The first switchable magnet included two permanent magnets positioned between two soft magnetic shunt plates made of a magnetically permeable material (e.g., a ferromagnetic material), where one of the permanent magnets was mechanically rotated to align the directions of magnetization of the two permanent magnets in the same direction, or align the directions of magnetization of the two permanent magnets in opposite directions, in order to turn the switchable magnet “on” or the switchable magnet turn “off,” respectively, where a magnetic latching field extended from the switchable magnet when the switchable magnet was on, and little or no magnetic latching field extended from the switchable magnet when the switchable magnet was off [3, 16].
An electropermanent magnet (EPM) is a type of switchable magnet where a switchable magnet is a magnet device where the magnetic field external to the device is switchable between an “on state” and an “off state”. Rather than physically rotating one of two permanent magnets to switch the alignment of the directions of magnetization of the two permanent magnets, an electropermanent magnet includes a pair of permanent magnets positioned between two soft magnetic shunt plates made of a magnetically permeable material, where a pulse of electric current passing through a coil in a first direction is used to create a magnetic field that flips the direction of magnetization of the switchable permanent magnet to align the directions of magnetization of the two permanent magnets in the same direction, or a pulse of current passing through the coil in a second direction opposite to the first direction flips the direction of magnetization of the switchable permanent magnet such that the directions of magnetization of the two permanent magnets are in opposite directions, in order to turn “on,” or “off,” respectively, a magnetic latching field of the EPM [14, 17]. In this way, an EPM is a switchable magnet that only consumes power during transitions between the on/off states, i.e., transitions from the on state to the off state and transitions from the off state to the on state. Switching the electropermanent magnets from the on state to the off state, and from the off state to the on state, controls the EPM's external magnetic (latching) field.
Electromagnets also can be used to create adjustable external magnetic fields, where the adjustable magnetic fields are created by driving an adjustable current through a coil. However, in contrast with an electromagnet, which requires continuous electric current to create an external magnetic field, using a single pulse of electric current to switch the EPM from one state to the other state limits the energy needed for magnet control when compared to electromagnets. Accordingly, EPMs can be advantageous in certain applications, such as when the amount of energy use is important.
Many of applications for EPMs benefit from the miniaturization of EPMs, such as the use of EPMs as: switchable magnetic components with application in MEMS; actuators/latches for microrobots and programmable matter [1]; and ferrofluid droplet manipulations in microfluidic devices [15].
EPMs are typically constructed using two adjacent permanent magnets and a soft magnetic material at each end of the two permanent magnets [1].
The alignment of the poles of the two permanent magnets is controlled for the prior art device shown in
Alternatively, a coil can be positioned around only the switchable magnet and not the fixed magnet. Specifically, in other EPMs, the alignment of the poles of the two permanent magnets is controlled using a coil that wraps around only one of the two permanent magnets (the switching magnet), such that the magnetic field produced by the electric current passing through the coil is only applied to the switching magnet, and the magnetic field created by the coil will only change the direction of magnetization of the switching magnet. Switching the magnetization of the switching magnet, and not the fixed magnet, then switches the EPM from on/off to off/on.
EPMs have been used since the late 20th century on a macroscopic scale, such as on cranes to lift large pieces of metal without a continuous energy source [3]. In 2010, EPMs were first built on a significantly smaller scale, measuring at approximately 3 mm2, for creating programmable matter blocks [2]. Controlling the external magnetic field of the EPM forced the blocks to attract, connect, and disconnect to form basic two-dimensional structures. Programmable matter has since been developed into more advanced structures beyond cubes [4]. The new programmable matter uses EPMs to assemble complex, abstract three-dimensional structures. However, these structures cannot be made smaller because the size of the EPMs restricts the scale (size) of the structures.
The controllable magnetic field of EPMs allows EPMs to be used in transportation. Legged robots have been developed with EPMs that connect to ferromagnetic materials, permitting the robots to climb structures made from steel [5]. The ability to control the strength of the external magnetic field also permits a circular wheel shape to be used to climb ferromagnetic structures for increased gripping and mobility [6][7]. In addition, EPMs can be used in connecting mechanisms in transportation. EPMs have been used in docking systems for underwater robots because the external magnetic field of the EPM can pass through the water [8]. EPMs have also been used in drone delivery systems, similar to how EPMs are used in a crane, where the EPMs on the drone, such as a quadcopter, can connect to a ferromagnetic material to attract, connect, and release an object [9].
EPMs have also been used in medical settings, where the properties of EPMs can help to anchor surgical instruments without inadvertently attracting other instruments [10]. Unlike permanent magnets, in which anchoring causes other magnets to be attracted to instruments, the electropermanent magnet can anchor instruments without affecting (attracting) other medical instruments.
