For example, a user may wish to mate a slender workpiece (carried by a mover) oriented in the positive X direction with a second workpiece located at an assembly station. However, if the mover is rotated by 90 or 180 degrees either manually or by an automation device, the carried workpiece will be oriented in the Y or in X directions; when the rotated mover moves to the assembly station, it may not be possible for the second workpiece to mate with the carried workpiece.
This summary does not necessarily describe the entire scope of all aspects. Other aspects, features and advantages will be apparent to those of ordinary skill in the art upon review of the following description of specific embodiments.
In the accompanying drawings, which illustrate one or more example embodiments:
The present disclosure seeks to provide improved systems and methods for identifying a magnetic mover. While various embodiments of the disclosure are described below, the disclosure is not limited to these embodiments, and variations of these embodiments may well fall within the scope of the disclosure which is to be limited only by the appended claims.
Throughout the following description, specific details are set forth in order to provide a more thorough understanding to persons skilled in the art. However, elements well known in the prior art may not have been shown or described in detail to avoid unnecessarily obscuring the disclosure. Accordingly, the description and drawings are to be regarded in an illustrative, rather than a restrictive, sense.
According to some embodiments, robotic devices (or systems) are provided and which comprise one or more stators and one or more movers. Each mover may carry one or more workpieces or parts (workpieces and parts are used interchangeably throughout this disclosure). In some applications, a plurality of movers may carry one part holder, which may hold one or more parts. A “part” is a general term, and non-limiting examples include a component, a sample, or an assembly. Generally, a stator and one or more movers may interact with each other via one or more magnetic fields so that the stator can provide forces and/or torques to the one or more movers to controllably move the one or more movers. In some embodiments, all movers in a system are substantially similar or nearly identical; however, this is not essential, and a system may comprise movers comprising magnet arrays of different size and/or configuration. In some embodiments, a stator may comprise a plurality of coils distributed in one or more planar layers. In some embodiments, a stator may further comprise a plurality of teeth, such as iron teeth.
The stator provides a work surface (which may have any of various suitable shapes, such as, flat, curved, cylindrical, or spherical), and each mover is able to move along, over, or on the work surface either in a contacting manner (via one or more contacting media such as sliding and/or rolling bearings, contact mode, or sitting mode) or without any contact by maintaining a controllable gap between a mover and a stator in a normal direction of the work surface. Such a gap may be maintained by passive or active levitation means.
Throughout this disclosure, moveable motion stages, moveable stages, motion stages, and movers are used interchangeably. Each mover may comprise one or more magnet assemblies. Each magnet assembly may comprise one or more magnet arrays rigidly connected together. Each magnet array may comprise one or more magnetization elements. Each magnetization element has a magnetization direction. Generally, magnets on a mover interact with stator coils via a working gap that is much smaller than a lateral dimension of the mover, i.e. a dimension parallel with the stator work surface.
In some embodiments, one or more amplifiers may be connected to drive a plurality of currents in the plurality of coils in the one or more stators. One or more controllers may be connected to deliver control signals to the one or more amplifiers. The control signals may be used to control current driven by the one or more amplifiers into at least some of the plurality of coils. The currents controllably driven into the at least some of the plurality of coils create magnetic fields which cause corresponding magnetic forces on the one or more magnet assemblies of a mover, thereby moving the mover relative to the stator (e.g. over or on the work surface) controllably in at least 2 in-plane degrees-of-freedom (DOF), or at least 3 in-plane DOFs, or at least 6 DOFs. In some embodiments, the magnetic forces associated with the interaction between the magnetic fields created by the currents in at least some of the coils and the magnetic fields associated with the magnet arrays may attract the moveable stage toward the stator when the controller is controlling the currents driven by the one or more amplifiers. In some embodiments, the magnetic forces associated with the interaction between the magnetic fields created by the currents in at least some of the coils and the magnetic fields associated with the magnet arrays may force the mover stage away from the stator to balance gravitational forces with an air gap when the controller is controlling the currents driven by the one or more amplifiers. In some embodiments, the gap between the movers and the stator is maintained by air bearings or compressed-fluid bearings.
