A cargo harness comprising a first diagonal strap, a second diagonal strap overlapping the first diagonal strap at a X-crossing. The first diagonal strap may be coupled to the second diagonal strap at a first joint. The cargo harness may also include a cross strap having a first end, a second end and a sleeve disposed between the first end and the second end, wherein the first diagonal strap and the second diagonal strap pass through the sleeve and the sleeve overlaps at least a portion of the x-crossing. In one embodiment, the cargo harness may include a dual-point release strap assembly operably connected to the first and second diagonal strap for connecting a cargo load to a parachute harness.

A cargo harness comprising a first diagonal strap, a second diagonal strap overlapping the first diagonal strap at a X-crossing. The first diagonal strap may be coupled to the second diagonal strap at a first joint. The cargo harness may also include a cross strap having a first end, a second end and a sleeve disposed between the first end and the second end, wherein the first diagonal strap and the second diagonal strap pass through the sleeve and the sleeve overlaps at least a portion of the x-crossing. In one embodiment, the cargo harness may include a dual-point release strap assembly operably connected to the first and second diagonal strap for connecting a cargo load to a parachute harness.

The embodiments of the Parachute Landing Assistant are comprised of a battery pack, a power switch, an LED indicator light; an audio jack; a microcontroller; and a ground proximity sensor. The LED indicator light informs the parachutist as to whether operation is enabled or disabled and indicates when the unit is charging. The microcontroller controls the components of the Parachute Landing Assistant. The ground proximity sensor senses the distance from the ground of the parachutist. The ambient pressure sensor allows the unit to determine its height. During a jump the ambient pressure gauge will sense the pressure change and turn on the Parachute Landing Assistant. It will also be used to send a warning to advise the parachutist of upcoming flare tones established by the ground proximity sensor and microcontroller.

The embodiments of the Parachute Landing Assistant are comprised of a battery pack, a power switch, an LED indicator light; an audio jack; a microcontroller; and a ground proximity sensor. The LED indicator light informs the parachutist as to whether operation is enabled or disabled and indicates when the unit is charging. The microcontroller controls the components of the Parachute Landing Assistant. The ground proximity sensor senses the distance from the ground of the parachutist. The ambient pressure sensor allows the unit to determine its height. During a jump the ambient pressure gauge will sense the pressure change and turn on the Parachute Landing Assistant. It will also be used to send a warning to advise the parachutist of upcoming flare tones established by the ground proximity sensor and microcontroller.

The present disclosure provides danger avoidance apparatuses and related methods, such as for use to avoid avalanches. An apparatus may include a container configured to couple to a user, a lift providing mechanism, a descent control mechanism and at least one rip cord engaged with the container and selectively operable by the user. Both the lift providing mechanism and the descent control mechanism may be movably coupled to the container between a packed position within the container and a deployed position exterior to the container controlled via the at least one rip cord. The lift providing mechanism may include an airfoil that provides lift to the user at a first velocity of the user along a first direction. The descent control mechanism may control the descent and reduce the velocity of the user along the first direction from the first velocity in the deployed position.

The present disclosure provides danger avoidance apparatuses and related methods, such as for use to avoid avalanches. An apparatus may include a container configured to couple to a user, a lift providing mechanism, a descent control mechanism and at least one rip cord engaged with the container and selectively operable by the user. Both the lift providing mechanism and the descent control mechanism may be movably coupled to the container between a packed position within the container and a deployed position exterior to the container controlled via the at least one rip cord. The lift providing mechanism may include an airfoil that provides lift to the user at a first velocity of the user along a first direction. The descent control mechanism may control the descent and reduce the velocity of the user along the first direction from the first velocity in the deployed position.

A method and apparatus for facilitating folding and packing of a parachute into a deployment bag is a planar, semi-rigid, horizontally oriented rectangular fabric panel that is seamed or scored to fold at four or more junctures.

A method and apparatus for facilitating folding and packing of a parachute into a deployment bag is a planar, semi-rigid, horizontally oriented rectangular fabric panel that is seamed or scored to fold at four or more junctures.

A parafoil for operation at high altitudes, in low density air, or at low airspeeds, and methods for opening same. Some versions of the parafoil comprise flexible members connected to the parafoil canopy. When the parafoil canopy is in a stowed configuration, the members are deformed, storing elastic energy. When the canopy is released from its stowed configuration, the members spring back to their undeformed shapes, thereby opening or assisting with opening the canopy. The flexible member may also be attached to a base structure, which is attached to the payload. The members may comprise rods or hollow tubes that can be flexed using a fulcrum near the base structure, or a spacer plate, so that the ends connected to the canopy are restrained by a parachute bag containing the stowed or packed canopy. The parachute bag can be opened prior to or during detachment of the parafoil from the flight vehicle.

A parafoil for operation at high altitudes, in low density air, or at low airspeeds, and methods for opening same. Some versions of the parafoil comprise flexible members connected to the parafoil canopy. When the parafoil canopy is in a stowed configuration, the members are deformed, storing elastic energy. When the canopy is released from its stowed configuration, the members spring back to their undeformed shapes, thereby opening or assisting with opening the canopy. The flexible member may also be attached to a base structure, which is attached to the payload. The members may comprise rods or hollow tubes that can be flexed using a fulcrum near the base structure, or a spacer plate, so that the ends connected to the canopy are restrained by a parachute bag containing the stowed or packed canopy. The parachute bag can be opened prior to or during detachment of the parafoil from the flight vehicle.