EPMs were initially going to be used to assemble Google's Project Ara modular cell phone [11]. In the original design, EPMs were going to be used to connect modules to a skeleton and to remove them, without requiring a constant power source. This design allowed for a customizable smartphone that could be adapted without turning off the phone. After a series of failed drop tests in which the modules were unable to stay connected to the skeleton with EPMs, Google determined that their EPMs could not both be decreased in size and still retain strong magnetic fields [12]. Accordingly, there is a need for EPMs that are both small and retain strong magnetic fields.
Embodiments of the subject invention relate to a switchable magnet having a magnet assembly that incorporates:
at least one fixed magnet having a first direction of magnetization, from a south end of the at least one fixed magnet to a north end of the at least one fixed magnet, in a first direction, and at least one switching magnet having a second direction of magnetization from a south end of the at least one switching magnet to a north end of the at least one switching magnet, where the at least one fixed magnet and the at least one switching magnet are permanent magnets, and
either:
a coil positioned with respect to the magnet assembly such that:
a first shunt plate and a second shunt plate, positioned with respect to the magnet assembly such that:
Embodiments of the switchable magnet are such that the one or more fixed magnets of the at least one fixed magnet are positioned within the corresponding one or more bores through the first switching magnet of the at least one switching magnet.
Embodiments of the switchable magnet are such that the one or more switching magnets of the at least one switching magnet is a first switching magnet, and the at least one fixed magnet is a first fixed magnet of the at least one fixed magnet, such that the first switching magnet is positioned within a bore through the first fixed magnet.
Embodiments of the switchable magnet are such that the one or more fixed magnets of the at least one fixed magnet are positioned within the corresponding one or more bores through the first switching magnet of the at least one switching magnet.
Embodiments of the switchable magnet are such that the one or more fixed magnets of the at least one fixed magnet is a first fixed magnet, and the at least one switching magnet is a first switching magnet of the at least one switching magnet, such that the first fixed magnet is positioned within a bore through the first switching magnet.
Embodiments of the switchable magnet are such that the first fixed magnet and the first switching magnet are concentric. Alternative embodiments of the switchable magnet are such that the first fixed magnet and the first switching magnet are not concentric.
Embodiments of the switchable magnet are such that the first fixed magnet and the first switching magnet are coaxial. Alternative embodiments of the switchable magnet are such that the first fixed magnet and the first switching magnet are not coaxial.
Embodiments of the switchable magnet are such that the on state switching magnetic flux is in a range of 95% to (1/0.95)%, 90% to (1/0.90)%, and/or 80% to (1/0.80)%, of the on state fixed magnetic flux.
Embodiments of the switchable magnet are such that the off state switching magnetic flux is in a range of 95% to (1/0.95)%, 90% to (1/0.90)%, and/or 80% to (1/0.80)%, of the on state switching magnetic flux.
Embodiments of the switchable magnet are such that the off state switching magnetic flux is in a range of 95% to (1/0.95)% , 90% to (1/0.90)% , and/or 80% to (1/0.80)%, of the on state switching magnetic flux.
Embodiments of the switchable magnet are such that the coil is positioned with respect to the magnet assembly such that:
Embodiments of the switchable magnet are such that the coil is positioned with respect to the magnet assembly such that:
Embodiments of the switchable magnet are such that the first fixed magnet is cylindrically shaped.
Embodiments of the switchable magnet are such that the bore through the first switching magnet is cylindrically shaped. Alternative embodiments of the switchable magnet are such that the bore through the first switching magnet has a rectangular cross section, is annular shape, an/or has other shape(s).
Embodiments of the switchable magnet are such that the first switching magnet is cylindrically shaped. Alternative embodiments of the switchable magnet are such that the first switching magnet has a rectangular cross section, is annular shape, an/or or has other shape(s).
Embodiments of the switchable magnet are such that the first shunt plate and the second shunt plate are cylindrically shaped, and the first shunt plate and the second shunt plate are coaxial with the first fixed magnet and the first switching magnet.
Embodiments of the switchable magnet are such that the coil is cylindrically shaped. Alternative embodiments of the switchable magnet are such that the coil is cylindrically shaped.
Embodiments of the switchable magnet are such that the first coil created magnetic field is uniform within an interior of the coil, and the second coil created magnetic field is uniform within the interior of the coil. Alternative embodiments of the switchable magnet are such that the first coil created magnetic field is uniform within an interior of the coil, and the second coil created magnetic field is not uniform within the interior of the coil.
Embodiments of the switchable magnet are such that the coil is positioned adjacent to an exterior surface of a side of the first switching magnet. Alternative embodiments of the switchable magnet are such that the coil is positioned adjacent to an exterior surface of a side of the first fixed magnet.
Embodiments of the switchable magnet are such that the on state external magnetic field is symmetrical about a longitudinal axis of the switchable magnet, and the off state external magnetic field is symmetrical about the longitudinal axis of the switchable magnet. Alternative embodiments of the switchable magnet are such that the on state external magnetic field is not symmetrical about a longitudinal axis of the switchable magnet, and the off state external magnetic field is not symmetrical about the longitudinal axis of the switchable magnet, and can have a desired shape.
