The invention relates to the utilization of magnetism in the roll stabilization and suspension of a radio-controlled car. In small radio-controlled vehicles, in particular, it is difficult to implement the conventional mechanical roll stabilization and a well-functioning suspension due to the small size, the accuracy required, dirt, and the loads exerted on the structures. In the structure according to the invention, the roll stabilization and suspension are implemented by means of magnetism, according to FIG. 2. The magnets at the ends of supporting arms (6) attract each other, implementing the roll stabilization. Magnets (3) are installed under the supporting arm magnets, repelling them and providing suspension.

A light-emitting toy assembly including a field generator that includes a first transmitting coil configured to inductively transmit energy and an object. The object includes a body, at least a part of which is translucent, at least one receiving coil configured to inductively receive energy from the first transmitting coil, and a lighting element having at least one light emitting diode that is configured to receive a current from a corresponding one of the at least one receiving coils. At least one of the first transmitting coil and the object is movable with respect to the other of the first transmitting coil and the object. A change in a rotational orientation of at least one of the first transmitting coil and the object alters a lighting state of the lighting element.

A light-emitting toy assembly including a field generator that includes a first transmitting coil configured to inductively transmit energy and an object. The object includes a body, at least a part of which is translucent, at least one receiving coil configured to inductively receive energy from the first transmitting coil, and a lighting element having at least one light emitting diode that is configured to receive a current from a corresponding one of the at least one receiving coils. At least one of the first transmitting coil and the object is movable with respect to the other of the first transmitting coil and the object. A change in a rotational orientation of at least one of the first transmitting coil and the object alters a lighting state of the lighting element.

A combined type toy top separated through induction control, includes a main top, an auxiliary top and an elastic part. When the combined type toy top is in a first state, the main top is limited and fixed by the auxiliary top, above the auxiliary top, and meanwhile the main top compresses the elastic part so that the elastic part is compressed. The combined type toy top is characterized in that a sensing mechanism is arranged in the auxiliary top. The sensing mechanism can controllably relieve limiting fixation of the main top from the auxiliary top under a second state through induction control. The main top pops up under an elasticity action of the elastic part, and, accordingly, the main top and the auxiliary top rotate independently.

A combined type toy top separated through induction control, includes a main top, an auxiliary top and an elastic part. When the combined type toy top is in a first state, the main top is limited and fixed by the auxiliary top, above the auxiliary top, and meanwhile the main top compresses the elastic part so that the elastic part is compressed. The combined type toy top is characterized in that a sensing mechanism is arranged in the auxiliary top. The sensing mechanism can controllably relieve limiting fixation of the main top from the auxiliary top under a second state through induction control. The main top pops up under an elasticity action of the elastic part, and, accordingly, the main top and the auxiliary top rotate independently.

A magnetic spinning toy comprising: a top magnetic assembly; a bottom magnetic assembly; a rod, wherein said rod extends between the top magnetic assembly and bottom magnetic assembly; a plurality of rotating wings mounted on the rod between the top magnetic assembly and bottom magnetic assembly; and a mounting arm, wherein the mounting arm receives top magnetic assembly, the plurality of rotating wings and bottom magnetic assembly. The top and bottom magnetic assemblies preferably also include a copper tube with embedded magnets, wherein the embedded magnets include a donut magnet at one end of the copper tube and additional magnets at the mid point and opposite end of the copper tube.

A magnetic spinning toy comprising: a top magnetic assembly; a bottom magnetic assembly; a rod, wherein said rod extends between the top magnetic assembly and bottom magnetic assembly; a plurality of rotating wings mounted on the rod between the top magnetic assembly and bottom magnetic assembly; and a mounting arm, wherein the mounting arm receives top magnetic assembly, the plurality of rotating wings and bottom magnetic assembly. The top and bottom magnetic assemblies preferably also include a copper tube with embedded magnets, wherein the embedded magnets include a donut magnet at one end of the copper tube and additional magnets at the mid point and opposite end of the copper tube.

The present invention relates to a magnetic assembly for creating three-dimensional structures, said magnetic assembly comprising at least one ferromagnetic element (1), at least one magnetic element (2), magnetically couplable to said at least one ferromagnetic element (1), and at least one support panel (3) having a perimeter edge (10). Said magnetic assembly being characterised in that it further comprises at least one connection element (4), said at least one connection element (4) comprising a seat (6) for removably housing and retaining a ferromagnetic element (1) or a magnetic element, and at least one peripheral portion (9) suitable for being removably coupled to at least one portion of the perimeter edge (10) of said support panel (3), becoming locked thereto.

A multi-body self-propelled device can include a drive body and a coupled head. The drive body can include a spherical housing, an internal drive system within the spherical housing to propel the multi-body self-propelled device, and a magnet holder coupled to the internal drive system to hold a first set of magnetic elements. The drive body can further include a first power source within the spherical housing to power the internal drive system and a first inductive interface. The coupled head can include second set of magnetic elements to establish a magnetic interaction with the first set of magnetic elements through the spherical housing. The coupled head can also include a second power source, and a second inductive interface. The multi-body self-propelled device can transfer power between the coupled head and the drive body via the first and the second inductive interfaces.

A spherical construction toy includes six segments consisting of a single outer convex surface and four inner concave surfaces, twelve segments consisting of a single outer convex surface, two inner convex surfaces, and two inner concave surfaces; and eight segments consisting of a single, outer convex surface and three inner convex surfaces. The segments are defined by the intersection of spherical surfaces having identical radius and disposed along Cartesian coordinate axes with the surface at the common center. The segments, when assembled in a base configuration with the outer surfaces disposed away from the common center, form a spherical assembly.