A balloon valve and pouch assembly 1 is mounted in a neck portion of a balloon and comprises a balloon valve 2 and a pouch 3. The pouch 3 is adapted to receive and retain an illumination device 100 in a predetermined position. The valve 2 has a valve inlet 2A and a valve outlet 2B provided at an opposite end of the valve 2. The valve 2 is delimited by sealing path 4 and layers 2C, 2D. The pouch 3 comprises an opening 3A through which an illumination device 100 can be inserted and a closed opposite end of the pouch 3B. The pouch 3 is delimited by the first sealing path 5 and layers 3C, 3D. The layers 3C, 3D are heat-sealed together along a first sealing path 5, which is substantially V-shaped, with the open end of the V-shape defining the pouch opening 3A and the closed end of the V-shape defining the closed end of the pouch 3B.

A balloon valve and pouch assembly 1 is mounted in a neck portion of a balloon and comprises a balloon valve 2 and a pouch 3. The pouch 3 is adapted to receive and retain an illumination device 100 in a predetermined position. The valve 2 has a valve inlet 2A and a valve outlet 2B provided at an opposite end of the valve 2. The valve 2 is delimited by sealing path 4 and layers 2C, 2D. The pouch 3 comprises an opening 3A through which an illumination device 100 can be inserted and a closed opposite end of the pouch 3B. The pouch 3 is delimited by the first sealing path 5 and layers 3C, 3D. The layers 3C, 3D are heat-sealed together along a first sealing path 5, which is substantially V-shaped, with the open end of the V-shape defining the pouch opening 3A and the closed end of the V-shape defining the closed end of the pouch 3B.

A rotating sprinkler head, comprising: a base, both ends of which are formed with a mounting cavity and a water inlet nozzle that are coaxially arranged and interconnected; a support seat, which is installed within the mounting cavity and forms an interference fit with the mounting cavity, a linkage hole being provided on the support seat along an axial direction; and a rotating sprinkler head, which comprises a linkage pipe, a seal assembly sleeved on one end of the linkage pipe, and four outward radiating water sprinkling pipes that are located on the other end of the linkage pipe to be integrally formed with same, one end of the linkage pipe installed with the sealing assembly being sleeved within the linkage hole. Such structure is convenient to mount and disassemble, and high in the stability of rotating water sprinkling.

A remote controlled lighter-than-air drone assembly that is capable of prolonged flight. The drone assembly utilizes a balloon structure. Separately, a reservoir is provided for holding a smaller second volume of gas. A propulsion system and a control unit are carried by the balloon structure. The control unit selectively transfers the gas from the reservoir to the balloon structure, and selectively vents the gas as needed. A receiver is used to receive command signals from an external source. The command signals are utilized to operate the propulsion system. An electronics suite is provided that can be altered depending upon duties. The electronics suite is used to scan or otherwise monitor an area below the drone assembly. In flight, the balloon structure is translucent and internally illuminated. A projector can be provided for projecting images onto the interior of the balloon structure.

The present invention provides a balloon containment device comprising a central portion having a diameter larger than the diameter of the narrowest part of an expanded opening portion of a balloon. An elongate external retainer extends from the central portion toward a proximate end to the balloon opening portion and having a length enabled for placement of the central portion, extending through a neck portion of the balloon opening portion. An elongate internal retainer extends from the central portion, and toward a distal end from the balloon opening portion, and having a length designed for placement inside of the balloon. Wherein when the balloon is inflated, the central portion is held against the neck portion by manipulation of the external retainer.

The present invention provides a balloon containment device comprising a central portion having a diameter larger than the diameter of the narrowest part of an expanded opening portion of a balloon. An elongate external retainer extends from the central portion toward a proximate end to the balloon opening portion and having a length enabled for placement of the central portion, extending through a neck portion of the balloon opening portion. An elongate internal retainer extends from the central portion, and toward a distal end from the balloon opening portion, and having a length designed for placement inside of the balloon. Wherein when the balloon is inflated, the central portion is held against the neck portion by manipulation of the external retainer.

A system for recycling helium comprising a bursting chamber with a re-sealable lid and a vent; a bursting mechanism disposed inside the bursting chamber; wherein the bursting chamber is in fluid communication with a compressor; wherein an output of the compressor is in fluid communication with an evacuation valve and a control valve; wherein when the evacuation valve is opened and the control valve is closed the compressor evacuates the air from the bursting chamber; and wherein when the evacuation valve is closed and the control valve is opened, and the bursting mechanism is activated, compressed helium gas recovered from balloons burst in the bursting chamber flows through the control valve into a helium storage tank.

A system for recycling helium comprising a bursting chamber with a re-sealable lid and a vent; a bursting mechanism disposed inside the bursting chamber; wherein the bursting chamber is in fluid communication with a compressor; wherein an output of the compressor is in fluid communication with an evacuation valve and a control valve; wherein when the evacuation valve is opened and the control valve is closed the compressor evacuates the air from the bursting chamber; and wherein when the evacuation valve is closed and the control valve is opened, and the bursting mechanism is activated, compressed helium gas recovered from balloons burst in the bursting chamber flows through the control valve into a helium storage tank.

Filling a balloon with a volume of material, the balloon having an adhesive staging segment formed about a peripheral surface of the moldable adhesive cross sectioned profile of the moldable adhesive ring. Retaining the volume of material within an expansion cavity of the balloon by applying a tensile force in a longitudinal direction between ends of the tubular balloon neck segment to expose the moldable adhesive ring from the adhesive staging segment and compressing the exposed moldable adhesive ring to form a seal. The material can be a gas, air, Helium, etc. A tether can be inserted into the balloon neck prior to filling and sealing, where the sealing step secures the tether to the balloon.

Filling a balloon with a volume of material, the balloon having an adhesive staging segment formed about a peripheral surface of the moldable adhesive cross sectioned profile of the moldable adhesive ring. Retaining the volume of material within an expansion cavity of the balloon by applying a tensile force in a longitudinal direction between ends of the tubular balloon neck segment to expose the moldable adhesive ring from the adhesive staging segment and compressing the exposed moldable adhesive ring to form a seal. The material can be a gas, air, Helium, etc. A tether can be inserted into the balloon neck prior to filling and sealing, where the sealing step secures the tether to the balloon.