This application relates generally to a timing device that has a magnetic levitation mechanism, and more particularly to clocks and visual aids for use in time management, goal management, and scheduling.
Magnetic levitation devices selectively oscillate or modulate a levitating force to float or levitate a displayed object or to animate an object and have been available for many years. Manipulating magnetic fields and controlling their forces to levitate an object is disclosed in many references. Such references include mechanisms for magnetically levitating an object, as well as controlling the spatial position of such a magnetically levitated object. Magnetic levitation devices typically use a horizontal support stand to provide an overhead electromagnet, and an object with a permanent magnet or at least a ferrous object embedded within it or on an outer surface is then positioned under the electromagnet. Some of the references of magnetic levitation systems are shown in U.S. Pat. Nos. 6,595,041, 6,035,703, 5,980,193, 5,319,670, 5,168,183, 4,585,282, and 4,191,951, all of which are incorporated by reference.
A magnetically levitated object can be suspended above a base by magnetic fields. An electromagnetic force is used to counteract the effects of gravitation. The forces acting on an object in any combination of gravitational, electrostatic, and magnetostatic fields will make the object's position unstable. The reason a permanent magnet suspended above another magnet is unstable is because the levitated magnet will easily overturn and the force will become attractive.
Magnetic levitation techniques have been used in the railways, mechanical equipment, floating globes, etc. Magnetic levitation technology has been incorporated into the designs of intelligent home appliances, such as a table lamp. U.S. Pat. Nos. 5,638,340 and 5,159,583 disclose clocks employing magnetically levitated mechanism.
Accordingly, there is always a need for improved timing devices and other novelty devices. There is also a need for an interactive timing device that can provide, among other things, time management, scheduled events reminders, goal management, and scheduling assistance. It is to these needs, among others, that this application is directed.
This application provides an interactive magnetic levitation timing device for, among other things, managing time, goal management, scheduling at least an event and remembering the scheduled events. The timing device visually reveals the time or period during which a predetermined event is scheduled to occur.
One embodiment includes a magnetic levitation timing device for levitating a marker or suspending the marker away from the device having a housing, an electromagnetic force driving configuration, wherein an electromagnetic force produced in the electromagnetic force driving configuration can move or rotate the marker at a constant or variable speed on, about or around the outer portion of the housing; a rotating disc configured with the electromagnetic configuration; and a gear assembly configured to move or rotate the electromagnetic configuration. The magnetic levitation timing device can have a timing mechanism, an electromagnetic force driving configuration, indicia (that may be on the housing of the device) and a marker on or above the housing. The outer portion of the housing can include indicia and can display information, e.g., about the timing elements. The housing may be configured to secure the device on a horizontal or non-horizontal surface (e.g., an angle greater than 10 degrees).
In another embodiment, the electromagnetic force from the magnet levitates or suspends the marker so that it may move or rotate at a constant or variable speed about or around the surface of the device. The marker may be a magnetic material or a permanent magnet. The marker may have various shapes including, e.g., a floating ball, cube, or other shape.
In another embodiment, the magnetic levitation timing device includes an interactive display. The device is further provided with indicia, including, but not limited to, goal marker or event indicia. The indicia can be removable or affixed to the upper surface or can be rearranged depending on the need of the user. The indicia may be disposed in relation to the marker such that the marker signals during the scheduled time that the particular event is to occur.
In another embodiment, the magnetic levitation timing device comprises a housing that has an electromagnetic force driving configuration and a marker. The outer portion of the housing can have grooves or marks representing the indicia. The lower portion of the housing can be configured to secure the device to a mounting surface. Inside the housing, there can be a rotating disc configured with a rotating assembly and the electromagnetic force driving configuration. The electromagnetic driving force configuration may include a magnet and coil array into a mounting plate assembled with the rotating disc. The marker is placed above the outer portion of the housing or over the rotating disc. The rotating assembly rotates the rotating disc and an electromagnetic force from the magnet levitates or suspends the marker, which may move or rotate at a constant or variable speed about or around the outer portion of the housing. In one embodiment, the rotating assembly includes a motor with gear mounted on a gear arranged on the rotating disc.
In some embodiment, the marker can move along a linear, rather than circular path on the surface of the magnetic levitation timing device. In some embodiments, the marker may be luminescent. For example, a transmitting coil can transmit power to the marker, which may allow the marker to illuminate. The marker can illuminate around or along the upper surface.
In some embodiment, the magnetic levitation timing device is desired to depict events over a nonstandard period of time. In other embodiment, the magnetic levitation timing device is desired to depict standard time, including, but not limited to, minutes, hours, second, days, etc.
