According to the present invention, disclosed is an assembled educational toy using polyomino including: a base plate 110 formed in a plate shape having a predetermined area and horizontally disposed, and having first coupling portions 112 aligned thereon to be in straight columns and rows; a block portion 120 constituted by the polyomino having a shape of a single hexahedron 121 or a shape in which a plurality of hexahedrons 121 are fastened to each other in a lateral direction, having a bottom surface provided with second coupling portions 122 fastened to the first coupling portions 112, and forming a set of blocks having various shapes while being assembled in plural on the base plate 110 by the first coupling portions 112 and the second coupling portions 122; and a guide image portion 130 having a film or plate shape having equal to or relatively smaller area than the base plate 110, seated on the base plate 110, and provided with an image I having a shape of objects including animals to guide each block portion 120 to be assembled on the base plate 110 as the shape of objects.

A crafting system for guiding a user in creating a craft, includes a crafting challenge repository storing a plurality of crafting challenges. The challenges each include instructions for creating a specific craft. A display surface can display the crafting challenges thereon. A controller includes instructions to receive a selection of a selected crafting challenge to be displayed on the display surface, and instructions to prepare a selected challenge for display on the display surface and to provide the prepared challenge to the display surface for display thereon. The controller is accommodated in a housing. At least one at least partially transparent crafting surface, may be removably mounted above the display surface such that when instructions of the prepared challenge are displayed on the display surface, the instructions are visible to the user through the crafting surface.

The present disclosure relates to a module-type robot control system comprising: a robot platform including a driving unit which is driven by a control signal, at least one function block which is assemblable and disassemblable on the robot platform and configured to perform a specific function, and a user terminal capable of wirelessly communicating with the robot platform and the function block According to the system, The user may remotely control the module-type robot through a smart device, or receive related content by receiving data from the robot through the terminal. The user may easily control the robot or receive more diverse customized contents by connection between the smart device and the module-type robot system.

A remote control device (10) configured for controlling one or more remote controllable actuators (50); said remote control device comprising a housing (11), one or more control units (21), one or more electromechanical interfaces (12) and a transmitter (13); said one or more electromechanical interfaces (12) being positioned inside said housing (11); said one or more control units (21) being functionally connected to said one or more electromechanical interfaces (12) which are functionally connected to said transmitter (13); said one or more control units (21) being structurally connected to said one or more control bases (20), said one or more control bases (20) being arranged rotatable about an axis of rotation (rA) relative to the housing (11) of the remote control device (10) wherein that said one or more control units (21) together define at least a first and a second functional position (A,B) relative to the one or more control bases, said first and second functional positions (A,B) being located radially on opposite sides of said axis of rotation (rA) of said one or more control bases (20), said one or more control units being configured, regardless of rotation of said one or more control bases (20), to produce a first control signal when activated at said first functional position (A) and to produce a second control signal when activated at said second functional position (B); said first control signal being configured to cause a first function having a first direction associated with it, and said second control signal being configured to cause a second function having a second direction associated with it, and where said second direction is opposite said first direction.

A magnetic latching mechanism including a servo-motor configured to rotate an axle; a latching rotor attached to the axle and configured to rotate; and a pair of latching permanent magnets attached to the latching rotor. A north pole of a permanent magnet and a south pole of another permanent magnet of the pair are facing along a same direction.

A modular toy construction system, comprising: a plurality of interactive toy construction elements, each interactive toy construction element comprising a sensor and/or a function device, the function device operable to perform a user-perceivable function; each interactive toy construction element further comprising a first communications circuit configured to wirelessly communicate signals and to wirelessly harvest energy for operating the function device and/or the sensor.

An identification (ID) number setting method for a modular device that comprises a master building element and a plurality of slave building elements that are connected to the master building element, includes: disconnecting the slave building elements from the master building element; setting ID numbers of all of the slave building elements to be a preset ID number; and assigning new ID numbers to slave building elements of N tiers that are connected to one output interface of the master building element in an order from first tier to Nth tier, wherein the slave building elements of the first tier are slave building elements that are directly connected to the output interface, the slave building elements of the Nth tier are slave building elements that are indirectly connected to the output interface through slave building elements of a (N−1)th tier, N is a natural number greater than 1.

A Lynchpin structure may be combined with one or more additional Lynchpin structures to form a compound Lynchpin propulsion structure. Each Lynchpin structure may include six pentangular areas, and one or more of the pentangular areas may include a propulsion device. The propulsion may be used to propel the compound Lynchpin propulsion structure through or over various media, such as through air, across ground, on or underwater, or through or over other media. The propulsion may include avionic propulsion, ground propulsion, hydrodynamic propulsion, or other types of propulsion. A single type of propulsion device may be used within one or more of the pentangular areas, or diverse types of propulsion may be used to provide various navigational performance or multi-mode operation. Each propulsion device may also include a device to direct the propulsion, such as a single or multi-axis gimble or adjustable aerodynamic control surface.

An assemblable toy has two bricks, a main base and an illuminating piece. Multiple light connectors are mounted on the main base. A power supply unit is mounted on the main base and electrically connected to the light connectors. An illuminating piece is selectively connected to one of the light connectors, and has a flexible flat cable, a plug, and an illuminating portion. The plug and the illuminating portion are mounted on opposite ends of the flexible flat cable and electrically connected to each other. The plug is electrically connected to the corresponding light connector. The flexible flat cable passes through a clearance between the two bricks without affecting ease of assembly and proper external appearance of the toy. The illuminating piece can be integrated into most of the standard plastic assemblable toys to provide decorative lighting.

Method, modules and a system formed by connecting the modules for controlling payloads are disclosed. An activation signal is propagated in the system from a module to the modules connected to it. Upon receiving an activation signal, the module (after a pre-set or random delay) activates a payload associated with it, and transmits the activation signal (after another pre-set or random delay) to one or more modules connected to it. The system is initiated by a master module including a user activated switch producing the activation signal. The activation signal can be propagated in the system in one direction from the master to the last module, or carried bi-directionally allowing two way propagation, using a module which revert the direction of the activation signal propagation direction. A module may be individually powered by an internal power source such as a battery, or connected to external power source such as AC power. The system may use remote powering wherein few or all of the modules are powered from the same power source connected to the system in a single point. The power may be carried over dedicated wires or concurrently with the conductors carrying the activation signal. The payload may be a visual or an audible signaling device, and can be integrated within a module or external to it. The payload may be powered by a module or using a dedicated power source, and can involve randomness associated with its activation such as the delay, payload control or payload activation.