1. Learning Outcome Lesson Objective
Understand the techniques used in the construction of superstructures for low-rise domestic and commercial buildings
Lesson Objective
To be able to explain the techniques used for construction of floors in domestic and commercial construction

2. Recap What is the purpose of site investigation?
What are its key stages?
What is the difference between a trenchfill foundation and a traditional strip foundation?
When is a wide strip foundation required?
In what situations are strip foundations not suitable?
Why is piling becoming more common?
What is the function of the ground beam which sits on top of the piles?
When are rafts sometimes used?

3. Industrial/Commercial flooring
What are the Functional Requirements of a floor slab?
Provide a flat surface
Strength and stability
Durability and freedom from maintenance
To support load
Fire safety
Resistance to passage of heat
Resistance to passage of sound
Act as a divider (privacy) for the occupants
Upper slab became the ceiling for the storey below
Space between slab and ceiling /floor finish can be used to place building facilities

4. Industrial/Commercial flooring

5. Industrial/Commercial flooring

6. Floor construction: Ground Bearing
Lightweight block
DPC
1. Cavity fill & backfill
2. Hardcore and blinding
3. Damp Proof membrane
4. Insulation & slab
5. Build walls
6. Floor screed

7. Ground Floors
The hardcore fills and levels out the sub floor void, reduces capillary action and provides a level stable base for the concrete.
A thin layer of sand called blinding can then be spread over the hardcore to provide a smooth bed for the polythene damp proof membrane.

8. Floor construction: Ground Bearing
Ground bearing floor – Insulation under slab, DPC above insulation

9. Floor construction: Ground Bearing
Ground bearing floor – Insulation under slab, DPC under insulation

10. Floor construction: Ground Bearing
Ground bearing floor – Insulation above slab, with screed

11. Floor construction: Ground Bearing
Ground bearing floor – Insulation above slab, with chipboard

12. Floor construction: Beam & Block
7. Insulation
8. Vapour check and chipboard
6. Build Wall
1. Cavity fill & backfill
2. Level earth
3. DPC
4. Position beams
5. Block infill and grout

13. Floor construction: Beam & Block
Precast Ground Floors
When do you think pre-cast ground floors may be specified?
the water table is high
there are aggressive chemicals in the ground
the ground is likely to heave
the ground quality is poor and large volumes of hardcore might be required
the site slopes steeply

14. Floor construction: Beam & Block
Modern pre-cast floors
require sub floor ventilation
Periscopic vents are common

15. Floor construction: Beam & Block
Polystyrene insulation
Polythene vapour check
Chipboard with glued joints

16. Floor construction: Beam & Block
Beam & Block Floor - alternative example
Pre-cast beams on DPCs
Polystyrene infill blocks

17. Floor construction: Beam & Block
Insitu concrete – optional reinforcement using lightweight mesh or glass fibre
Powerfloat concrete

18. Floor construction: Beam & Block
Advantages

19. Floor construction
Suspended timber ground floor

20. Floor construction Upper floor: traditional construction
In modern construction joists are supported on joist hangers.
The joists should be a good fit in the hangers and must have a good bearing
to ensure structural stability. They should be nailed to the hangers.
In all but the shortest of spans strutting is required to prevent the floor joists from twisting and cracking the ceiling below

21. Simple first-floor joist plan
This house has cavity walls with mineral wool cavity batts
Joists are built-in to internal leaf
100mm aerated block
50mm mineral wool batt
100mm face brick

22. Lounge
Hall
Approx 5 metres
Kitchen/Diner
Approx 9 metres

23. 1st joist about 50mm from wall
Internal load-bearing walls
Joists 400mm centres
Extra joists to avoid gaps

25. Trimming
Trimmer

26. Strapping
Strutting

27. Photographs

28. Floor construction

29. Floor construction
In any modern house cables and water pipes will have to run through the floor.
To prevent the floor from being weakened the Building Regulation lay down strict rules for the positioning of cables and pipes.
As a general rule cables run through holes drilled in the centre-line of the joists, pipes lie in notches cut in the top of the joists.

30. Floor construction Timber framed construction: Intermediate floors
The construction of the first floor is very similar to that used in more traditional houses.
The joists are usually at 400 or 600mm centres and are secured in position by nailing to the head binder.
A header joist is nailed round the perimeter of the floor and, besides providing a firm base for the upper floor panels, prevents fire from entering the floor cavities.
Once the joists are in position, the chipboard or plywood deck is laid right across the joists, and this forms the platform for the next lift of wall panel

31. Floor construction Timber framed construction: Intermediate floors
Most systems in the UK use the platform method of construction. This means that the upper floor panels sit on the chipboard decking.
If this chipboard gets wet for any reason and needs renewing, there are obvious problems

32. Floor construction
Timber framed construction

33. Floor construction Concrete Intermediate floors
In modern construction low-rise purpose-built flats, usually have upper floors made from precast concrete.
The floors in flats separate dwellings and, as such, require higher levels of fire protection and sound insulation than their timber counterparts in houses.
Concrete floors are also
capable of greater spans than
timber floors and are ideally
suited to flats where large floor
areas may be required without
the complication of unnecessary
internal load bearing walls.

