The present invention relates to magnetic parallel dipole line (PDL) trap systems, and more particularly, to a motor-actuator device using a PDL trap system.
There is a need to construct miniature, micro-scale motors for various applications such as micromechanical systems for micro and nanotechnology. Unfortunately, traditional electric motor systems prohibit down scaling due to the various components needed for the designs and the overall contact nature of the system.
As such, a dramatically different electric motor architecture is needed that allows miniaturization. One important requirement at small scale is that the motor has to have a non-contact design, otherwise the friction loss over the rotational kinetic energy of the system becomes too large making the operation of the motor very difficult if not impossible. Another important factor at play in micromechanical systems is the significant adhesion force between micro- and nano-scale objects attributed to van der Walls and Casimir force.
Thus, an improved, scalable electric motor architecture would be desirable.
The present invention provides a motor-actuator device using a parallel dipole line (PDL) trap system. In one aspect of the invention, a motor-actuator device is provided. The motor-actuator device includes: a PDL trap having a pair of diametric magnets, and a levitated diamagnetic rotor in between the diametric magnets, wherein at least a portion of the diamagnetic rotor has a rectangular shape; and an electrode shell having at least one pair of semicircular electrodes which surround, but are in a non-contact position with the levitated diamagnetic rotor and each other.
In another aspect of the invention, a system is provided. The system includes: a motor-actuator device including: i) a PDL trap having a pair of diametric magnets, and a levitated diamagnetic rotor in between the diametric magnets, wherein at least a portion of the diamagnetic rotor has a rectangular shape, and ii) an electrode shell having at least one pair of semicircular electrodes which surround, but are in a non-contact position with the levitated diamagnetic rotor and each other; and an electrode driver circuit connected to each electrode in the electrode shell and which is configured to apply electric pulses to the at least one pair of semicircular electrodes.
In yet another aspect of the invention, a method of operating a motor-actuator device is provided. The method includes: providing the motor-actuator device having: i) a PDL trap having a pair of diametric magnets, and a levitated diamagnetic rotor in between the diametric magnets, wherein at least a portion of the diamagnetic rotor has a rectangular shape, and ii) an electrode shell having at least one pair of semicircular electrodes which surround, but are in a non-contact position with the levitated diamagnetic rotor and each other; and applying electric pulses to the at least one pair of semicircular electrodes causing the levitated diamagnetic rotor to rotate.
A more complete understanding of the present invention, as well as further features and advantages of the present invention, will be obtained by reference to the following detailed description and drawings.
Provided herein are miniature levitated electric motors using a parallel dipole line (PDL) trap system. As will be described in detail below, the present motor design can be implemented using a capacitive drive system with multiple electrodes enclosing, but not physically contacting, a levitated object (the rotor) levitated in the PDL trap. Since the system operates in a levitated state, advantageously there is no friction or adhesion force other than viscous forces due to air. As such, the system requires a small amount of power to operate and is scalable to very small sizes, i.e., in the micro-scale range.
The present PDL trap-based motor system also provides an additional notable feature. By controlling the voltage bias, the position of the rotor can be controlled. Thus, the system also serves as a linear actuator.
A PDL trap consists of a magnetic parallel dipole line system made of a pair of transversely magnetized cylindrical (or diametric) magnets that naturally join together. See, for example,
The central feature of the PDL trap is the existence of a “camelback magnetic potential” along the longitudinal (z-axis), i.e., the magnetic field is enhanced near the edge of the dipole line which occurs for a diametric magnet with length L approximately L>2.5a, wherein a is the radius of the magnet. See, for example, FIG. 1 of Gunawan 2017.
According to an exemplary embodiment of the present PDL trap-based motor design, the trapped diamagnetic object is a rectangular slab of an electrically conductive material, such as graphite. This trapped diamagnetic object will serve as the rotor, i.e., it is the component of the motor that spins and/or is actuated. See
A pair of electrode shells are used surrounding (but not in physical contact with) the rectangular slab that serve a capacitor. An enlarged view of the rectangular slab and electrode shells is shown in
As the rectangular slab rotates, the capacitance of the system changes. This change of capacitance (C) as a function of angular displacement (θ) will create a torque (τ) as the voltage bias (V) is applied:
wherein the system torque (τ) is:
τ=∂U/∂θ=−ΔCV2 cos 2θ (2)
Therefore, by applying voltage bias pulses torque is applied to and rotates the rectangular slab/levitated rotor. See, for example,
As provided above, another notable feature of the present system is that it can also serve as a linear actuator. For instance, consider a parallel plate capacitor model consisting of top and bottom electrode plates, and a conductor that freely moves along the z-axis at constant spacing d1 and d2 between the electrode plates. See, for example, FIGS. 1 and 2 of U.S. patent application Ser. No. 15/131,443 by Oki Gunawan, entitled “Voltage-Tunable 1D Electro-Magnet Potential and Probe System with Parallel Dipole Line Trap” (hereinafter “U.S. patent application Ser. No. 15/131,443”), the contents of which are incorporated by reference as if fully set forth herein.
