Steel
Beam or member
A calculation for the linear static analysis of a single steel beam or a multi-span continuous beam. The calculation allows a wide variety of loading to be applied and results for shear, moment, axial force, deflection and axial deflection can all be output.
Steel joist
This steel joist calculation, specific to the needs of US engineers, makes it easy to check the strength capacity and deflection requirements of steel joists.
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Cast-in-place reinforced concrete slab design
This reinforced concrete slab design Eurocode calculation makes it easy to check the design of one or two-way spanning cast-in-place reinforced concrete slabs.
Watch the video at TUACast-in-Place Reinforced Concrete Industrial Ground Floor Design
This concrete ground floor design calculation quickly checks the design subject to point loads, line loads and uniformly distributed loads applied to a slab using fabric, fiber or fiber and bar reinforcement. The calculation uses the Technical Report 34 Guide to Design and Construction, 4th Edition.
Watch the video at TUACast-in-place reinforced concrete stairs
This reinforced concrete stairs Eurocode calculation makes the design of straight flights of cast-in-place reinforced concrete stairs faster and easier. The stairs span longitudinally between supports at the top and the bottom of the flight and are unsupported at the sides. Supporting beams are located at the outside edges of the landings.
Watch the video at TUAPrecast
Precast concrete stair design
This precast concrete stair design Eurocode calculation checks the design of a reinforced straight flight, spanning longitudinally between supports at the top and the bottom of the flight and unsupported at the sides. Supporting beams are located at the outside edges of the landings. The calculation allows for the design of a single precast reinforced concrete unit. A lifting check is included.
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“Ledger” design
This wood ledger design calculation quickly checks the design of solid wood, glulam and structural composite members subject to major and minor axis bending, shear, bearing and axial tension or compression, and flitch members subject to major axis bending, shear and bearing. All design is in accordance with the provisions for Allowable Stress Design (ASD) and Load and Resistance Factor Design (LRFD) methods.
Watch the video at TUATimber joist design
This Timber Joist Eurocode calculation speeds up design by checking solid wood or glulam stud subjected to uniformly distributed loads and point loads. Permanent, imposed and wind loads can be defined depending on the load duration selected. The studs may be braced in the weaker axis by a suitable sheathing fixed to one or both faces, or by the use of dwangs tied into a bracing system or support.
Watch the video at TUATimber rafter design
Speed up design by using this Timber Rafter Eurocode calculation to check solid wood or glulam rafters subjected to uniformly distributed loads and point loads. Permanent, imposed, snow and wind loads can all be defined depending on the load duration selected. The rafter may be either a simply supported single span or a continuous multispan beam propped by purlins.
Watch the video at TUACross-laminated floor design
The Eurocode calculation determines the capacity of a horizontally spanning, cross-laminated timber floor panel subjected to a series of vertical area loads applied to its top edge. Floor panels may feature one or more openings and shear, flexure, perpendicular compression and deflection checks are performed.
Watch the video in TUACross-laminated timber roof panel design
The Eurocode calculation determines the capacity of a cross-laminated timber roof panel, inclined at an angle of 20 to 70 degrees, supporting area loads applied to its top edge. It considers shear, flexure, axial compression, and deflection checks. The documentation reports the horizontal and vertical reactions.
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