Embodiments of the switchable magnet are such that the on state external magnetic field is not symmetrical about a longitudinal axis of the switchable magnet, and, absent the presence of the first shunt plate and the second shunt plate, when the second direction of magnetization is in the first direction, an on state fixed magnetic flux exits out of the north end of the at least one fixed magnet and enters into the south end of the at least one fixed magnet, and an on state switching magnetic flux exits out of the north end of the at least one switching magnet and enters into the south end of the at least one switching magnet, so as to create an on state external magnet assembly created magnetic field, wherein the on state magnet assembly created external magnetic field is symmetrical about the longitudinal axis of the switchable magnet,
the off state external magnetic field is not symmetrical about the longitudinal axis of the switchable magnet, and
absent the presence of the first shunt plate and the second shunt plate, when the second direction of magnetization is in the second direction, an off state fixed magnetic flux exits out of the north end of the at least one fixed magnet and enters into the south end of the at least one fixed magnet and/or the south end of the at least one switching magnet, and an off state switching magnetic flux exits out of the north end of the at least one switching magnet and enters into the south end of the at least one switching magnet and/or the south end of the at least one fixed magnet, so as to create an off state magnet assembly created external magnetic field, wherein the off state magnet assembly created external magnetic field is symmetrical about the longitudinal axis of the switchable magnet.
Alternative embodiments of the switchable magnet are such that the off state magnet assembly created external magnetic field is not symmetrical about the longitudinal axis of the switchable magnet.
Embodiments of the switchable magnet are such that the first fixed magnet is made of NdFeB and the first switching magnet is made of Alnico. Alternative embodiments of the switchable magnet are such that the first fixed magnet is made of materials known to one of skill in the art and the first switching magnet is made of is made of materials known to one of skill in the art, where the coercivity of the first fixed magnet is higher than the coercivity of the first switching magnet.
Embodiments of the switchable magnet are such that the first fixed magnet has a length LF along a longitudinal axis of the first fixed magnet,
the first switching magnet has a length LS along a longitudinal axis of the first switching magnet,
LF is equal to LS, and
longitudinal axis of the first switching magnet is coextensive with the longitudinal axis of the first fixed magnet.
Embodiments of the switchable magnet are such that the latching force can exert a force on an object in the axial direction at the top or bottom of the switchable magnet, such as the embodiment shown in
Embodiments of the subject invention relate to an electropermanent magnet core (EPM core) having two permanent magnets (or two permanent magnet portions where each portion can have one or more permanent magnets), including a fixed permanent magnet portion and a switching permanent magnet portion, where a switching magnetic field is used to switch the magnetization of the switching permanent magnet portion, but not switch the magnetization of the fixed permanent magnet portion. In this way, the fixed permanent magnet portion has a fixed magnetization, such that the direction of magnetization of the fixed permanent magnet portion remains the same during switching of the magnetization of the switching permanent magnet portion, given the magnitude and duration of the switching magnetic field used to switch the magnetization of the switching permanent magnet portion, and the switching permanent magnet portion has a switching magnetization, such that the direction of magnetization of the switching permanent magnet portion is switched during switching of the magnetization of the switching permanent magnet portion, given the magnitude and duration of the switching magnetic field used to switch the magnetization of the switching permanent magnet portion.
Embodiments of the subject invention relate to an electropermanent magnet (EPM) having two permanent magnets (or two permanent magnet portions where each portion can have one or more permanent magnets), including a fixed permanent magnet portion and a switching permanent magnet portion, where a switching magnetic field is used to switch the magnetization of the switching permanent magnet portion, but not switch the magnetization of the fixed permanent magnet portion. In this way, the fixed permanent magnet portion has a fixed magnetization, such that the direction of magnetization of the fixed permanent magnet portion remains the same during operation of the EPM, given the magnitude and duration of the switching magnetic field used to switch the magnetization of the switching permanent magnet portion, and the switching permanent magnet portion has a switching magnetization, such that the direction of magnetization of the switching permanent magnet portion is switched during operation of the EPM, given the magnitude and duration of the switching magnetic field used to switch the magnetization of the switching permanent magnet portion. Specific embodiments are directed to a switchable magnet that only consumes power during transitions between the on/off states, such that the switchable magnet only consumes power while creating the switching magnetic field used to switch the magnetization of the switching permanent magnet portion.
In specific embodiments, the switching magnetic field is pulsed, preferably for time periods <1 s, <100 ms, <10 ms, <1 ms, <100 microseconds, <10 microseconds, <1 microsecond, and/or <100 ns, and at a magnitude of the switching magnetic field is at least a threshold magnitude that reverse the direction of magnetization of the portion of the switching magnet that is exposed to the switching magnetic field.