In some embodiments, movers may work in levitation mode, i.e. movers may be levitated near the work surface without contacting the work surface either in a passive way or in an active way, and movers 100 may move along the work surface extending in X and Y directions, where X and Y are two in-plane, non-parallel directions. The separation gap between the work surface and a mover is generally much smaller than dimensions of the mover in both the X and the Y directions. Although in some embodiments movers are capable of 6 DOF controllable motion, this is not essential. In certain applications, where levitation of a mover may not be required and heavy load-carrying capability is more important, it will be understood by those of skill in the art that movers can sit on the work surface with proper mechanical bearings (including but not being limited to planar sliding bearings and ball transfer units), and are capable of three in-plane DOF controllable motion (translation in the X and Y directions, and rotation around the Z direction), where the X and Y directions are two in-plane, non-parallel direction, and the Z direction is normal to the work surface. When a mover relies on sliding and/or rolling bearings to sit on the work surface and the mover is capable of 3 in-plane DOF controllable motion (translation in the X and Y directions, and rotation around the Z direction), it is working in a 3-DOF controlled sitting mode. In some embodiments, a mover is capable of 3-DOF controllable motion (translation in the X and Y directions, and rotation around the Z direction) while working in levitation mode without contact with the stator; in this mode, translation in the Z direction, and rotation around the X and Y directions are open-loop controlled without feedback, using suitable passive levitation technology known to those of skill in the art. When a mover is capable of 3-DOF controllable motion without contact with the stator, it is working in a 3-DOF controlled levitation mode.
Generally, a stator working region is a two-dimensional (2D) area provided by the stator work surface, and movers can be controllably moved with at least two in-plane DOFs inside the stator working region, with suitable feedback control algorithms and suitable position feedback sensors.
For the purposes of describing the movers disclosed herein, it can be useful to define a pair of coordinate systems—a stator coordinate system which is fixed to the stator (e.g. to stator 200 of
In some embodiments, the stator-x and stator-y directions are non-parallel. In particular embodiments, the stator-x and stator-y directions are generally orthogonal. In some embodiments, the mover-x and mover-y directions are non-parallel. In particular embodiments, the mover-x and mover-y directions are generally orthogonal. In some embodiments, the stator-x and stator-y directions are parallel with the stator work surface, and the stator-z direction is normal to the stator work surface.
The coupling coil circuits 61 are driven with currents at a base frequency significantly higher than the base frequencies of currents flowing into the actuation coil circuits 51. In one non-limiting example, the base frequency of currents in actuation coil circuits 51 are in the range of a few hundred hertz or less, while the base frequency of currents in coupling circuits 61 are in the range of tens of kHz or higher. The coupling coil circuits 61 are driven with currents of amplitudes significantly lower than the amplitude of currents driven into the actuation coil circuits 51. In one non-limiting example, the amplitude of currents in the actuation coil circuits 51 is in the range of amperes or higher, while the amplitude of currents in the coupling coil circuits 61 is in the range of milliamperes or lower. The coupling coil circuits 61 have a geometry (shape and/or coil width) significantly different from the actuation coil circuits 51. For example, the coil circuits 51 may be linearly elongated in the X or Y directions; the coil circuits 61 may be have a rectangular, square, circular, or any other suitable shape in the plane extending in the X or Y directions.
In one non-limiting example, the 1st MRU 10 comprises a magnet array suitably designed so that the interaction between the actuation coil currents and the 1st MRU 10 via magnetic fields can controllably move the mover 100 in at least two degrees of freedom.
In one non-limiting example, the 2nd MRU 20 comprises an inductive coil and a capacitor, the inductive coil and the capacitor suitably connected to form a resonance circuit to facilitate bidirectional transfer of power or information. In some embodiment, the 2nd MRU 20 may transfer its internally stored information to the coupling coil circuit 61, by demodulating the terminal voltage or currents of the coupling coil circuit 61.
