The present disclosure provides a drift toy car including a power assembly, a steering assembly, a control assembly, a driving wheel, a driven assembly, and a housing. The power assembly, the control assembly, and the driven assembly are all mounted in the housing, the power assembly is connected to the driving wheel to provide power to the toy car, a connecting plate of the steering assembly is connected to a driven wheel device of the driven assembly, and the connecting plate is controlled by the steering assembly for turning a preset angle; the control assembly is configured to receive control instructions and control the steering assembly, making the driven wheel device perform steering; once the movement direction of the driven wheel device deviates from the movement direction of the driving wheel, the toy car performs steering and drift.

The present disclosure provides a drift toy car including a power assembly, a steering assembly, a control assembly, a driving wheel, a driven assembly, and a housing. The power assembly, the control assembly, and the driven assembly are all mounted in the housing, the power assembly is connected to the driving wheel to provide power to the toy car, a connecting plate of the steering assembly is connected to a driven wheel device of the driven assembly, and the connecting plate is controlled by the steering assembly for turning a preset angle; the control assembly is configured to receive control instructions and control the steering assembly, making the driven wheel device perform steering; once the movement direction of the driven wheel device deviates from the movement direction of the driving wheel, the toy car performs steering and drift.

A throwing or catching toy includes a generally elongated spheroidal body defined as having a longitudinal axis, where a length of the body along the longitudinal axis between a front end to a back end of the body is longer than an equatorial diameter. A support is attached to the body and extends beyond the back end of the body and does not extend beyond the front end of the body. A lift-generating wing is non-movably attached to the support. A push surface is disposed near the back end of the body, where the push surface is generally perpendicular to the longitudinal axis. A horizontal stabilizer is attached to the support and disposed behind the lift-generating wing. An impact transfer surface is attached directly to the support, where the impact transfer surface is disposed within the body and fixed between the front end of the body and the support.

The present invention is a toy projectile and launcher system. The lightweight projectile has an exterior surface symmetrically disposed about an imaginary longitudinal axis. The launcher has planar leaves or holding pins, for receiving and holding the projectile. Within the launcher is a spring-loaded element that moves between cocked and released positions. The spring-loaded element contacts a first planar leaf or a first holding pin as the spring-loaded element moves from cocked to released position. Contact with the spring-loaded element causes the leaves or pins to pinch the projectile and launch the projectile into flight in a direction perpendicular to its longitudinal axis. In an alternate embodiment, rotational and linear velocities are imparted to a projectile by action of a ribbon held against the projectile's exterior surface by parallel members. Contact with the spring-loaded element causes the ribbon to translate along the length of said parallel members and into flight.

The present invention is a toy projectile and launcher system. The lightweight projectile has an exterior surface symmetrically disposed about an imaginary longitudinal axis. The launcher has planar leaves or holding pins, for receiving and holding the projectile. Within the launcher is a spring-loaded element that moves between cocked and released positions. The spring-loaded element contacts a first planar leaf or a first holding pin as the spring-loaded element moves from cocked to released position. Contact with the spring-loaded element causes the leaves or pins to pinch the projectile and launch the projectile into flight in a direction perpendicular to its longitudinal axis. In an alternate embodiment, rotational and linear velocities are imparted to a projectile by action of a ribbon held against the projectile's exterior surface by parallel members. Contact with the spring-loaded element causes the ribbon to translate along the length of said parallel members and into flight.

A walking toy in which if a torso is moved forward walking motion is performed has the torso, two legs. The walking toy includes a crank member having a pair of crank eccentric shafts. Each of the legs has a motion member giving rotational force to the crank member when the torso moves forward. Each of the motion members has an eccentric shaft connecting part pivotably connected to the corresponding crank eccentric shaft, a torso cooperation part, and an action part on which force received from the walking surface act. Projections are formed at the torso cooperation part, while grooves are formed at the torso. If the action part of the one leg moves rearward, the motion member moves to thereby impart rotational force to the crank member and, the other leg is moved forward due to rotation of the crank member, and then contacts the walking surface.

A walking toy in which if a torso is moved forward walking motion is performed has the torso, two legs. The walking toy includes a crank member having a pair of crank eccentric shafts. Each of the legs has a motion member giving rotational force to the crank member when the torso moves forward. Each of the motion members has an eccentric shaft connecting part pivotably connected to the corresponding crank eccentric shaft, a torso cooperation part, and an action part on which force received from the walking surface act. Projections are formed at the torso cooperation part, while grooves are formed at the torso. If the action part of the one leg moves rearward, the motion member moves to thereby impart rotational force to the crank member and, the other leg is moved forward due to rotation of the crank member, and then contacts the walking surface.

A model vehicle with body mount components are provided. A tongue member attached to a model vehicle body with a first and second tongue member is configured to engage a first securing member attached to a model vehicle chassis. A top surface of the second tongue member draws the model vehicle body towards the model vehicle chassis when the second tongue member engages the first securing member. A lever member with a lever handle, jaw clamp, and a lever pivot is configured to pivot between an engage and an unengaged position. The jaw clamp engages with a second securing member in the engaged position. The lever member further contains a retaining mechanism that is configured to rotate between a retained and unretained position. The retaining mechanism inhibits the lever handle from moving from the engaged to the unengaged position when the retaining mechanism is in the retained position.

A model vehicle with body mount components are provided. A tongue member attached to a model vehicle body with a first and second tongue member is configured to engage a first securing member attached to a model vehicle chassis. A top surface of the second tongue member draws the model vehicle body towards the model vehicle chassis when the second tongue member engages the first securing member. A lever member with a lever handle, jaw clamp, and a lever pivot is configured to pivot between an engage and an unengaged position. The jaw clamp engages with a second securing member in the engaged position. The lever member further contains a retaining mechanism that is configured to rotate between a retained and unretained position. The retaining mechanism inhibits the lever handle from moving from the engaged to the unengaged position when the retaining mechanism is in the retained position.

Aspects of the disclosure relate to a conical-shaped articulated member. The conical-shaped articulated member includes a conical-shaped structure including an inner surface and an outer surface. The conical-shaped articulated member further includes a plurality of rotary actuation units disposed along a length of the conical-shaped structure, where at least two rotary actuation units of the plurality of rotary actuation units are coupled together. The plurality of rotary actuation units are configured to perform one or more motions.