In some embodiments, the magnetic levitation timing device may include non-magnetic or levitating features. For example, the magnetic levitation timing device may have a digital display or another feature that is not magnetically driven.
The application includes the use of an electromagnetic theory of the permanent magnet that moves a metallic object around or about the surface.
Other features and advantages of the present invention will become apparent from following specification taken in conjunction with the enclosed drawings.
The drawings and the associated descriptions are provided to illustrate embodiments:
Specific embodiments include a magnetic levitation or an electromagnetic timing device that includes a timing mechanism, a magnetic marker operatively connected to the timing mechanism, and indicia (e.g., a goal marker). As used herein, the term “levitated” or “levitation” includes an object held aloft or suspended away from (e.g., horizontal) a device, without mechanical support, in a stable position. That is, the magnetic levitation or the electromagnetic timing device can be mounted on surfaces that may not be horizontal and the device can operate accordingly such that the marker is suspended away from the device.
Now referring to
In one embodiment, the electromagnetic driving force configuration 55 may include a magnet 52 and coil array 53. In this embodiment, the motor 60 with the gear 70 is configured to drive the rotating disc 50, which holds the electromagnetic driving force configuration 55 that magnetically levitates or holds away the marker 20 on the outer portion of the housing. Components involved in mechanically driving the rotating disc 50 further includes a gear 85 that snap fits into the motor 60 with gear 70. The magnet 52 can be a permanent magnet or at least ferrous object mounted within a mounting plate 51. The magnet 52 is integrated with the coil array 53 formed by electromagnetic coils or coil windings or copper windings. One or more stepper motors or servo motors can provide overall period of movement and thus the movement of the marker 20. A feedback loop may include one or more position sensors (such as a Hall Effect sensor), which compensates for gravity and rotational forces.
In one specific embodiment, the electromagnetic force driving configuration 55 includes the marker 20 and the coil array 50 mounted within the mounting plate 40 and operatively attached to the rotating disc 50 through magnetic mounting groove 12. In another embodiment, the coil array 53 is copper sleeve wound on the magnet 52 to form an electromagnet. A feedback loop may include one or more position sensors 54 (such as a Hall Effect sensor), which compensates for gravity and rotational forces, e.g., on the marker 20.
In another embodiment, the rotating disc 50 includes the motor 60 with gear 70 and the motor housing which are securely attached to form a drive mechanism. The outer portion of the housing 30, the rotating disc 50 and the back portion 40 can be assembled into a compact design that looks like a clock, which can be mounted or placed at an angle greater than for example 10 degrees, 20 degrees, 30 degrees, 40 degrees or at an angle between 1 and 90 degrees. The marker 20 may freely move through the magnetic levitation principle. The movement is realized through electromagnetic force generated from the electromagnetic force driving configuration 55 in conjunction with the mechanical transmission by a motor or multiple motors. The motor 60 is configured to drive the rotating disc 50 and the electromagnetic force levitates the marker 20 on upper side in, e.g., circular movements.
The magnetic levitation timing device 10 may include an interactive display 35 and other operative mechanism such as on/off function (not shown). Further, in one example, the magnetic levitation timing device 10 provides a visual aid for users to help with understanding the concept of time, the concept of passage of time, remembering scheduled events, or the concept of future timelines. The magnetic levitation timing device 10 may visually demonstrate the time during which at least one predetermined event is scheduled to occur. The magnetic levitation timing device can levitate or be held away the marker 20 when mounted at, e.g., 90 degrees, as it can be hung on a vertical surface (e.g., a wall).
In one embodiment, the marker 20 is disposed in relation to indicia 31 such that the indicia 31 signals at a scheduled time corresponding to a particular event. In one example, the magnetic levitation timing device 10 is provided with numerous event indicia 31 that are removable or affixed to the outer portion 30 or can be rearranged depending the need of the user. The marker 20 can be disposed in relation to indicia 31 such that indicia 31 provides a signal during the time the event is scheduled to occur or is desired to ultimately occur. Indicia 31 can visually symbolize (through pictures, words, or otherwise) a past, scheduled, or future event. Depending on the length of a scheduled event, a group of markers can represent a single event. Among other things, the shape of the magnetic levitation timing device 10, orientation and nature of the markers, method of signaling by the indicia, and type and speed of the timing mechanism employed are all variable for use with certain specific embodiments. As a metaphor, the magnetic levitation timing device 10 can tell a “story.”