In one non-limiting example, the 2nd MRU 20 comprises a material of high electrical conductivity, such as but not being limited to copper or gold, so that the coupling between the 2nd MRU 20 and the coupling coil circuit 61 significantly weakens the inductance of the coupling coil circuit 61, such as by 20% or more. The inductance change (reduction) can be used to indicate whether the 2nd MRU 20 is located above the coupling coil circuit 61 for detecting the mover's in-plane orientation (its angular rotation relative to the Z axis).
In one non-limiting example, the 2nd MRU 20 may comprise a magnetic core made of material(s) of high magnetic permeability, such as but not being limited to iron and/or nickel, so that the coupling between the 2nd MRU 20 and the coupling coil circuit 61 is strengthened. In this embodiment, the inductive coil of the 2nd MRU 20 is wound around the magnetic core.
One non-limiting example of actuation coil circuits 51 and/or coupling coil circuits 61 are traces manufactured with PCB fabrication technology.
In some embodiments, the actuation coil circuits 51 and the coupling coil circuits 61 overlap with each other in the stator Z direction, but are located at different Z positions, so that the coupling coil circuits 61 do not interrupt the continuity of actuation coil circuits 51, and the mover 100 can be actuated smoothly during its planar motion in at least two planar degrees of freedom.
The actuation coil circuits 51 and the coupling coil circuits 61 are intentionally designed or created in such a way to minimize the cross-coupling between the coupling coil circuits 61 and the 1st MRU 10, and/or the cross-coupling between the actuation coil circuits 51 and the 2nd MRU 20.
The mover 100 is controllably moveable along a work surface 3, which is the top surface of stator 200 extending in the X and Y directions. Due to the fact that the actuation coil circuits 51 and the coupling coil circuits 61 are separated from the mover 100 by the work surface 3, the mover 100's planar motion in the X and Y directions is not mechanically constrained by the actuation coil circuits 51 or the coupling coil circuits 61.
The stator 200 comprises a controller 70. The controller 70 may receive signals from position sensors 80 (not shown in
The mover 100 may be controllably moved relative to the stator 200 by the interaction between the stator actuation coil assembly 50 and the 1st MRU 10 about a working region in at least two in-plane DOFs. In some embodiments, mover 100 is capable of 6-DOF controllable motion (X, Y, Z, Rx, Ry, and Rz); in some embodiments, mover 100 is capable of three in-plane DOF controllable motion (X, Y, and Rz), in a passive levitation mode or in a sitting mode.
Although only one mover 100 is shown in
As shown in
It should be noted that the actuation coil circuits 51 and the coupling coil circuits 61 are substantially different from each other in geometry. In some embodiment, the width 62 of coil traces in the coupling coil circuits 61 is substantially smaller than the width 52 of coil traces in the actuation coil circuits 51. In some embodiments, the shape of coil traces in the coupling coil circuits 61 is substantially different from the shape of coil traces in the actuation coil circuits 51. For example, the traces (circuits) in the coupling coil circuits 61 may be in square, circular, triangular, rectangular, or polygonal shapes; traces in the actuation coil circuits 51 may be linearly elongated. A reason for the different geometry is that these two groups of coil traces in the actuation coil circuits 51 and the coupling coil circuits 61 are used to carry currents of significantly different frequencies and significantly different amplitudes.
In some embodiments, the coupling between the coupling coil circuits 61 and the 2nd MRU 20 is used to detect the presence or absence of 2nd MRU 20 above coupling coil assembly 60. The inductance of coupling coil assembly 60 will differ greatly between the case of 2nd MRU 20 being located above coupling coil assembly 60 as opposed to the case of 2nd MRU 20 not being located above coupling coil assembly 60. Such characteristics may be used to detect the presence of mover 100 and/or the orientation of mover 100, as explained later in connection with
In some embodiments, the stator coupling coil assembly 60 can transfer power/energy to 2nd MRU 20 when effective stator coupling coil region 63 and 2nd MRU 2020 are overlapping with each other in the stator Z direction. With the received energy from stator coupling coil assembly 60, 2nd MRU 20 can transmit its stored information to coupling coil assembly 60 by exciting its inductive coil 22 with information-carrying AC current 24 to produce a magnetic flux that is coupled to the coupling coil circuits 61, and the coupled flux will induce electrical voltage on the coupling coil circuits 61. In some embodiments, each 2nd MRU 20 may store unique identification information so that coupling coil assembly 60 may detect whether a 2nd MRU 20 is within its effective stator coupling coil region 63 (in other words, 2nd MRU 20 and effective stator coupling coil region 63 are overlapping in the Z direction), but also can detect exactly which 2nd MRU 20 is within its effective stator coupling coil region 63.
