EDMUND FINLEY TRISHA LOWE NICK MENCHEL ANNA SLEETER 60% DESIGN PRESENTATION.

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Presentation transcript:

EDMUND FINLEY TRISHA LOWE NICK MENCHEL ANNA SLEETER 60% DESIGN PRESENTATION

30% DESIGN

TO AVOID THIS…

LIVE LOADS VehicleGross Weight (kg) Wheelbase (m) Track (approx., m) 17’ U-Haul ’ U-Haul ’ U-Haul Pick-Up Truck Standard Size Car

BEAM DESIGN LOAD CALCULATIONS Live Loads (37.5% of the weight of a 17’ U-Haul) Dead Loads (due to slab) Using beam design program, d= m (assuming 0.15 m deep slab) N N N N/m 3 m

SLAB DESIGN LOAD CALCULATIONS Widest Load Spacing, Narrowest Beam Spacing Limiting case Maximum Moment: N*m Minimum Depth: 0.15 m Designed as a beam N 23,444.7 N 24,112.2 N m 0.68 m 1.63 m 3.5 m N load is from curb 23,444.7 N load is from 37.5% of the weight of a 17’ U-Haul Truck

SLAB DESIGN CONSIDERATIONS Determined optimal beam spacing (1.90 m)  Used different track measurements Cases Considered  Each of the four vehicles centered on the span  Each of the four vehicles as far to one edge as possible  Smallest and largest vehicles with one tire centered on the span (basically the same as vehicle at edge) Checked against 0.15 m slab depth to ensure that the moment created would be safe 0.15 m was estimate for slab depth used when designing beam, so recalculation was not necessary

PIER DESIGN Designed as a wall 3.5 m x m x 2 m 2 m 3.5 m m

AMOUNT OF CONCRETE AND FILL Concrete  2 beams spanning piers, slab spanning crossing, 5 piers  Total volume: 28 cubic meters Fill  Around culverts  Total volume:

UPDATED PROFILE VIEW

PLAN VIEW

WHAT COMES NEXT Determine footing for piers Adjust pier shape if necessary Check moment calculations to ensure slabs and beams are thick enough Design armoring Design curb on slab Design reinforcement for concrete