A toy vehicle booster is presented herein. The toy vehicle booster includes a booster assembly that is integrated into a lid of a track storage container so that the toy vehicle booster forms a portion of a storage container for a track set. In some instances, the booster assembly includes a first booster and a second booster. The first booster may accelerate toy vehicles along a first pathway and the second booster may accelerate toy vehicles along a second pathway. In at least some of these embodiments, at least the second booster may be reversible so that the second booster can accelerate toy vehicles along the second pathway in a first direction or a second direction opposite the first direction.

A toy vehicle booster is presented herein. The toy vehicle booster includes a booster assembly with linked booster wheels positioned on opposite sides of a track section. The booster's track section includes a central wall that defines two pathways between the linked booster wheels. Consequently, either one of the linked booster wheels can compress a first toy vehicle of a first size that is traveling within one of the two pathways against the central wall to accelerate the first toy vehicle through the track portion. Additionally or alternatively, the linked booster wheels can engage both sides of a second toy vehicle of a second size that is traveling along both of the two pathways to accelerate the second toy vehicle.

An improved toy vehicle playset contains a tower and multiple track portions coupled to the tower that provide a path for toy vehicles to descend from the top of the tower. The tower may include an elevator mechanism for transporting toy vehicles up the tower and an interactive feature that is configured to interact with descending toy vehicles along the track portions. The descent of the toy vehicles may trigger the interactive feature to also descend from the top of the tower, where the descending interactive feature may attempt to impede or stop the descending toy vehicles along the track portions. In some embodiments, the one or more towers may further include platforms configured to store and retain a plurality of toy vehicles, mechanisms that trigger one or more toy vehicles to be launched from the platforms, and mechanisms for diverting toy vehicles onto the platforms.

A stackable track assembly and method for stacking a booster and/or track frame is disclosed. The stackable track assembly includes a base, a track portion disposed in the base, and a frame extending out of the base and laterally across the top of the base. The stackable track assembly further includes a tab and slot for laterally coupling two track assemblies. The stackable track assembly further includes a receiving member and engagement member for vertically and/or laterally coupling two track assemblies. In some implementations, the track assembly may include a booster for accelerating a toy vehicle.

A circuit arrangement for a model car racing track, having at least two tracks for model cars, wherein a positive busbar and a negative busbar are in each case assigned to each track, and a first driving speed controller is connected between a positive supply terminal and the positive busbar of the first track and a second driving speed controller is connected between a negative supply terminal and the negative busbar of the second track.

This utility model discloses a building block and track building block toy including four of single components and eight of magnetic spheres; each one of single components comprises a first connecting rod, a second connecting rod and a third connecting rod; the first connecting rod, the second connecting rod, and the third connecting rod are sequentially connected to form a “” shape; a first insertion portion is disposed on an end of the first connecting rod, and another one of first insertion portion is disposed on an end of the third connecting rod; second insertion portions extend vertically at both ends of the second connecting rod; each of the second insertion portions is provided with one of inserting holes. A plurality of the building blocks are able to be adsorbed together by magnetic spheres and assembled into various shapes.

A test track assembly comprising a test track, the test track comprises a support structure and at least one track portion, adapted for testing a spatial structure; the test track assembly comprises at least two different interchangeable track sections, each of the at least two interchangeable track sections comprises an action track portion, each of the action track portions comprise a different geometrical track path, the action track portions adapted to provide geometric challenges to a user who tests a spatial structure on the test track, the support structure comprises a void adapted to accommodate one of the at least two interchangeable track sections in position such that the action track portion is arranged adjacently in continuation to the at least one track portion, the track portions comprises a starting point and a ending point, which are positioned opposed each end of the test track, wherein the test track assembly comprises a toy construction system, the toy construction system comprises several toy construction elements, the toy building elements comprise one or more coupling organs adapted to be interconnected to form a spatial structure, said spatial structure adapted to be tested on said test track.

A toy vehicle launcher comprising a housing, a guide track connected to the housing, and a slidable member movably engaged with the guide track. The housing includes a lever mechanism, wherein actuation of the lever mechanism causes the slidable member to move along the length of the guide track in a forward direction. A plurality of projections are pivotally mounted to the slidable member and protrude upwardly from the guide track. The plurality of projections are configured to allow a toy vehicle to pass over the one or more projections only when the toy vehicle travels along the guide track in the forward direction.

A toy vehicle booster includes a launcher that can be actuated via repeated user actuations of an actuator. The force of each actuation is mechanically transferred to a booster assembly to cause rotation of the booster assembly and repeated actuations of the actuator continuously increase the rotational speed of the booster assembly. The toy vehicle booster also includes a feedback portion configured to provide feedback based on a rotational speed of the booster assembly and/or a speed at which the booster assembly will boost a toy vehicle. In at least some instances, the feedback is based on the detected rotational speed of booster wheels. The detected rotational speed may also be transmitted to an electronic device to provide additional feedback at the electronic device.

A toy vehicle track system of the present application includes electrical connections between the track pieces that allow a central hub, referred to herein as a portal piece, to communicate with any track pieces included in the track system. In order to ensure that the portal piece can quickly and accurately identify track configurations that are built, the toy vehicle track system implements a communications protocol that supports communications between any two pieces of track. Based on these communications, the portal piece can determine an orientation, a track type, and a position of any track pieces attached, whether directly or indirectly, to the portal piece. The portal piece can then transmit this information to an electronic device executing an application associated with the track system to allow for digital play on a digital version of the track configuration (among other digital play modes).