Systems and methods herein provide for balloon launching. In one embodiment, a Portable Balloon Launch System (PBLS) includes a tank operable to retain water, and a reactor fluidly coupled to the tank and comprising a reductant material that reacts with the water to produce a lift gas. The PBLS also includes a first valve operable to release the water into the reactor, and an exhaust operable to vent the lift gas into a balloon to inflate the balloon. The lift gas is lighter than air so as to lift the balloon into the atmosphere.

A balloon is provided having an exostructure comprised of hollow struts or rods and an envelope positioned over the exostructure, and a pump for pumping air out of the balloon to create an air pressure differential between the pressure inside the envelope and the atmospheric pressure outside the envelope, a control system configured to allow air to flow into the envelope to control the altitude of the balloon, and to operate the pump to pump air out of the envelope to control the altitude of the balloon, wherein the material of the envelope is arranged so as to sag between the struts or rods and form at least one catenary surface when there is an air pressure differential between the pressure inside of the balloon envelope and the atmospheric pressure outside the envelope.

A balloon is provided having an exostructure comprised of hollow struts or rods and an envelope positioned over the exostructure, and a pump for pumping air out of the balloon to create an air pressure differential between the pressure inside the envelope and the atmospheric pressure outside the envelope, a control system configured to allow air to flow into the envelope to control the altitude of the balloon, and to operate the pump to pump air out of the envelope to control the altitude of the balloon, wherein the material of the envelope is arranged so as to sag between the struts or rods and form at least one catenary surface when there is an air pressure differential between the pressure inside of the balloon envelope and the atmospheric pressure outside the envelope.

Provided is a balloon-launching apparatus capable of reducing an increase in the size of the apparatus when a large number of housing sections for housing observation balloons are provided. A balloon-launching apparatus 1 includes a plurality of housing sections 41 each formed in a box shape having an opening 321 that opens in an upper part thereof and configured to house a balloon 21, the housing section 41 launching the balloon 21 from the opening 321. The plurality of housing sections 41 are arranged in a matrix shape. Due to the matrix arrangement of the housing sections 41, the balloon-launching apparatus 1 can reduce the creation of dead space even when a large number of the housing sections 41 are disposed and can thus reduce an increase in the size of the balloon-launching apparatus 1.

Provided is a balloon-launching apparatus capable of reducing an increase in the size of the apparatus when a large number of housing sections for housing observation balloons are provided. A balloon-launching apparatus 1 includes a plurality of housing sections 41 each formed in a box shape having an opening 321 that opens in an upper part thereof and configured to house a balloon 21, the housing section 41 launching the balloon 21 from the opening 321. The plurality of housing sections 41 are arranged in a matrix shape. Due to the matrix arrangement of the housing sections 41, the balloon-launching apparatus 1 can reduce the creation of dead space even when a large number of the housing sections 41 are disposed and can thus reduce an increase in the size of the balloon-launching apparatus 1.

High-altitude balloons and apparatuses for filling such high-altitude balloons are provided. As an example, an apparatus for filling a high-altitude balloon includes a tube extending through envelope material of the balloon is provided. The apparatus also includes a flange connected to a first end of the tube. The flange is connected to an interior surface of the balloon. A fitting is connected to a second end of the tube. The fitting is configured for attachment with an apparatus for filling the balloon with lift gas. In addition, methods of filling high-altitude balloons with lift gas and methods of manufacturing balloons are also provided.

Aspects of the technology relate to temperature regulation for high altitude, long duration balloons, such as balloons that operate in the stratosphere for weeks, months or longer. A balloon covering overlays the balloon envelope, providing an opaque or otherwise light-reflective layer with low emissivity that blocks or reflects optical and/or infrared light. Heat from within the envelope is reflected back from the covering toward the envelope, while light from the sun is reflected back towards the environment. An active venting system is employed to draw in cooler ambient air from the external environment while expelling warmer air from within the envelope. Vent and air intake assemblies of the active venting system are actuated in view of current and/or predicted balloon conditions to regulate internal balloon temperature. This approach reduces repeated pressure changes, which can put undue stress on the balloon envelope and adversely affect the operational lifespan of the system.

Aspects of the technology relate to temperature regulation for high altitude, long duration balloons, such as balloons that operate in the stratosphere for weeks, months or longer. A balloon covering overlays the balloon envelope, providing an opaque or otherwise light-reflective layer with low emissivity that blocks or reflects optical and/or infrared light. Heat from within the envelope is reflected back from the covering toward the envelope, while light from the sun is reflected back towards the environment. An active venting system is employed to draw in cooler ambient air from the external environment while expelling warmer air from within the envelope. Vent and air intake assemblies of the active venting system are actuated in view of current and/or predicted balloon conditions to regulate internal balloon temperature. This approach reduces repeated pressure changes, which can put undue stress on the balloon envelope and adversely affect the operational lifespan of the system.

A towed atmospheric balloon system includes an atmospheric balloon including a quantity of lift gas and a neutral buoyancy towing system coupled with the atmospheric balloon. The neutral buoyancy towing system includes one or more towing thrusters configured to move the towed atmospheric balloon system in a neutrally buoyant condition between altitudes, and a power source operatively coupled with the towing thruster. Wherein a composite mass of the towed atmospheric balloon system includes component masses of the atmospheric balloon and the neutral buoyancy towing system, and the composite mass is static and neutral buoyancy is maintained with movement between altitudes. At differing altitudes the composite mass of the towed atmospheric balloon system is static and the system remains neutrally buoyant.

An airship dynamic adaptive harness is provided to stabilize airships and particularly a tethered aerostat in high winds and atmospheric changes. A novel adaptive device accommodates the supply of a lift gas and simultaneously controls opposing cables in a tethered harness with a cascade control system that provides an immediate and particularly the dynamic control of roll, yaw and particularly the pitch of the aerostat in response to real time environmental flight conditions and impart stability to the airship in high winds using a stability zone geometric suspension control system and enhance the duration of in flight missions. A lifting gas replenishment system and particularly a ground based lifting gas replenishment system adds long duration deployment to the dynamic adaptability to high wind conditions for long term deployment.