PRINCIPLES OF STRUCTURE IN BUILDINGS

main loads causes by = GRAVITY ( live and dead loads), vertically downwards

                                = WIND (positve and negative loads) , mainly horizontal and multi directionl

REINFORCED CONCRETE

THE BEAM

concrete = compressive strength

steel = tensile strength

- together = combination =best result

reinforcing - adequate cover + 40mm

                = bar has  good grip to a body of concrete

                = no danger of moisture causing corrosion and spalling

- cantilever = a projecting beam supported at one end

- force of the bending moment = a combination of the load and it's distance from the point of support.

- beams spanning across columns = rienforcing is added at right angles to these lines to resist against failure ( shear failure)

simple slab -  smaller spans between supports

                   = no beams needed

mushroom -  very economical

                  = for large areas of spaces with no complications

flat rib - development of mushroom slab

           = allows longer spans in one direction

pick rib -  beams pick up slab loads and covey them to columns

             = slab becomes thinner

ribs - slab between ribs can be very thin

        = resemble hollow slab

coffer/waffle slab - combination of slab and beam

                           = reasonable overall depth for spans

THE COLUMN

columns = transmit loads from the building to the foundations at given points.

slenderness ration of a column = ration of width or thickness to height = reinforcing needs to be added for a column to take on much more load.

column - one side is in tension and another in compression

           = reinforcing is evenly and symmetrically placed = avoid buckling

- concrete columns and beams are much thicker than steel = juctions (structural elements0 for more rigid and secure.

- at junctions = reinforcing bars take bending moment loads

- at multi-storey buildings = at higher levels columns remain the same size as the lower level = standard size (formwork and finishes)

POPULARITY OF CONCRETE

concrete = fludity - may be moulded to variety of shapes

= pipes and services may be cast in

= finish - keeps its good appearance for longer

=inherent quality lasts indefinitely

= becomes harder and stronger with age

= natural material(sand and stone)

resistance to corrosion

ADVANTAGES OF FRAMED STRUCTURES

- steel and concrete frame replacing masonry or brick load bearing structure

- frame can span freater distances

-larger openings(internally and in hte envelope)

-no load bearing walls = maybe placed anywhere = flexibility in planning

- walls may be of any material (provide basic functions0

- lighter partitions = structural savings

STEEL STRUCTURES

governing principles of steel structure = concrete

- yet method of using some cases differs and overall appearance is very different

-steel = is a different type of material

         = very strong structurally

         = useful tensile qualities(better tensile, higher cost)

         = because of stength -reads lighter and elegant

         = by nature -flexible

         = lower depth-to-span ratio than concrete

STRUCTURAL SHAPES/SECTIONS

- flat steel bar = easily bend

- steel ange will resist a moderate load yet vertical flange under compression will buckle

- resist = add another flange = channel

-more strength = I beam / H section beam - hot rolled sections, process of manufacture

columns = I/H section

trusses = combination of sections used

shorter beam spans = I section

LIGHT GUAGE SECTIONS

- refers to as cold rolled pressed or light guage

- forms = door jambs, in painted steel etc.

- for light loads and smaller spans

- former range from about 8-20mm thick, later average 2mm

- common = roof purlins, vertical sheet clading rails for industrial buildings

COMMON STRUCTURAL FORMS

- barcing or triangulation

- in steel because of smaller joints and flexibility of steel , trusses have to be braced

- rectangular arrangement of members with weak joint will stabilise with bracing

- two ties of bracing are lighter and less costly than one stiff brace = movement maybe in amy direction, therefore, prevented

- application = work out the tendency of movement first then arrange braced to act in tension

- purlins are placed at the jionts where the load is distributed to 3 memebers ar once

-lattice principle(interlaced structure or pattern) make up a prtial frame(entrance0

application = H sections

- stanchions = columns

- roof trusses need to take upward lift = wind, wight of structure is not as strong as the downward force.

- steel framed buildings have additional bracing to prevent movement or deflection in the overall structure.

-steel sheeting for roofing and cladding is profiled(corrugated)

= placed at the top and bottom of teh given depth to stabilise it along its length

= deeper the profile - greater the span

= thicker the sheet - greater the span

- most economical = arranges/ designs must be suitably combined

- principle then = construct the envelope of a thin spanning material, rests on a secondary maybe tertairy support system, rests on main structural frame, rests on columns, rests on foundations, rest on the earth.

- in concrete the lattice principle maybe used in two directions = space frame

depth-to-span ratio

solid I beam = 1:50

castellated beam = 1:40

lattice/space frame = 1:16-20

concrete = 1:12-15

ADVANTAGES OF STEEL

-quick site erection

- structural elements occupy less space

- large span-to-depth ratio

- lighter overall weight than concrete

- elegant and aesthetically apealing

recycleable

DISADVANTAGES OF STEEL

- corrosion from moisture is a problem

- maintenance cost problem

- fire will weaken stel cause to collapse

- movement is more

- quite noisy

REFERENCE

PRINCIPLES OF STRUCTURE IN BUILDING

 BY MIKE RODSETH

kIsSeS.... :-)