The capacitance C (per unit normal length l) as a function of the conductor center position (z) is given as:
wherein |x| is the absolute value of z. The capacitance of the system increases as the conductor enters in between the electrode plates. This happens because the conductor screens out all electric field, thus effectively making the spacing between the electrode plates smaller.
Assuming an isolated system and that the electrode plate is charged by an amount Q, then the energy of the capacitor UC is:
U
C
=Q
2/2C. (4)
This means that the internal energy is lower when the conductor is in between the electrode plates implying that, if the conductor moves freely, it will get attracted toward the center of the capacitor.
The PDL trap with top electrode yields a tunable 1D hybrid magneto-electric potential system for the diamagnetic rod levitating at height y0. The energy potential per unit volume has two components:
Thus, the final total energy (UME) is:
wherein χ is the magnetic susceptibility of the diamagnetic object (which has a negative value), the physical constant μ0 is the magnetic permeability of vacuum, and V is the voltage bias and C(z) is the capacitance of the system as a function of rod position z as described in Equation 3 above.
Referring, for example, to FIG. 6 in U.S. patent application Ser. No. 15/131,443, the magnetic camelback potential provides the base confinement for the PDL trap. With increasing voltage there is a negative electrostatic potential contribution underneath the electrode that pulls the trapped object towards the electrode. In other words, with increasing voltage bias the minimum of the magneto-electric camelback potential shifts towards the electrode. As such, this yields a voltage-controlled tunable 1D potential and the position of the diamagnetic object in the PDL trap can be controlled with the voltage bias. In this levitated rotor application, the diamagnetic rod would be shaped to have a rectangular cross section that allows variation in the capacitance as a function of angular rotation.
A combination of the above-described principles relating to rotation and linear actuation of the rectangular slab in the PDL trap is leveraged herein to produce a hybrid motor-actuator system. See, for example,
The levitated rotor levitates in between the PDL magnets. As provided above, the levitated rotor can be a rectangular diamagnetic slab. As shown in
The electrode shell includes at least one pair of semicircular electrodes which surround but do not contact/touch the levitated rotor (or each other). For instance referring again to
Operation of the present levitated rotor motor-actuator device is now described by way of reference to the motor-actuator system shown in
An electrode driver circuit (“electrode driver”) is connected to each of the electrodes and serves to deliver the proper phase electric pulse to the electrode pairs at the proper frequency. For instance, referring to methodology 600 of
With regard to linear actuation motion, as provided above the position of the diamagnetic object in the PDL trap can be controlled via the voltage bias by shifting the minimum of the magneto-electric camelback potential. Namely, by varying the amplitude of the voltage bias being applied to the electrode shell by the electrode driver (see above), the linear position of the levitated rotor relative to the electrode shells can be changed (i.e., actuating the levitated rotor in the device). See step 606.
It is notable that the motor and linear actuation functions of the device can be operated together. For instance, the electrode driver can apply the electric pulses in the above-described manner to cause the levitated rotor to spin, while at the same time varying the amplitude of the electric pulses to linearly actuate the (spinning) levitated rotor. The device can also be operated as a motor independent of a linear actuation, and vice versa.
Referring back to
A variety of different motor-actuator designs can be implemented in accordance with the present techniques. For instance, as shown in the three-dimensional rendering provided in
One important design consideration is, regardless of the shape/configuration of the end of the levitated rotor, the portion of the levitated rotor within the electrode shell has to be rectangular. As described above, a rectangular shape is needed for rotation of the levitated rotor. See
Turning now to
Apparatus 800 includes a computer system 810 and removable media 850. Computer system 810 includes a processor device 820 (e.g., a microprocessor, CPU etc.), a network interface 825, a memory 830, a media interface 835 and an optional display 840. Network interface 825 allows computer system 810 to connect to a network, while media interface 835 allows computer system 810 to interact with media, such as a hard drive or removable media 850.
Processor device 820 can be configured to implement the methods, steps, and functions disclosed herein. The memory 830 could be distributed or local and the processor device 820 could be distributed or singular. The memory 830 could be implemented as an electrical, magnetic or optical memory, or any combination of these or other types of storage devices. Moreover, the term “memory” should be construed broadly enough to encompass any information able to be read from, or written to, an address in the addressable space accessed by processor device 820. With this definition, information on a network, accessible through network interface 825, is still within memory 830 because the processor device 820 can retrieve the information from the network. It should be noted that each distributed processor that makes up processor device 820 generally contains its own addressable memory space. It should also be noted that some or all of computer system 810 can be incorporated into an application-specific or general-use integrated circuit.
Optional display 840 is any type of display suitable for interacting with a human user of apparatus 800. Generally, display 840 is a computer monitor or other similar display.
Although illustrative embodiments of the present invention have been described herein, it is to be understood that the invention is not limited to those precise embodiments, and that various other changes and modifications may be made by one skilled in the art without departing from the scope of the invention.