The present disclosure relates to a toy that provides attachable wheeled base for a mobile device to turn the mobile device into a wheeled toy. In one embodiment, the disclosed toy comprises a four linkages with each linkage connecting a wheel, a first alignment telescoping rod connecting the first linkage and the third linkage, a second alignment telescoping rod connecting the second linkage and the fourth linkage, a first flat bar that connects the first linkage and the fourth linkage, and a second flat bar that connects the second linkage and the third linkage. The flat bars form a scissor structure so that when it expands, the alignment telescoping rods will retract causing distance between first and second linkage and distance between third and fourth linkage to increase, and distance between first and third linkage and distance between second and fourth linkage to decrease.

The disclosure relates to the technical field of toy vehicles, in particular to a pull back vehicle capable of switching travelling lines including a pull back vehicle chassis. The pull back vehicle chassis includes a driving gear box, driving wheel, a driving gear, a steering wheel shaft, steering wheels and a centering spring. The pull back vehicle chassis is fixedly installed with the driving gear box, the driving gear box is fixedly connected with a driving axle, the driving axle is fixedly connected with the driving gear, and the driving axle is fixedly connected with the driving wheel, and the pull back vehicle chassis is fixedly connected with the steering wheel shaft.

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.

A suspension shock absorber for remote control (RC) cars includes an inner tube and an outer tube coaxial with each other. The hollow area inside the inner tube defines a hollow chamber where a piston and a piston rod slidably moves. A shock cap seals the top of the inner tube and the outer tube. The space between the coaxial inner tube and outer tube is used as an inter-tube bypass route through which bypass oil flows. The shock cap has a bypass passage connecting the inter-tube bypass route with the upper portion of the hollow chamber. A bypass valve in line with the co-axis of the inner tube and the outer tube is disposed on top of the shock cap and used to regulate the amount of oil flow through the bypass passage.

The present invention provides for a protective enclosure comprising a base comprising a first continuous mating surface and at least one conveyance aperture, a cover comprising a second continuous mating surface, wherein the second continuous mating surface is configured to form a seal with the first continuous mating surface, and a clamp, wherein at least a portion of the clamp is coupleable to the base, wherein a mouth of the clamp is configured to be offset from the aperture when the clamp is coupled to the base, wherein the clamp comprises a first sealing layer, and wherein the clamp is configured to seal the aperture against contaminants. The protective enclosure may be configured for use in a remotely controllable model vehicle to protect a control module.

A toy vehicle configured for running on rails, the toy vehicle comprises a chassis comprising a first end and a second end, two side faces extending in the longitudinal direction of the toy vehicle and a top portion, the toy vehicle comprising at least two axles, said at least two axles comprising a wheel wherein the chassis comprises oblong recesses positioned on the inner surface of the chassis, the oblong recesses adapted to obtain a protrusion of a wheel or an end portion of the at least two axles, the chassis comprising two or more axle support arms adapted to support the at least two axles, the two or more axle support arms being adapted to avoid disengagement between an oblong recess and the protrusion of a wheel or an end portion of the at least two axles, respectively.

In one aspect, there is provided a toy vehicle that includes a vehicle body, at least one motor and a plurality of wheels. The at least one motor is mounted to the vehicle body, and is sized to have a selected amount of torque. The plurality of wheels includes at least one driven wheel which includes at least one flip-over wheel which has an axis closer to one end of the vehicle than the other end. In an upright orientation the vehicle body extends above the plurality of wheels. The toy vehicle has a centre of gravity that is positioned, such that, application of torque from the at least one motor causes the vehicle body to drive rotation of the vehicle body about the axis of rotation from an inverted orientation over to the upright orientation.

An eccentric omnidirectional wheel, having a fixed wheel frame having a hollow center, a driving ring, a driving mechanism and at least one slanted rollable barrel evenly distributed around an outer perimeter of the driving ring; the driving ring sleeves onto an outer perimeter of the fixed wheel frame and is rotatably connected with the fixed wheel frame; an eccentric shaft seat is mounted at an inner perimeter of the fixed wheel frame; the driving mechanism is connected with the driving ring to achieve motion transmission.

A building block assembly (50) comprises a first module (50A) and a second module (50B) which are in detachable engagement, wherein the first module (50A) and the second module (50B) are mechanically connected and relatively rotatable about a rotation axis. The first module (50A) is a building block module comprising a first building block and a second building block which are snap fastened or press fastened to form a building block stack. The second module (50B) is mechanically retained by the first module (50A) in a retention state upon snap fastening of the first building block and the second building block in a connection direction defined by a connection axis which is coaxial with the rotation axis to form the building block stack.

The purpose of the present invention is to provide a driving toy and a playing device using same, the driving toy being provided with auxiliary wheels for guiding the driving toy to travel along a track, and capable of travelling on various tracks by allowing the auxiliary wheels to be installed by changing the positions thereof according to the type of tracks.