Specific embodiments are directed to an EPM incorporating an axisymmetric architecture for the two permanent magnets (i.e., the fixed permanent magnet and the switching permanent magnet). Specific embodiments are sub-millimeter in size. A specific embodiment is a sub-millimeter axisymmetric electropermanent magnet having a latching force on/off ratio of 784 with a total volume of 34 mm3. Compared to conventional architectures, the axisymmetric design: (1) provides better performance in a smaller form factor, (2) has a symmetric magnetic field along the magnetization axis, as opposed to the asymmetric fields in the transverse direction, (3) facilitates microfabrication, and (4) allows large tunability of the magnetic field on/off ratio (therefore the force) as a function of design variables (e.g., radii and thickness).
The subject application describes modeling, optimization, and experimental evaluation of a sub-millimeter electropermanent magnet yielding an on/off force ratio of 784 with a total volume of 34 mm3, corresponding to hundred-fold higher on/off force ratio than conventional EPM architectures in 1/10th of the volume. Specific embodiments have been fabricated (i) using alnico as the switching magnet material and SmCo as the fixed magnet material, having an EPM volume of 3.8 mm3 and a latching force ratio of 191, and (ii) using alnico as the switching magnet material and NdFeB as the fixed magnet material, having an EPM volume of 3.8 mm3 and a latching force ratio of 303.
An embodiment is directed to a cylindrical electropermanent magnet that can be scaled down to microscopic sizes. In specific embodiments, the overall switchable magnet (EPM) diameter, or thickness, is <1 mm, <100 micrometers, and/or <10 micrometers. Embodiments of the subject EPM incorporate two permanent magnets, a Neodymium-Iron-Boron (NdFeB) magnet embedded inside an Aluminum-Nickel-Cobalt (Alnico) magnet, and two steel plates, one placed above the magnets and the other placed below the magnets. When the poles of the permanent magnets are parallel (same directions of magnetization), the steel plates act as poles of a permanent magnet combination, with the ability to attract ferromagnetic and paramagnetic materials and repel diamagnetic materials [1]. When the poles of the permanent magnets are antiparallel (directions of magnetization opposite), the magnetic field (magnetic flux) is contained within the steel plates and permanent magnets, and the steel plates are unable to interact with (create a force on) other magnetic materials.
The dimensions of an embodiment of an EPM, and the relative dimensions of subparts of the EPM, were optimized using Comsol Multiphysics simulations, by individually manipulating (varying) each of various parameters. The embodiment incorporates a cylindrical switching permanent magnet (Alnico) having a cylindrical bore therethrough along a central longitudinal axis of the Alnico magnet, with a cylindrical fixed permanent magnet (NdFeB) positioned in the bore, such that the Alnico magnet and the NdFeB magnet are concentric and have the same length, and are positioned at the same axial position. It was determined that important factors for creating an EPM that has a high holding force when the EPM is in the on position and a low holding force when in the off position were the thickness of the steel plates, the ratio of the volumes of the two permanent magnets, and the aspect ratio (L/D) of the permanent magnet assembly. The poles (direction of magnetization) of the Alnico magnet are reversed using a copper coil that wraps around the Alnico magnet, with the NdFeB magnet positioned within the Alnico magnet, and flips the magnetization of the Alnico magnet, without flipping the magnetization of the NdFeB magnet, due to the low coercivity of the Alnico magnet and the high coercivity of the NdFeB magnet [2]. A current is passed through a separate electric circuit, and through the coil, to create a magnetic field to reverse the magnetization of the Alnico.
Using 2D simulations in COMSOL Multiphysics, the B fields and latching forces of both the transversal field architecture and the axisymmetric field architecture were studied as a function of several design variables, including: outer radius of cap plate, aspect ratio (L/D) of permanent magnet assembly (NdFeB and AlNiCo), ratio of radius of fixed permanent magnet (NdFeB) radius to radius of switchable permanent magnet (AlNiCo), and cap plate thickness. For the simulations, the following materials were assumed: grade N52 NdFeB as fixed (i.e., not switched) inner permanent magnet, grade 5 AlNiCo for the outer switching magnet, and mild/low-carbon steel (AISI 1018) for the cap plates. The cap plate thickness was found to be an important variable for tuning the on/off latching force ratio.
Embodiments can incorporate two permanent magnets, where the fixed permanent magnet is an Aluminum-Nickel-Cobalt (Alnico) magnet (Sintered Alnico 5 with a coercivity of 48 KA/m and a residual induction of 1.26 T) and the switchable permanent magnet is a Neodymium-Iron-Boron (NdFeB) magnet (Grade N40 NIB with a coercivity of 1000 KA/m and a residual induction of 1.28 T)
Simulations of the external magnetic field of the optimal EPM evidenced ˜10× difference in external B field near the EPM poles in the on/off states (
The materials for fabricating the EPMs shown in
The magnets were secured using crystal bond glue, which was removed after fabrication. The carbon steel was held in place using clamps. During fabrication, oil was applied to the steel and pressurized air was released when buildup accumulated around the tip. After fabrication, the pieces were sanded to remove any sharp edges or abnormalities.
