A structure for growing plants comprising a main support, vertical supports along the perimeter of the foundation, a perimeter frame connected to the vertical supports, cables connected to the main support, vertical supports and perimeter frame, and an inner and outer shell formed from transmissive panels supported by the cables.

A clearspan structure including component systems, and methods of forming a clearspan structure including component systems, for mitigating hazards to personnel or equipment from explosions, fires, toxic material release, and other hazards in hazardous locations. The exemplary clearspan structure is also capable of withstanding environmental conditions such as snow loads and wind. The exemplary clearspan structure is, for example, a tent or fabric structure which includes a plurality of frame members forming a support system for the clearspan structure, and fabric roof portions and walls for enclosing the clearspan structure.

A clearspan structure including component systems, and methods of forming a clearspan structure including component systems, for mitigating hazards to personnel or equipment from explosions, fires, toxic material release, and other hazards in hazardous locations. The exemplary clearspan structure is also capable of withstanding environmental conditions such as snow loads and wind. The exemplary clearspan structure is, for example, a tent or fabric structure which includes a plurality of frame members forming a support system for the clearspan structure, and fabric roof portions and walls for enclosing the clearspan structure.

A long-span structure engaged with a plurality of first and second transportation devices for moving the long span structure. The transportation devices travel along parallel, longitudinally-oriented first and second tracks; moving the structure between a first position and a second position. A first region of the structure is fixed to each first transportation device. A second region of the structure is secured to each second transportation device via a bearing assembly. The first and second regions of the structure are laterally spaced apart. When the long-span structure thermally expands or contracts, a slider plate of each bearing assembly moves laterally relative to the rest of the bearing assembly. Growth of the structure in a predictable direction is forced by keeping the first region thereof fixed against lateral movement with the first transportation devices and allowing movement of the second region thereof via the bearing assemblies on the second transportation devices.

A long-span structure engaged with a plurality of first and second transportation devices for moving the long span structure. The transportation devices travel along parallel, longitudinally-oriented first and second tracks; moving the structure between a first position and a second position. A first region of the structure is fixed to each first transportation device. A second region of the structure is secured to each second transportation device via a bearing assembly. The first and second regions of the structure are laterally spaced apart. When the long-span structure thermally expands or contracts, a slider plate of each bearing assembly moves laterally relative to the rest of the bearing assembly. Growth of the structure in a predictable direction is forced by keeping the first region thereof fixed against lateral movement with the first transportation devices and allowing movement of the second region thereof via the bearing assemblies on the second transportation devices.

A deployable production facility may be used to produce building modules for use in the construction of buildings, and may be capable of later being redeployed at other locations. A frame is removably mounted to a production floor and is used to support one or more overhead cranes that are positioned over one or more production lines defined on the production floor, and a tent, is used to enclose the production line(s), frame and overhead cranes. As desired, the tent, overhead cranes and frame may be disassembled and redeployed at a different site.

A deployable production facility may be used to produce building modules for use in the construction of buildings, and may be capable of later being redeployed at other locations. A frame is removably mounted to a production floor and is used to support one or more overhead cranes that are positioned over one or more production lines defined on the production floor, and a tent, is used to enclose the production line(s), frame and overhead cranes. As desired, the tent, overhead cranes and frame may be disassembled and redeployed at a different site.

An inflatable habitat using inflatable structures and necessary accessories offers secure permanent human settlement in an environment such as Mars with an air pressure below the earth's atmospheric pressure. Built upon a crater, the inflatable structure comprises various resilient multilayer roof segments integrated with segment frames to contain extreme internal inflation pressures to provide habitability, maintenance of thermal environment, and low-cost manufacturability using local resources. The roof of the inflatable structure is firmly secured along a rim and a floor of the crater through a wall anchor system and a dual internal roof anchor system to provide a durable structure against hostile weather conditions. A “smart design” using the wall anchor system allows the installation of an outer roof in parallel to the existing roof. Further, a magnetic radiation shield generated through roof power elements externally encloses the roof to facilitate optimal active protection against solar and/or cosmic radiations.

An inflatable habitat using inflatable structures and necessary accessories offers secure permanent human settlement in an environment such as Mars with an air pressure below the earth's atmospheric pressure. Built upon a crater, the inflatable structure comprises various resilient multilayer roof segments integrated with segment frames to contain extreme internal inflation pressures to provide habitability, maintenance of thermal environment, and low-cost manufacturability using local resources. The roof of the inflatable structure is firmly secured along a rim and a floor of the crater through a wall anchor system and a dual internal roof anchor system to provide a durable structure against hostile weather conditions. A “smart design” using the wall anchor system allows the installation of an outer roof in parallel to the existing roof. Further, a magnetic radiation shield generated through roof power elements externally encloses the roof to facilitate optimal active protection against solar and/or cosmic radiations.

A method and apparatus according to which a blast resistant shelter is assembled. The blast resistant shelter includes first and second structural members, a third structural member coupled to the first and second structural members, a first airway adjacent the third structural member, and a first blast panel pivotably mounted to the third structural member and adapted to pivot thereabout in response to a blast wave. In a first configuration, the first blast panel is detachably connected to a first portion of the blast resistant shelter and prevented from pivoting about the third structural member so that the first blast panel obstructs air flow through the first airway. In a second configuration, in response to the blast wave, the first blast panel is detached from the first portion of the blast resistant shelter and permitted to pivot about the third structural member to permit air flow through the first airway.