A modular robot system includes N (N is an integer that is 2 or greater) cube-type unit robots, each of the N cube-type unit robots comprising: a housing in the shape of a regular hexahedron; a step motor installed in the housing; and a controller installed in the housing and for controlling the step motor. The housing has, on one surface thereof, a mounting groove in which a rotary body rotating by means of a rotating shaft of the step motor can be mounted, and, on the other surface of the housing, a connection groove in the same shape, so that by means of a connector to be mounted in the connection groove, connection to another cube-type unit robot is possible, and the housing has identification marks with different shapes from one another on the respective surfaces thereof.

A modular robot system includes N (N is an integer that is 2 or greater) cube-type unit robots, each of the N cube-type unit robots comprising: a housing in the shape of a regular hexahedron; a step motor installed in the housing; and a controller installed in the housing and for controlling the step motor. The housing has, on one surface thereof, a mounting groove in which a rotary body rotating by means of a rotating shaft of the step motor can be mounted, and, on the other surface of the housing, a connection groove in the same shape, so that by means of a connector to be mounted in the connection groove, connection to another cube-type unit robot is possible, and the housing has identification marks with different shapes from one another on the respective surfaces thereof.

An electric toy vehicle according to the present disclosure comprises an illuminated handlebar including a hollow tube having a first end and a second end. The illuminated handlebar also includes a light disposed within the hollow tube and between the first end and the second end of the tube and a switch electrically coupled to the light and disposed at one of the first end and the second end of the hollow tube. The toy vehicle further includes a motor electrically coupled to the switch and a battery electrically coupled to the motor, the light and the switch. The light is visible within the hollow tube when the switch is activated and the motor powers the electric toy vehicle.

An electric toy vehicle according to the present disclosure comprises an illuminated handlebar including a hollow tube having a first end and a second end. The illuminated handlebar also includes a light disposed within the hollow tube and between the first end and the second end of the tube and a switch electrically coupled to the light and disposed at one of the first end and the second end of the hollow tube. The toy vehicle further includes a motor electrically coupled to the switch and a battery electrically coupled to the motor, the light and the switch. The light is visible within the hollow tube when the switch is activated and the motor powers the electric toy vehicle.

A remote control vehicle comprises light fixtures, which when operated at high speeds, can create a neon glow in its wake. The remote control vehicle has at least eight distinct color combinations, can spin and flip in three hundred sixty degree stunts, and travel through all terrains. A remote control is responsible for remotely communicating aspects related to the control of the remote control vehicle, such as speed and drifting.

A magnetic conductive car model includes a frame, a wheel positioned below the frame, a shell magnetically connected with the frame, a power supply arranged on the frame and a power consumption component positioned on the shell, when the frame is magnetically connected with the shell, the power supply is electrically connected with the power consumption component. The present disclosure can not only quickly and conveniently separate and assemble the shell and the frame, but also quickly and conveniently connect or disconnect a circuit between the shell and the frame, which is very convenient for maintenance and installation and improves use experiences of users.

A magnetic conductive car model includes a frame, a wheel positioned below the frame, a shell magnetically connected with the frame, a power supply arranged on the frame and a power consumption component positioned on the shell, when the frame is magnetically connected with the shell, the power supply is electrically connected with the power consumption component. The present disclosure can not only quickly and conveniently separate and assemble the shell and the frame, but also quickly and conveniently connect or disconnect a circuit between the shell and the frame, which is very convenient for maintenance and installation and improves use experiences of users.

A method and system for activating and cancelling a first or second turn signal indicator for an R/C vehicle are provided. The method may include determining that the R/C vehicle is stationary and reading a rotation of a steering input to a stationary activation threshold. In addition, the method may include activating the turn signal indicator on a side of the R/C vehicle and setting an active turn signal indicator to on. Further actions in the method may involve determining that the R/C vehicle is in motion and reading a rotation of the steering input to a moving initiation threshold. Still further actions may include reading a rotation of the steering input in another direction to a moving cancellation threshold and deactivating the first or second turn signal indicator and setting the active turn signal indicator to off.

A method and system for activating and cancelling a first or second turn signal indicator for an R/C vehicle are provided. The method may include determining that the R/C vehicle is stationary and reading a rotation of a steering input to a stationary activation threshold. In addition, the method may include activating the turn signal indicator on a side of the R/C vehicle and setting an active turn signal indicator to on. Further actions in the method may involve determining that the R/C vehicle is in motion and reading a rotation of the steering input to a moving initiation threshold. Still further actions may include reading a rotation of the steering input in another direction to a moving cancellation threshold and deactivating the first or second turn signal indicator and setting the active turn signal indicator to off.

The self-propelled toy includes a vehicle body, wheels connected to the vehicle body, a battery provided at the vehicle body, a motor using electric power stored in the battery to output drive power for running use, an imaging device connected to the vehicle body so as to capture an image of an area in front of the self-propelled toy, an operating part operated by a user so as to make the imaging device operate, and a charging port supplying electric power from an outside power source to the battery. The operating part is provided at a top part of the vehicle body at one side from a centerline of vehicle width of the self-propelled toy, and the charging port is provided at a side part of the vehicle body at the same side as the operating part from the centerline of vehicle width.