Coil windings were wound around the AlNiCo magnets by fastening the AlNiCo magnets to two plastic plates using superglue and wrapping the copper wire around the magnets. After the coils were wrapped, the ends of the coil were secured and the plastic plates were removed. The resistance and inductance of the coil were measured with the Tongui LCR Meter TH2811D to determine the maximum current that could be safely passed through the coil. The EPM was constructed using the NdFeB magnet and the AlNiCo magnet with the coil wrapped around it. A measuring setup was assembled to electrically switch the conventional EPM transversal field architecture configuration.
A specific embodiment of a method of making an EPM core can include:
start with first magnetic material for switchable (or fixed);
demagnetize the first magnetic material, which allows magnetic powder to be introduced into the bore;
create a bore into, and preferably through, the first magnetic material (before or after demagnetization); and
position a second magnetic material at least partially into bore, to create a fixed magnet.
The switching magnet can be demagnetized in this method by applying a magnetic field opposite to the magnetization, where the field amplitude exceeds the material coercivity of the switching magnet, or by subjecting the switching magnet to a temperature that is close to or exceeds the material Curie temperature of the switching magnet (an intrinsic property of the switching magnet magnetic material). Further embodiments can then add a top shunt plate at top of EPM core and/or add a bottom shunt plate at bottom of EPM core. Still further embodiments can a coil positioned with respect to the EPM core, or the EPM core with one or two shunts plates, so as to apply the switching magnetic fields when driven with a switching coil current.
The simulation results and measurement results from the manually assembled EPM devices (shown in
Embodiments of the invention are directed to an EPM that can be built at a microscopic scale, e.g., the overall switching magnet (EPM) diameter, or thickness, can be <1 mm, <100 micrometers, and/or <10 micrometers, without substantially losing the strength of the magnetic field. An embodiment of the electropermanent magnet includes a cylindrical NdFeB magnet embedded in a cylindrical AlNiCo magnet. On the top and bottom (i.e., each end of the cylindrical permanent magnets) are two end caps made of a ferromagnetic material (made of low-carbon steel), forming a small EPM, as shown in
To optimize the EPM axisymmetric field architecture configuration, simulations were run in Comsol Multiphysics 5.2a. Dimensions of the EPM were manipulated individually, and then the dimensions indicated were used in simulations. The parameters that were changed included the aspect ratio (L/D) of the magnet assembly (where D is the diameter and L is the length of the cylindrical magnet assembly), the ratio of the radius of the steel plates to the outer radius of the Alnico magnet, the ratio of the radius of the NdFeB magnet to the radius of the AlNiCo magnet, and the thickness of the steel plates. The efficacy of the configurations was determined by finding the holding force in the on position and dividing it by its holding force in the off position to find the on/off holding force ratio. Two-dimensional axisymmetric simulations were used to simulate three-dimensional configurations to minimize the time spent running simulations.
The properties of the NdFeB magnets, the AlNiCo magnets, and the steel plates were measured using the GMW Magnetic Systems Model 3473-70 Vibrating Sample Magnetometer (VSM) by measuring the magnetization of the materials with the change in the external B-field applied to the material. To measure the materials, each magnet was magnetized up out of plane and the materials were attached to glass probes using double-sided tape. The properties of the magnets and steel plates were measured out of plane and inputted into the simulations using the procedures described in [1][2].
After running simulations to select the EPM configurations, the EPMs shown in
The holding force of the embodiment of the subject EPM shown in
The aspect ratio of the permanent magnet assembly was varied while keeping the volume of the magnet assembly constant and plotted on the logarithmic graph shown in
When the ratio of the radius of the steel to the outer radius of the AlNiCo was simulated, the force was maximized when the radius of the steel was equal to the outer radius of the AlNiCo, as can be seen in the logarithmic graph in
The on/off holding force ratio was maximized when the ratio of the radius of the NdFeB to the radius of the AlNiCo was 0.6 (e.g., (1/2)T/(5/6)T as shown in
When plotted in a double logarithmic graph, as shown in
Rectangular EPMs were constructed and tested. 40 V were used to reverse the magnetization of the AlNiCo, but it was not enough to completely reverse the magnetization of the AlNiCo. When the AlNiCo magnet was fully magnetized, the field strength at the surface was approximately 38 mT, but the field strength at the surface was only approximately 18 mT when reversed electrically. The on/off holding force ratio was 1.3 in this configuration.
An embodiment of the invention relates to a cylindrical EPM as shown in
The properties of the NdFeB, AlNiCo, and steel limit the EPM configurations that can be constructed and effectively be turned on and off. Because the retentivity of the NdFeB magnet is larger than the coercivity of the AlNiCo magnet, the NdFeB magnet has the potential to inadvertently reverse the magnetization of the AlNiCo magnet. In specific embodiments, the size of the NdFeB magnet is restricted such that the volume of the NdFeB magnet is less than or equal to the volume of the AlNiCo magnet. Similarly, because the saturation of the NdFeB magnet is greater than the saturation of the AlNiCo magnet, the AlNiCo magnet must be larger than the NdFeB to counter the magnetic field of the NdFeB magnet.