In some embodiments, each mover 100 may only be able to be rotated around Rz for a relatively small angle range such as +/−15 degrees or less. However, there may exist multiple possible Rz orientation ranges, including but not limited to 0+/−15 degrees, 90+/−15 degrees, 180+/−15 degrees, and 270+/−15 degrees. In order to determine the absolute Rz orientation (e.g. distinguish which Rz orientation range the mover 100 is actually in), one method is described in connection with
In
Generally, the detection procedure can be summarized in the following steps:
In some embodiments, it may be advantageous to position the 2nd MRU 20 such that the 2nd MRU magnetic core axial dimension center 26 (shown in
As shown in
Since magnet array 12B has a finite extension in the Y direction, the leakage field from the magnet array 12B has a Y-component that is strongest near the two ends of the magnet array 12B in the Y direction, and weakest near the plane extending in the X and Z directions and passing through the Y dimension center of the magnetization segment 12B. In some embodiments, it is advantageous to position the 1st MRU 10 and 2nd MRU 20 such that the 2nd MRU magnetic core axial dimension center 26 is sufficiently near to or coincides with the plane extending in the X and Z directions and passing through the Y dimension center of the magnetization segment 12B adjacent to the 2nd MRU magnetic core, or such that the 2nd MRU magnetic core axial dimension center 26 is sufficiently far from the two ends of the magnet array 12B in the Y direction, such that the leakage field from the magnet array has a minimal axial (Y-direction) component. Sufficiently far from the two ends of the magnet array 12B may be interpreted as a Y-distance between the magnetic core axial dimension center 26 and the ends of the magnet array 12B that is larger than about ⅓ of the Y-dimension of the magnet array 12B. In some embodiments, sufficiently far may be interpreted as meaning that a distance separating either end of magnet array 12B from magnetic core axial dimension center 26 is greater than a length of the 2nd MRU magnetic core.
As show in
In some embodiments, the stator coupling assembly 60 is positioned such that the XY center point of the stator coupling assembly 60 is roughly aligned with the XY center point of the stator 200 in the Z direction. This arrangement may accommodate different positions of the 2nd MRU 20 on mover 100, such as placing 2nd MRU 20 on the edge of the mover 100 or placing 2nd MRU 20 in the center of mover 100. With the stator coupling assembly 60 positioned roughly in the XY center of the stator 200, it is possible to achieve strong coupling between 2nd MRU 20 and stator coupling assembly 60 without making the mover 100 extend beyond the boundaries of the stator 200.
In some embodiments, 2nd MRU 20 may be incorporated into a workpiece 300 carried by mover 100, as shown in
In some embodiments, a 3rd MRU 30 is incorporated into the workpiece 300 carried by the mover 100, as shown in
At block 110, controller 70 activates actuation coil assembly 50. For example, controller 70 may cause current to flow through actuation coil circuits 51. At block 112, by driving actuation coil circuits 51, controller is able to move mover 100 over or on work surface 3, through the interaction of the magnetic fields generated by actuation coil circuits 51 with the magnetic components of mover 100. Mover 100 is moved to a sensing position, which may be a position in which a 2nd MRU 20 of mover 20 overlaps effective stator coupling region 63. At block 114, identification information is read by controller 70. For example, controller 70 may drive coupling coil circuits 61 so as initiate the transfer of data from 2nd MRU 20 to stator coupling assembly 60. Based on the identification information read by controller 70, controller 70 may identify mover 100.
