The present invention provides for a protective enclosure comprising a base comprising a first continuous mating surface and at least one conveyance aperture, a cover comprising a second continuous mating surface, wherein the second continuous mating surface is configured to form a seal with the first continuous mating surface, and a clamp, wherein at least a portion of the clamp is coupleable to the base, wherein a mouth of the clamp is configured to be offset from the aperture when the clamp is coupled to the base, wherein the clamp comprises a first sealing layer, and wherein the clamp is configured to seal the aperture against contaminants. The protective enclosure may be configured for use in a remotely controllable model vehicle to protect a control module.

A method that provides a virtual presentation includes providing a real-world toy associated with a registration code, receiving the code by a registration subsystem via a computer interface of a computer system, and validating the registration code. Responsive to the validating, the computer system processes the registration code to transform the real-world toy into a virtual toy that is a virtual replica of the real-world toy in a virtual world to be displayed by a computer display. Content is provided for displaying a virtual room and a selection of virtual furnishings. In response a user command, the virtual furnishings are provided, arranged and displayed at an initial location within the virtual room. In response to another user command, the one or more virtual furnishings are moved to a new virtual location within the virtual room. The virtual toy interacts with one of the virtual furnishings and exhibits an animated response that simulates a real-world activity.

A toy flowerpot with a movable toy flower includes a battery to power a mechanism in the toy flower. The flower includes the parts of a stem, sepal, petals and a front flower face around which the petals are mounted, at least one of which parts is a reactive part. A mechanism moves one or more parts of the flower; and includes an actuator with a magnet and electromagnetic coil with the flower. A signal receiver or sensor of changes causes at least one of movement of the flower parts. A microprocessor processes the signal or sensed change and generates instructions to change the operation of the electromagnetic coil in response to the signal or sensed change.

An eliciting system is provided. The eliciting system may embody a method for collecting market research data by eliciting customer input through an interactive, competitive game format. The eliciting system may provide the game format by including a controllable object, a control unit and a display platform, wherein the display platform provides a plurality of scan codes presented in an eye-catching manner. The control unit provides a user interface and is adapted to remotely control the controllable object as it hovers over the display platform. The controllable object may provide a scanner for reading the plurality of scan codes. Each scan code may provide a market association with a good and/or service. Each market association scanned by the scanner is represented on the user interface, whereby the user of the control unit can view and approve of or disapprove of it, while the user controls the controllable object hovering over the display platform.

Horizontal control of a toy flying vehicle intended for indoor hovering flight comprises providing the vehicle having a rotor and a separate remote controller for use by a player of the toy. The vehicle is airborne relative to the controller. A signal is sent from a transmitter with the toy to the controller. A variation in intensity of the received signal from the toy being effected in a horizontal plane of the controller. The controller is programmed to transmit a responsive signal to the toy according to the variation of intensity of signal received and thereby to cause the toy with the transmitter in the toy to move horizontally and to thereby retain the received signal in the horizontal direction of the controller at a first predetermined level.

A mobile device includes a body, at least one drive wheel coupled with the body, a control structure configured to automatically control rotational movements of the at least one drive wheel so as to selectively control movement of the body, and a motion detection system coupled with the control structure and configured to detect a plurality of different movements of a user. The control structure controls rotational movements of the at least one drive wheel to effect different movements of the body based upon different detected movements of the user.

A mobile device includes a body, at least one drive wheel coupled with the body, a control structure configured to automatically control rotational movements of the at least one drive wheel so as to selectively control movement of the body, and a motion detection system coupled with the control structure and configured to detect a plurality of different movements of a user. The control structure controls rotational movements of the at least one drive wheel to effect different movements of the body based upon different detected movements of the user.

A shock absorber spring retention structure is provided for a remote control car. A spring is arranged between a shock absorption cylinder and a piston rod that are axially movable relative to each other to produce an effect of damping. The spring has a top supported on an adjustment ring that is threadingly screwed to an outer circumference of the shock absorption cylinder and a bottom having a wire rotatably coupled to a clip and held in position by a mounting seat to be coupled to a connection seat mounted to an end of the piston rod. The connection seat includes an engagement section with which the clip is engageable for locking. Thus, in the assembly of the shock absorber, the clip securely retains and couples the spring, the mounting seat, and the connection seat together to prevent the spring from detaching during the operation of the shock absorber.

A handle structure comprises a left body including a left docking portion, a right body including a right docking portion configured to be docked with the left docking portion, and a connecting mechanism connecting the left docking portion and the right docking portion and configured to allow the left docking portion and the right docking portion to slide relatively to adjust an interval between an end of the left body and an end of the right body that are distal from each other.

A shock absorber spring retention structure is provided for a remote control car. A spring is arranged between a shock absorption cylinder and a piston rod that are axially movable relative to each other to produce an effect of damping. The spring has a top supported on an adjustment ring that is threadingly screwed to an outer circumference of the shock absorption cylinder and a bottom having a wire rotatably coupled to a clip and held in position by a mounting seat to be coupled to a connection seat mounted to an end of the piston rod. The connection seat includes an engagement section with which the clip is engageable for locking. Thus, in the assembly of the shock absorber, the clip securely retains and couples the spring, the mounting seat, and the connection seat together to prevent the spring from detaching during the operation of the shock absorber.