The ratio of the radius of the NdFeB magnet to the radius of the AlNiCo magnet, illustrated in
Other important parameters that impact the performance of a cylindrical EPM with a high on/off holding force ratio are the aspect ratio of the NdFeB magnet and the ratio of the radius of the steel to the radius of the AlNiCo magnet. As shown in
Experimental testing showed that the magnetization of the AlNiCo can be reversed with an electric current passing through the coil, without reversing the magnetization of the NdFeB. An EPM in accordance with the subject invention having a rectangular configuration was used due to difficulties in machining AlNiCo magnets. The on/off holding force ratio of the rectangular EPM was 1.3, which is too low to be considered effective. However, the magnetization of the AlNiCo magnet was only partially reversed, which reduced the on/off holding force ratio, but smaller EPMs require less current to reverse the magnetization of the AlNiCo magnet.
A specific embodiment of a magnet assembly (EPM core) is shown in
The functionality of the embodiment was demonstrated as explained. The EPM cores were magnetically characterized by using a vibration sample magnetometer (VSM, ADE Technologies EV9), where
Additional magnetic characterization was performed by obtaining magneto optical images (MOI) and using a pulse magnetizer to switch the EPM cores from the on state (pulsing 7 T in the axial direction) to the off state (by pulsing −700 mT for SmCo or −440 mT for NdFeB EPMs). MOI characterization (shown in
From the MOI images is it possible to calculate the magnetic flux (in units of nWb) produced by the EPM core when magnetized at different reversal magnetic fields (shown in
Fully assembled EPMs with the steel cap plates were also used to measure the magnetic flux in the on/off state (by applying the reversal magnetic fields described above). An EPM that can be turned “on” and “off” and have a magnetic flux on/off ratio of ˜2 was achieved for both fixed magnet materials.
An assembly of a microbalance (Explorer 2, Ohaus) with an automated 3D micro positioner (built with Newport DC servo controllers) was implemented as a variation of experiments proposed by [8], to measure the latching force between the EPM and an approximately infinite ferromagnetic plate (mild/low-carbon steel AISI 1018). By cautiously lowering the EPM over the ferromagnetic plate, the latching force raises the plate away from the balance and the force is registered as weight in the balance.
Embodiments of the EPM core can have multiple bores, such as shown in
Further, embodiments can have multiple “on states” by using two or more switching magnetic materials, and or applying the switching magnetic field to multiple portions of the EPM core.
In an embodiment, a second switching magnetic material can be positioned in a portion of each bore (e.g., the bottom half), a subset of bores (e.g., every other bore of n bores positioned in a radially symmetric pattern), or combination thereof, in a first switching magnetic material, and the fixed magnetic material can be positioned in the remaining portion of each bore (e.g., the top half), and the remaining bores (e.g., the other every other bore of the n bores positioned in the radially symmetric pattern), and then subject to EPM core to a first switching magnetic field strong enough to switch the first switching magnetic material, or the second switching magnetic material, to create a “first on state,” or subject to EPM core to a second switching magnetic field strong enough to switch both the first switching magnetic material and the second switching magnetic material, to create a “second on state.”
In an embodiment, positioning multiple coils (to apply the switching magnetic field) can be positioned with respect to the EPM core, so that each coils only “reverses” a portion of the switching magnet when driven with the corresponding switching current, such that different combinations of coils can be driven to switch different combinations of portions of the switching magnet. In a specific embodiment, two coils, where a first coil switches a first portion of the switching magnet and a second coil switches a second portion of the switching magnet, can be used, where the switching magnetic flux due to the first portion of the switching magnet and the second portion of the switching magnet are different (e.g., the switching magnetic flux of first portion is ⅓ of the total switching magnetic flux and the switching magnetic flux of second portion is ⅔ of the total switching magnetic flux), such that by: switching the first portion of the switching magnet only; switching the second portion of the switching magnet only; or switching both portions of the switching magnet, one of three different “on-states” of the switchable magnet can be achieved (i.e., a “first on state” having ⅓ of the total switching magnetic flux; a “second on state” having ⅔ of the total switching magnetic flux; and a “third on state” having 3/3 of the total switching magnetic flux).
This example relates to a method of operating an EPM in a manner to create a plurality of “on states” where a magnetization of the one or more switching magnets is different for each on state of the plurality of “on states.” In an embodiment, the magnetization of the one or more switching magnets can vary from a magnetization having a maximum magnetization magnitude in a first direction to a magnetization having the maximum magnetization magnitude in a second direction, having an opposite direction to the first direction. When the magnetization of the one or more fixed magnets is in the second direction: the one or more switching magnets having a magnetization having the maximum magnetization magnitude in the first direction can be the off state of the EPM, and results in creating a minimum flux and minimum latching force; where the one or more switching magnets having a magnetization having the maximum magnetization magnitude in the second direction can be the “maximum on state” of the EPM, and result in creating a maximum flux and maximum latching force. The EPM can be operated to also be switched to (transitioned to) one or more additional on states, where the one or more switching magnets have a magnetization having less than the maximum magnetization magnitude in the second direction (or a magnetization having less than the maximum magnetization magnitude in the first direction). Each of these one or more additional on states results in a flux less than the maximum flux and a latching force less than the maximum latching force. Switching (or transitioning): from the off state to one of the on states; from one of the on states to another of the on states; or from one of the on states to the off state, is accomplished by applying a switching magnetic field having an appropriate magnitude and direction, and sufficient duration, where to transition from the off state to one of the maximum on state, or to transition from the maximum on state to one of the off state, a magnetic field having a switching magnitude at or above the magnitude of magnetic field that fully magnetizes the switching magnetic material is applied, and to transition from any state to any on state other than the maximum on state, a magnetic field having a switching magnitude below the magnitude of magnetic field that fully magnetizes the switching magnetic material, and has a magnitude corresponding to the desired state, is applied.