34. To investigate industrial and commercial floor construction
Lecture Objective
To investigate industrial and commercial floor construction

35. Classification of Slabs
Industrial/Commercial flooring
Classification of Slabs
UPPER FLOOR
GROUND FLOOR
TIMBER FLOOR
PRECAST FLOOR
SOLID FLOOR
REINFORCED CONCRETE FLOOR
SUSPENDED GROUND FLOOR

36. Industrial/Commercial flooring
Materials
Steel and concrete; These two materials complete one another.
Why?
Concrete is efficient in compression and steel in tension
Concrete encasement restrain steel against buckling
Protection against corrosion and fire
Steel bring ductility into the structure

37. Industrial/Commercial flooring
Rebar Used For Slab Construction

38. Industrial/Commercial flooring
Joints
Why are joints required in concrete floor slabs?
All concrete floor slabs are subject to stress. Causes include drying shrinkage, settlement, temperature changes, and applied loads. When stresses acting on concrete exceed its tensile strength, cracking will occur.
That’s why joints —planned breaks in concrete — are important. They relieve stress by allowing concrete to move.

39. Industrial/Commercial flooring
Joints
Most concrete floors require three types of joints:
Isolation
Contraction
Construction
Though each type of joint is
installed differently, they all work together
to help minimize cracking.

40. Industrial/Commercial flooring
Composite slabs
Reinforced concrete slab
In-situ concrete on shuttering Partially prefabricated slabs Fully prefabricated slabs

41. Industrial/Commercial flooring
In situ cast concrete floors
The principal types of reinforced in situ cast concrete floor construction:-
Beam and slab
Waffle grid slab
Drop beam and slab
Flat slab

42. Industrial/Commercial flooring
Flat plate system
Waffle Slab
One Way Slab /Two Way Slab

43. Industrial/Commercial flooring
What are the reasons for using composite slabs?
Architectural
Structural
Economical
Functionality
Service and Flexibility
Assembly

44. Industrial/Commercial flooring
What are the Architectural reasons for using composite slabs?
Longer spans
Thinner slabs
More slender columns
More generous design solutions

45. Industrial/Commercial flooring
What are the economical reasons for using composite slabs?
Reduction in building height - saves area of cladding
Loner spans with the same height –column free spaces
Additional storeys with the same total building height
Quicker time of erection
Saving costs, earlier completion of building
Lower financing costs
Ready for use earlier - increasing rental income

46. Industrial/Commercial flooring
What are the functional reasons for using composite slabs?
Fire protection by using principles of reinforced concrete in which the concrete protects the steel
Against Internal fire spread
Resistance to collapse (loadbearing capacity)
Resistance to fire penetration (integrity)
Resistance to the transfer of excessive heat (insulation)

47. Industrial/Commercial flooring
What are the service and flexibility reasons for using composite slabs?
Adaptable structures
Modification during the life of the building
Modify services without violating the privacy of other occupants
Accommodation of service facilities in the ceiling within a false floor in a coffer box running along the walls

48. Industrial/Commercial flooring
What are the assembly reasons for using composite decking slabs?
Working platforms of steel decking
Permanent shuttering
Reinforcement of profiled steel sheetings
Speed and simplicity of construction
Quality controlled products ensure greater accuracy

49. Industrial/Commercial flooring
Precast Hollow Floors
Prestressed Slabs

50. Industrial/Commercial flooring
Precast Flooring
There are many types of precast concrete floor such as :
Precast Hollow Floors
Precast hollow floor units are available in a variety of sections such as box planks / beams, tee section, I beam sections and channel sections.
Composite floors
Composite floors are combination of steel sheet, precast units and in situ concrete.

51. Industrial/Commercial flooring
Precast floor
What are the advantages of Precast Concrete floors?
Doesn’t need formwork
Time taken for concrete to cure in the formwork can be eliminated
Better quality control
Doesn’t need many workers as in in-situ concrete construction
Fast completion of construction project
Long spans available with precast concrete flooring systems reduce the number of secondary beam required and maximize the column free space.
Fire resistance ratings normally between 1 & 2 hours