A swirl confetti blower is designed to create a conical swirl motion that would cause the confetti to blow down around and up/out the spouts. This blower consists of top that has the confetti loading doors, fan housing and fan blade guard, hanging bracket, the main housing body with the confetti snouts and the octagon vent bottom which is the confetti trough and the bottom air relief portion with the conical diffuser. Diversion of air flow is what helps the confetti to flow not only up and out but also out the bottom relief channel. This Vortex or Swirl is created by using a high velocity blower fan. The blower loads from the snouts or the doors on the top of the unit. This unit can be hung from a truss or positioned on a flat surface. This would be for either manual control or an external DMX unit that would be able to be controlled from a lighting console.

An air driven toy includes at least one connectible section that is removably couplable to an air flow generator to receive the object and defines at least one path for fluid flow through the at least one connectible section, wherein the air flow generator is configured to cause the object to be propelled through the at least one connectible section.

A wall-climbing vehicle having a bottom cover configured along a bottom portion. The bottom cover is disposed along the bottom portion such that a gap between the vertical wall and the bottom portion of the wall-climbing vehicle is formed. An air intake area is configured along a middle portion of the bottom cover to enable symmetrical weight balance. The air intake area is configured to accommodate a circular air intake arrangement that includes a circular configuration to create a large opening along the air intake area to increase an air suction volume along the air intake area. The wall-climbing vehicle includes a plurality of sealing cloths strips configured along sides the bottom portion to form a closed area in the wall-climbing vehicle to be continuously evacuated to form a negative pressure. Moreover, a plurality of bumps and a plurality of dots may be provided for balancing effect.

A rotary displacement structure of a fun device includes a container body. The container body has a space therein. A fluid is provided in the space. A rotary displacement unit is disposed in the space. The rotary displacement unit has buoyancy or gravity. The rotary displacement unit includes at least one blade assembly. When the container body is overturned, the rotary displacement unit will rise or descend through buoyancy or gravity. At the same time, the blade assembly enables the rotary displacement unit to rotate when ascending or descending, so as to obtain a different visual effect from the prior art.

A rotary displacement structure of a fun device includes a container body. The container body has a space therein. A fluid is provided in the space. A rotary displacement unit is disposed in the space. The rotary displacement unit has buoyancy or gravity. The rotary displacement unit includes at least one blade assembly. When the container body is overturned, the rotary displacement unit will rise or descend through buoyancy or gravity. At the same time, the blade assembly enables the rotary displacement unit to rotate when ascending or descending, so as to obtain a different visual effect from the prior art.

The disclosure relates to the technical field of toys, and provides a non-electric toy transmission system, to resolve a prior-art technical problem that an electric toy transmission mechanism has high use costs and a short service life. Technical solutions in the disclosure are as follows: The non-electric toy transmission system includes an instruction apparatus, an execution apparatus, a pipeline, and a transmission medium, where the instruction apparatus and the execution apparatus are connected by the pipeline, and the instruction apparatus, the execution apparatus, and the pipeline are filled with the transmission medium; and the instruction apparatus is capable of being triggered to enable the transmission medium in the instruction apparatus to enter the execution apparatus through the pipeline, and the execution apparatus completes, under pressure of the transmission medium, an action designed for a toy.

The disclosure relates to the technical field of toys, and provides a non-electric toy transmission system, to resolve a prior-art technical problem that an electric toy transmission mechanism has high use costs and a short service life. Technical solutions in the disclosure are as follows: The non-electric toy transmission system includes an instruction apparatus, an execution apparatus, a pipeline, and a transmission medium, where the instruction apparatus and the execution apparatus are connected by the pipeline, and the instruction apparatus, the execution apparatus, and the pipeline are filled with the transmission medium; and the instruction apparatus is capable of being triggered to enable the transmission medium in the instruction apparatus to enter the execution apparatus through the pipeline, and the execution apparatus completes, under pressure of the transmission medium, an action designed for a toy.

A wall-climbing toy vehicle includes a body having a car frame structure and a base member. The car frame structure is coupled to the base member. The base member includes a horizontal part and a vertical part. The horizontal part defines a curved surface negative pressure cavity. The horizontal part includes air inlet ports and shunt grooves. The vertical part includes at least one drive mechanism installation port and a plurality of wheel installation ports. Further an air suction assembly is coupled along the air inlet ports on the horizontal part. Furthermore, at least one drive mechanism assembly is coupled to the at least one drive mechanism installation port on the vertical part. The air suction assembly and the at least one drive mechanism assembly are adapted to be driven via a power supply arrangement to enable the wall-climbing toy vehicle to drive against the vertical wall.

A wall-climbing toy vehicle includes a body having a car frame structure and a base member. The car frame structure is coupled to the base member. The base member includes a horizontal part and a vertical part. The horizontal part defines a curved surface negative pressure cavity. The horizontal part includes air inlet ports and shunt grooves. The vertical part includes at least one drive mechanism installation port and a plurality of wheel installation ports. Further an air suction assembly is coupled along the air inlet ports on the horizontal part. Furthermore, at least one drive mechanism assembly is coupled to the at least one drive mechanism installation port on the vertical part. The air suction assembly and the at least one drive mechanism assembly are adapted to be driven via a power supply arrangement to enable the wall-climbing toy vehicle to drive against the vertical wall.

Many devices with “limbs” or “arms” are susceptible to damage when a user bends or twists a joint of the limb or arm beyond its design point or in a direction other than intended. This is common with children's toys. Accordingly, it would be beneficial to provide children with toys employing fluidic actuators that can be bent, twisted, deformed and yet recover subsequently allowing the intended motion to be performed. Further, it would be beneficial by providing devices that employ fluidic actuators, and hence are essentially non-mechanical, to provide users not only of toys but other devices with driving mechanisms that are not susceptible to wear-out such as, by stripping drive gears, etc., thereby increasing their reliability and reducing noise. Fluidic devices allow for high efficiency, high power to size ratio, low cost, limited or single moving part(s) and allow for mechanical springless designs as well as functional reduction by providing a piston which is both pump and vibrator.