Controller 70 may additionally determine the orientation of mover 100. In particular, at block 116, controller 70 determines whether it is possible based on the identification information obtained at block 114 to determine the orientation of mover 100. For example, the identification information may include information identifying a position of the 2nd MRU 20 on mover 100. If it is possible to determine from the identification information the orientation of mover 100, then at block 118 controller 70 determines the orientation of mover 100. If it is not possible to determine from the identification information the orientation of mover 100, then at block 120 controller 70 adjusts a position of the mover 100. For example, through suitable driving of actuation coil circuits 51, controller 70 may cause the mover 100 to be repositioned in the X and/or Y directions such that another 2nd MRU 20 of mover 100 overlaps effective stator coupling region 63. At block 122, identification information is read by controller 70. In particular, controller 70 drives coupling coil circuits 61 so as initiate the transfer of data from the other 2nd MRU 20 to stator coupling assembly 60. At block 124, controller 70 determines whether it is possible based on the identification information of the other 2nd MRU 20 to determine the orientation of mover 100. The process repeats until controller 70 is able to determine the orientation of mover 100.
According to some embodiments, the system may include more than one stator, with the stators positioned adjacent one another such a mover moving over or on the surface of a first one of the stators may be moved onto an adjacent one of the stators, such that the mover may then be moved over or on the adjacent stator.
According to some embodiments, the system may include more than one stator, with the stators positioned adjacent one another such a mover moving over or on the surface of a first one of the stators may be moved onto an adjacent one of the stators, such that the mover may then be moved over or on the adjacent stator.
According to some embodiments, the stator coupling coil circuits may be sized such that, for any given position of a mover on or over the work surface, at least a portion of the 2nd MRU overlaps with at least a portion of the stator coupling coil circuits.
Throughout this description, it should be understood that a mover may carry one or more part(s), such as but not limited to more biological sample(s), device(s), one or more drugs possibly in suitable container(s), product(s) being assembled, raw part(s) or material(s), component(s), to meet the needs of a desired manufacturing purpose. Suitable tooling and/or material feeding mechanism may be installed or distributed along the sides of stators or over the stators from above, although these are not shown to avoid obscuring the description.
While a number of exemplary aspects and embodiments are discussed herein, those of skill in the art will recognize that the disclosure extends to any suitable modification, permutation, addition, and sub-combination thereof. For example:
The word “a” or “an” when used in conjunction with the term “comprising” or “including” in the claims and/or the specification may mean “one”, but it is also consistent with the meaning of “one or more”, “at least one”, and “one or more than one” unless the content clearly dictates otherwise. Similarly, the word “another” may mean at least a second or more unless the content clearly dictates otherwise.
The terms “coupled”, “coupling” or “connected” as used herein can have several different meanings depending on the context in which these terms are used. For example, the terms coupled, coupling, or connected can have a mechanical or electrical connotation. For example, as used herein, the terms coupled, coupling, or connected can indicate that two elements or devices are directly connected to one another or connected to one another through one or more intermediate elements or devices via an electrical element, electrical signal or a mechanical element depending on the particular context. The term “and/or” herein when used in association with a list of items means any one or more of the items comprising that list.
As used herein, a reference to “about” or “approximately” a number or to being “substantially” equal to a number means being within +/−10% of that number.
While the disclosure has been described in connection with specific embodiments, it is to be understood that the disclosure is not limited to these embodiments, and that alterations, modifications, and variations of these embodiments may be carried out by the skilled person without departing from the scope of the disclosure.
It is furthermore contemplated that any part of any aspect or embodiment discussed in this specification can be implemented or combined with any part of any other aspect or embodiment discussed in this specification.
Filing Document | Filing Date | Country | Kind |
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PCT/CA2019/051429 | 10/4/2019 | WO | 00 |
Number | Date | Country | |
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62745290 | Oct 2018 | US | |
62786553 | Dec 2018 | US |