For an embodiment, such as disclosed in
Embodiment 1. A switchable magnet, comprising:
a magnet assembly,
wherein the magnet assembly comprises:
wherein the coil is positioned with respect to the magnet assembly such that:
a first shunt plate; and
a second shunt plate,
wherein the first shunt plate and the second shunt plate are positioned with respect to the magnet assembly such that:
Embodiment 2. The switchable magnet according to Embodiment 1,
wherein the one or more fixed magnets of the at least one fixed magnet are positioned within the corresponding one or more bores through the first switching magnet of the at least one switching magnet.
Embodiment 3. The switchable magnet according to Embodiment 2,
wherein the one or more fixed magnets of the at least one fixed magnet is a first fixed magnet, and the at least one switching magnet is a first switching magnet of the at least one switching magnet, such that the first fixed magnet is positioned within a bore through the first switching magnet.
Embodiment 4. The switchable magnet according to Embodiment 3,
wherein the first fixed magnet and the first switching magnet are concentric.
Embodiment 5. The switchable magnet according to Embodiments 3 or 4,
wherein the first fixed magnet and the first switching magnet are coaxial.
Embodiment 6. The switchable magnet according to Embodiments 3, 4, or 5,
wherein the on state switching magnetic flux is in a range of 95% to (1/0.95)% of the fixed on state magnetic flux.
Embodiment 7. The switchable magnet according to Embodiments 3, 4, 5, or 6,
wherein the off state switching magnetic flux is in a range of 95% to (1/0.95)% of the on state switching magnetic flux.
Embodiment 8. The switchable magnet according to Embodiments 3, 4, 5, or 6,
wherein the off state switching magnetic flux is in a range of 90% to (1/0.90)% of the on state switching magnetic flux.
Embodiment 9. The switchable magnet according to any of Embodiments 4-8,
wherein the coil is positioned with respect to the magnet assembly such that:
Embodiment 10. The switchable magnet according to any of Embodiments 4-8,
wherein the coil is positioned with respect to the magnet assembly such that:
Embodiment 11. The switchable magnet according to Embodiments 1-4,
wherein the first fixed magnet is cylindrically shaped.
Embodiment 12. The switchable magnet according to Embodiments 1-11,
wherein the bore through the first switching magnet is cylindrically shaped.
Embodiment 13. The switchable magnet according to Embodiments 1-11,
wherein the first switching magnet is cylindrically shaped.
Embodiment 14. The switchable magnet according to Embodiments 1-13,
wherein the first shunt plate and the second shunt plate are cylindrically shaped, and
wherein the first shunt plate and the second shunt plate are coaxial with the first fixed magnet and the first switching magnet.
Embodiment 15. The switchable magnet according to Embodiments 1-13,
wherein the coil is cylindrically shaped.
Embodiment 16. The switchable magnet according to Embodiments 1-15,
wherein the first coil created magnetic field is uniform within an interior of the coil, and the second coil created magnetic field is uniform within the interior of the coil.
Embodiment 17. The switchable magnet according to Embodiments 1-15,
wherein the coil is positioned adjacent to an exterior surface of a side of the first switchable magnet.
Embodiment 18. The switchable magnet according to Embodiments 1-17,
wherein the on state external magnetic field is symmetrical about a longitudinal axis of the switchable magnet, and
wherein the off state external magnetic field is symmetrical about the longitudinal axis of the switchable magnet.
Embodiment 19. The switchable magnet according to Embodiments 1-17,
wherein the on state external magnetic field is not symmetrical about a longitudinal axis of the switchable magnet,
wherein, absent the presence of the first shunt plate and the second shunt plate, when the second direction of magnetization is in the first direction, an on state fixed magnetic flux exits out of the north end of the at least one fixed magnet and enters into the south end of the at least one fixed magnet, and an on state switching magnetic flux exits out of the north end of the at least one switching magnet and enters into the south end of the at least one switching magnet, so as to create an on state magnet assembly created external magnetic field, wherein the on state magnet assembly created external magnetic field is symmetrical about the longitudinal axis of the switchable magnet,
wherein the off state external magnetic field is not symmetrical about the longitudinal axis of the switchable magnet, and
wherein, absent the presence of the first shunt plate and the second shunt plate, when the second direction of magnetization is in the second direction, an off state fixed magnetic flux exits out of the north end of the at least one fixed magnet and enters into the south end of the at least one fixed magnet and/or the south end of the at least one switching magnet, and an off state switching magnetic flux exits out of the north end of the at least one switching magnet and enters into the south end of the at least one switching magnet and/or the south end of the at least one fixed magnet, so as to create an off state magnet assembly created external magnetic field, wherein the off state magnet assembly created external magnetic field is symmetrical about the longitudinal axis of the switchable magnet.
