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.

Disclosed is a vertical profile for an automated sliding door. The profile is formed by front and rear walls connected by nose and tail walls. The nose and tail walls are thicker than the front and rear walls to provide enhanced resistance to deflection in the through-door direction. The walls are formed as an aluminum extrusion. The arrangement and thickness of the walls provides strength sufficient to withstand high wind loads without the installation of reinforcing members. Fillets may be provided where the walls are joined to lessen the tendency for the nose and tail walls deflect, further strengthen the profile.

Modular system for creating a structure, in particular a building component, comprising at least one post profile (2), at least one ceiling profile (3) and at least one floor profile (4) for a basic framework of a first modular unit (50, 50′, 50″, 50′″), at least one further post profile (2), at least one further ceiling profile (3) and at least one further floor profile (4) for a basic framework of a second modular unit (50, 50′, 50″, 50′″), and a module connector (38) for connecting the first and the second modular unit (50, 50′, 50″, 50′″), wherein the post profile (2) has a first pin holding fixture (55) and the further post profile (2) has a second pin holding fixture (55), wherein the module connector (38) has a first connecting pin (39) for insertion into the first pin holding fixture (55) and a second connecting pin (40) for insertion into the second pin holding fixture (55), and wherein the module connector (38) has a supporting element (41) on which the first and second connecting pins (39, 40) are arranged.

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 method for producing a support structure having a three-dimensional geometry curved in any manner, includes making at least one first and one second flat material piece. The geometry has curves in three directions that are orthogonal to one another, and the method includes the following steps: A. preparing the desired geometry, B. approximating the desired geometry, C. subdividing the geometry, D. defining at least one clearance region, E. defining a plurality of connection points arranged on the at least one first and one second part, F. defining chamfered edges extending between the polygonal cross-sections, G. developing the at least one first and one second part, H. cutting to length at least one first and one second flat material piece, I. chamfering, and J. connecting the at least one chamfered first material piece and the at least one chamfered second material piece.

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.

Disclosed is a vertical profile for an automated sliding door. The profile is formed by front and rear walls connected by nose and tail walls. The nose and tail walls are thicker than the front and rear walls to provide enhanced resistance to deflection in the through-door direction. The walls are formed as an aluminum extrusion. The arrangement and thickness of the walls provides strength sufficient to withstand high wind loads without the installation of reinforcing members. Fillets may be provided where the walls are joined to lessen the tendency for the nose and tail walls deflect, further strengthen the profile.

A pocket door frame includes a stud having a first section, a second section, and a third section. The first section is perpendicular to the second section, and the third section is perpendicular to the second section. The first section includes a first opening. The stud also includes a second opening located at least partially in the second section and at least partially in the third section. The second opening is at least partially aligned with the first opening so as to provide access to the first opening through the second opening.

A modular constructed building includes a plurality of ground beams and a plurality of wall panels, each ground beam has a pair of surfaces and a longitudinally extending male projection interspaced between the pair of surfaces. The extending male projection is formed as a flat plate and at least able to be partially inserted into a wall panel with each of the wall panels being secured to a respective ground beam, so that each wall panel, at an end opposite the ground beam, has a lateral groove for accepting a protrusion for a T-shaped member or an X-shaped member, and an upper end of each of the wall panels is retained together through each of the wall panels and either a T-shaped member or an X-shaped member.

The present invention provides a building frame structure with both support and ventilation functions, the building frame structure contains at least one starting column and multiple main beams, the main beams are connected with the starting column, and top of the starting column is connected to a fan. The starting column is a hollow cylinder, and there are four thin hollow columns in the starting column. The main beams are hollow structures, and a reinforcing wall is arranged inside the main beams, the reinforcing wall is connected with inner walls of the main beam to form multiple ventilation ducts. When the frame structure is installed, air sent by the fan flows to the ventilation ducts of the main beams through the ventilation spaces of the thin hollow columns, the second air guide holes, and the first air guide holes, and then sends the air to various places in the building.