While the magnetic levitation timing device 10 can have traditional levitation systems and features,
In one embodiment, the magnetic levitation timing device 10 can incorporate a magnetic field (or levitation forces) provided by the magnet 52 oscillated at one or more frequencies. These oscillation or drive frequencies are typically selected to correspond to frequencies of one or more driven or vibrated elements on a supported or magnetically levitated object. The magnetic field or levitating force provided by the electromagnetic force driving configuration 55 and oscillation assembly may be varied using an oscillation signal generator or oscillation driver such as a sinusoidal signal generator feeding an oscillation signal to the levitation driver/actuator controlling the electromagnet or such as an unstable feedback loop for the levitation driver/actuator or via another oscillation means as described herein or as will become apparent based on this description. The electromagnetic configuration can have an oscillation assembly comprising an electromagnet, a levitation driver driving the electromagnet with a control signal to generate a controlled levitating magnetic field. The electromagnetic configuration may be configured with adjustments to compensate for permanent non-equilibrium.
The electromagnetic configuration or assembly can be powered or driven with a control signal that is maintained via a stable feedback loop to provide a suspending magnetic field or levitating force to float or suspend the marker 20 at a fixed distance and position relative to the electromagnet. The feedback loop may include one or more position sensors (such as a Hall Effect sensor) to sense the distance between the levitated marker 20 and either the electromagnet itself or a separate magnet (e.g., a magnet) placed at the bottom or base of the levitated marker 20.
As shown in
In operation, the magnetic levitation timing device 10 works as follows. The timing mechanism moves the marker 20 at a constant or variable speed about or around the face of magnetic levitation timing device 10. A battery or a direct current provides power to the timing mechanism in the “on” position. Optionally, the magnetic levitation timing device 10 can be provided with the ON/OFF switch. Further, when pressing the ON switch, a screen may appear on the display 35. The display 35 may show the current time, to see whether the time reaches the pre-set time; to reach the pre-set given time the event is activated and subsequently the marker 20 starts to float.
In another embodiment, the indicia 31 can move along a linear, rather than circular path on the surface of the magnetic levitation timing device 10. In some embodiments, the indicia 31 may be luminescent. For example, the indicia 31 can illuminate around or along the outer portion 30.
In some embodiments, the magnetic levitation timing device 10 is desired to depict events over a nonstandard period of time. In other embodiments, the magnetic levitation timing device is desired to depict standard time, including, but not limited to, minutes, hours, seconds, days, etc.
In some embodiments, the magnetic levitation timing device 10 may include non-magnetic or levitating features. For example, the magnetic levitation timing device 10 may have a digital display or another feature that is not magnetically driven.
In some embodiments, the device 10 can be at an angle between 0 degrees and 90 degrees from the center. In such an arrangement, the marker 20 is held and moved by the magnetic forces.
In an exemplary use and application shown in
Further in another embodiment, a control unit includes a microcontroller, power module, touch screen module, time module and Bluetooth® module/Wi-Fi module. The power module, touch screen module, time module, and Bluetooth® module/Wi-Fi module are electrically connected to the microcontroller, where the touch screen module uses a resistive touch screen that supports a variety of configuration controls.
In another embodiment, the base may be illuminated from the back side or from the sides of the housing. In this arrangement, the device 10 can have the appearance of a lunar eclipse.
In some embodiments, the marker may be luminescent through power delivered from the electromagnetic configuration. For example, a transmitting coil can transmit power to the marker, which may allow the marker to illuminate. The marker can illuminate around or along the upper surface.
Referring to
The magnetic levitation timing device is capable of other embodiments and of being practiced or carried out in various ways, without departing from the spirit and scope of this application. In another embodiment, the back of the housing or some of the house may have a light or be backlit.
Certain features of the embodiments of the claimed subject matter have been illustrated as described herein; however, many modifications, substitutions, changes and equivalents will now occur to those skilled in the art. Additionally, while several functional blocks and relations between them have been described in detail, it is contemplated by those of skill in the art that several of the operations may be performed without the use of the others, or additional functions or relationships between functions may be established and still be in accordance with the claimed subject matter. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the embodiments of the claimed subject matter.
This application claims the benefit of priority of U.S. Provisional Patent Application No. 62/424,932, filed Dec. 1, 2016 and U.S. Provisional Patent Application No. 62/457,667, filed on Feb. 10, 2017, both of which are incorporated by reference herein in their entirety.
Number | Date | Country | |
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62424932 | Nov 2016 | US | |
62457667 | Feb 2017 | US |