Embodiment 20. The switchable magnet according to Embodiments 3-19,
wherein the first fixed magnet is made of NdFeB and the first switching magnet is made of Alnico.
Embodiment 21. The switchable magnet according to Embodiments 5-20,
wherein the first fixed magnet has a length LF along a longitudinal axis of the first fixed magnet,
wherein the first switching magnet has a length LS along a longitudinal axis of the first switching magnet,
wherein LF is equal to LS, and
wherein longitudinal axis of the first switching magnet is coextensive with the longitudinal axis of the first fixed magnet.
Embodiment 22. The switchable magnet according to Embodiment 1,
wherein the one or more switching magnets of the at least one switching magnet are positioned within the corresponding one or more bores through the first fixed magnet of the at least one fixed magnet.
Embodiment 23. The switchable magnet according to Embodiment 22,
wherein the one or more switching magnets of the at least one switching magnet is a first switching magnet, and the at least one fixed magnet is a first fixed magnet of the at least one fixed magnet, such that the first switching magnet is positioned within a bore through the first fixed magnet.
Embodiment 24. The switchable magnet according to Embodiments 22-23,
wherein the first fixed magnet and the first switching magnet are concentric.
Embodiment 25. The switchable magnet according to Embodiments 22-24,
wherein the first fixed magnet and the first switchable magnet are coaxial.
Embodiment 26. The switchable magnet according to Embodiments 22-23,
wherein the on state switching magnetic flux is in a range of 95% to (1/0.95)% of the on state fixed magnetic flux.
Embodiment 27. The switchable magnet according to Embodiments 22-23,
wherein the off state switching magnetic flux is in a range of 95% to (1/0.95)% of the on state switching magnetic flux.
Embodiment 28. The switchable magnet according to Embodiments 22-23,
wherein the off state switching magnetic flux is in a range of 95% to (1/0.95)% of the on state switching magnetic flux.
Embodiment 29. The switchable magnet according to Embodiments 22-23,
wherein the coil is positioned with respect to the magnet assembly such that:
Embodiment 30. The switchable magnet according to Embodiments 22-23,
wherein the first switching magnet is cylindrically shaped.
Embodiment 31. The switchable magnet according to Embodiments 22-30,
wherein the bore through the first fixed magnet is cylindrically shaped.
Embodiment 32. The switchable magnet according to Embodiments 22-31,
wherein the first fixed magnet is cylindrically shaped.
Embodiment 33. The switchable magnet according to Embodiments 22-32,
wherein the first shunt plate and the second shunt plate are cylindrically shaped, and
wherein the first shunt plate and the second shunt plate are coaxial with the first fixed magnet and the first switching magnet.
Embodiment 34. The switchable magnet according to Embodiments 22-32,
wherein the coil is cylindrically shaped.
Embodiment 35. The switchable magnet according to Embodiments 22-34,
wherein the first coil created magnetic field is uniform within an interior of the coil, and the second coil created magnetic field is uniform within the interior of the coil.
Embodiment 36. The switchable magnet according to Embodiments 22-34,
wherein the coil is positioned adjacent to an exterior surface of a side of the first fixed magnet.
Embodiment 37. The switchable magnet according to Embodiments 22-23,
wherein the first fixed magnet is made of NdFeB and the first switching magnet is made of Alnico.
Embodiment 38. The switchable magnet according to Embodiments 22-25,
wherein the first fixed magnet has a length LF along a longitudinal axis of the first fixed magnet,
wherein the first switching magnet has a length LS along a longitudinal axis of the first switching magnet,
wherein LF is equal to LS, and
wherein longitudinal axis of the first switching magnet is coextensive with the longitudinal axis of the first fixed magnet.
Embodiment 39. The switchable magnet according to Embodiments 22-23,
wherein the first fixed magnet is made of NdFeB and the first switching magnet is made of Alnico.
Embodiment 40. The switchable magnet according to Embodiments 22-25,
wherein the first fixed magnet has a length LF along a longitudinal axis of the first fixed magnet,
wherein the first switching magnet has a length LS along a longitudinal axis of the first switching magnet,
wherein LF is equal to LS, and
wherein longitudinal axis of the first switching magnet is coextensive with the longitudinal axis of the first fixed magnet.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/US2017/065145 | 12/7/2017 | WO | 00 |
Number | Date | Country | |
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62431239 | Dec 2016 | US |