In one embodiment there is a toy vehicle having a motor configured to cause a motion of an element of the toy. The motion of the element further accessible for manipulation by a human to in turn rotate the motor. The toy vehicle further having a processor configured to detect a back electromotive force (EMF) voltage generated by the rotation of the motor due to the manipulation by a human, and the processor being further configured to include at least a sleep state and a wake state. The processor have a function configured to transition between the sleep state and the wake state when the detected back EMF voltage reaches a pre-determined value.

In one embodiment there is a toy vehicle having a motor configured to cause a motion of an element of the toy. The motion of the element further accessible for manipulation by a human to in turn rotate the motor. The toy vehicle further having a processor configured to detect a back electromotive force (EMF) voltage generated by the rotation of the motor due to the manipulation by a human, and the processor being further configured to include at least a sleep state and a wake state. The processor have a function configured to transition between the sleep state and the wake state when the detected back EMF voltage reaches a pre-determined value.

An apparatus for achieving magnetically harnessed locomotion may include (1) a housing that at least partially houses a wheeled machine, (2) a plurality of wheels attached to a plurality of independently rotatable axles that are oriented substantially opposite one another along a plane of the wheeled machine, (3) a plurality of motors having shafts oriented substantially perpendicular to the independently rotatable axles, (4) at least one magnet positioned between the independently rotatable axles within the housing such that a magnetic force of the magnet (A) pulls the independently rotatable axles toward an inward point of the wheeled machine and (B) causes the wheels attached to the independently rotatable axles to press against the shafts of the motors. Various other apparatuses, systems, and methods are also disclosed.

A power unit for a toy or a system of toys that can removable receive the power unit. The power unit comprises a drive gear that can provide rotational power to one or more driven components of a toy with which the power unit is associated. The drive gear can comprise multiple drive portions. The toys can comprise a wide variety of toy types.

[Problem to be Solved] To provide an electrically-operated toy that uses an electric double-layer capacitor as a main power source and yet can secure an operation duration time per charge that is long enough to fully satisfy the users who are infants, younger school children, etc. [Solution] Provided is an electrically-operated toy that includes: an electric double-layer capacitor acting as a main power source; a movable mechanism for realizing toy functions; an electric motive power source for operating the movable mechanism; and a chopper-type step-up DC/DC converter that boosts a voltage received from the electric double-layer capacitor and supplies the voltage as a power source to at least the electric motive power source.

[Problem to be Solved] To provide an electrically-operated toy that uses an electric double-layer capacitor as a main power source and yet can secure an operation duration time per charge that is long enough to fully satisfy the users who are infants, younger school children, etc. [Solution] Provided is an electrically-operated toy that includes: an electric double-layer capacitor acting as a main power source; a movable mechanism for realizing toy functions; an electric motive power source for operating the movable mechanism; and a chopper-type step-up DC/DC converter that boosts a voltage received from the electric double-layer capacitor and supplies the voltage as a power source to at least the electric motive power source.

An illustrative toy vehicle is provided having a two-section chassis and a pivot mechanism rotatably attaching the two sections. The vehicle has the ability to move in multiple orientations and execute movements including a side rollover movement where the pivot mechanism assists in directing the vehicle to roll over from a first orientation to a second orientation about a central axis. A modified wheel design further assists in facilitating movements including the rollover movement. The vehicle may perform movements without user control where the vehicle responds to external factors, such as objects or terrain or the vehicle may use control systems such as radio or remote control with a transmitter/receiver pair, on vehicle switches or sensors utilizing interactive preprogrammed content.

The present invention discloses a servo of an entertainment robot that includes a servo main body and a servo plate. The servo main body includes a casing and an output shaft. The casing is a hexahedron. The servo plate is fixed to the output shaft of the servo main body. The servo plate includes a square drive plate. At least one surface of the servo main body includes a T slot having an opening at one end. The size of the T slot matches the size of the drive plate of the servo plate. Tools are not needed for assembling/disassembling during the assembling of entertainment robots, thereby reducing the complexity during assembling, lowering the assembly difficulty, simplifying the assembling process, increasing the joy of DIY, and providing more space for the users to bring into play their imaginations.

The present invention discloses a servo of an entertainment robot that includes a servo main body and a servo plate. The servo main body includes a casing and an output shaft. The casing is a hexahedron. The servo plate is fixed to the output shaft of the servo main body. The servo plate includes a square drive plate. At least one surface of the servo main body includes a T slot having an opening at one end. The size of the T slot matches the size of the drive plate of the servo plate. Tools are not needed for assembling/disassembling during the assembling of entertainment robots, thereby reducing the complexity during assembling, lowering the assembly difficulty, simplifying the assembling process, increasing the joy of DIY, and providing more space for the users to bring into play their imaginations.

A self-propelled toy glider includes a flexible frame and a flight surface. The flexible frame may deformed and held within the user's hand. When deformed, the flexible frame stores spring energy. This spring energy is subsequently used to propel the self-propelled toy glider forward as it returns to original shape. Related to glider durability and overall safety, the flexible frame can elastically deform when the toy glider impacts objects during flight.