RCC
MEMBER DESIGN TIPS
www.softcivil.com
A.BEAMS:
OVERALL DEPTH OF BEAMS:
SL.NO
|
MEMBER
|
SPAN/OVERALL
DEPTH RATIO
|
1.
|
PLINTH
BEAM
|
15
TO 18
|
2.
|
TIE
BEAM
|
18
TO 20
|
3.
|
FLOOR
BEAMS
|
12
TO 15
|
4.
|
GRID
BEAMS
|
20
TO 30
|
1. Beam sections should be designed for:
- Moment values at the column face & (not the value at centre line as per analysis)
- Shear values at distance of d from the column face. (not the value at centre line as per analysis)
- Moment redistribution is allowed for static loads only.
- For beams spanning between the columns about the weak axis, the moments at the end support shall be reduced more and distributed and the span moments shall be increased accordingly to account for the above reduction.
- Moment distribution shall be done in such a way that 15% of the support moments shall be added to the span moment without the support moments getting reduced.
- The section within the span shall be designed for the increased span moment which will account for the concentrated & isolated loading that may act within one span.
- Moment redistribution is not allowed if
- moment co-efficient taken from code table
- designed for earthquake forces and for lateral loads.
- At least 1/3 of the +ve moment reinforcement in SIMPLE SUPPORTS & ¼ the +ve moment reinforcement in CONTINUOUS MEMBERS shall extend along the same face of the member into the support, to a length equal to Ld/3. (Ld-development length)
- Use higher grade of concrete if most of the beams are doubly reinforced. Also when Mu/bd^2 goes above 6.0.
- Try to design a minimum width for beams so that the all beam reinforcement passes through the columns. This is for the reason that any reinforcement outside the column will be ineffective in resisting compression.
- Restrict the spacing of stirrups to 8”(200mm) or ¾ of effective depth whichever is less.(for static loads)
- Whenever possible try to use T-beam or L-beam concept so as to avoid compression reinforcement.
- Use a min. of 0.2% for compression reinforcement to aid in controlling the deflection, creep and other long term deflections.
- Bars of Secondary beam shall rest on the bars of the Primary beam if the beams are of the same depth. The kinking of bars shall be shown clearly on the drawing.
- Length of curtailment shall be checked with the required development length.
- Keep the higher diameter bars away from the N.A(i.e. layer nearest to the tension face) so that max. lever arm will be available.
- Hanger bars shall be provided on the main beam whenever heavy secondary beam rests on the main beam.(Try to avoid the hanger bar if secondary beam has less depth than the main beam, as there are enough cushions available).
- The detailing for the secondary beam shall be done so that it does not induce any TORSION on the main beam.
- For cantilever beams reinforcement at the support shall be given a little more and the development length shall be given 25% more.
- As a short cut, bending moment for a beam (partially continuous or fully continuous) can be assumed as wl^2/10 and the same reinforcement can be detailed at span and support. This thumb rule should not be applied for simply supported beams.
B:SLAB
EFFECTIVE DEPTH:
Sl.no
|
SLAB
|
SPAN/EFFE.DEPTH
|
1.
|
One-
way simply supported slab
|
30
|
2.
|
One-way
continuous slabs
|
35
|
3.
|
Two-way
simply supported slabs
|
38
for L/B=1.5
35
for L/B>1.5
|
4.
|
Teo-way
continuous slabs
|
40
for L/B=1.5
38
for L/B>1.5
|
- Whenever the slab thickness is 150mm, the bar diameter shall be 10mm for normal spacing.(It can be 8mm at very closely spaced).
- Slab thickness can be 10mm,110mm,120mm,125mm,150mm, etc.
- The maximum spacing of Main bar shall not exceed 200mm(8”) and the distribution bars @ 250mm(10”).
- If the roof slab is supported by load bearing wall(without any frames) a bed block of 150/200mm shall be provided along the length of supports which will aid in resisting the lateral forces.
- If the roof is of sheet(AC/GI) supported by load bearing wall (without any frames) a bed block of 150/200mm shall be provided along the length of supports except at the eaves. The bed block is provided to keep the sheets in position from WIND.
- For the roof slab provide a min. of 0.24% of slab cross sectional area reinforcement to take care of the temperature and other weathering agent and for the ponding of rain water etc since it is exposed to outside the building enclosure.
COLUMN:
- Section should be designed for the column moment values at the beam face.
- Use higher grade of concrete when the axial load is predominant.
- Go for a higher section properties when the moment is predominant.
- Restrict the maximum % of reinforcement to 3.
- Detail the reinforcement in column in such a way that it gets maximum lever arm for the axis about which the column moment acts.
- Position of lap shall be clearly mentioned in the drawing according to the change in reinforcement. Whenever there is a change in reinforcement at a junction, lap shall be provided to that side of the junction where the reinforcement is less.
- Provide laps at midheight of column to minimize the damage due to moments(Seismic forces).
- Avoid KICKER concrete to fix column form work since it is the weakest link due to weak and non compacted part.
FOOTING:
- Never assume the soil bearing capacity and at least have one trial pit to get the real site Bearing capacity value.
- Check the Factor of Safety used by the Geotechnical engineer for finding the SBC.
- SBC can be increased depending on the N-value and type of footing that is going to be designed. Vide IS-1893-2000(part-I).
- Provide always PLINTH BEAMS resting on natural ground in orthogonal directions connecting all columns which will help in many respect like reducing the differential settlement of foundations, reducing the moments on footings etc.
- Always assume a hinged end support for column footing for analysis unless it is supported by raft and on pile cap.
The Common assumption of full fixity at the column base may only be
valid for columns supported on RIGID RAFT
foundations or on individual
foundation pads supported by
short stiff piles or by foundation walls in Basement. Foundation pads
supported on deformable soil may have considerable rotational flexibility,
resulting in column forces in the
bottom storey quite different from those resulting from the assumption
of a rigid base. The consequences can be unexpected column HINGES at the top of
lower storey
columns under seismic lateral forces. In such cases the column base
should be modeled by a rotational springs. (Ref:page 164-Seismic design of
Reinforced concrete and
Masonry buildings by T.Paulay & M.J.N.Priestley.)
Also refer the Reinforced concrete Designer’s Handbook by Reynold where
it is clearly mention about the column base support.
R.C.C.WALLS:
- The minimum reinforcement for the RCC wall subject to BM shall be as follows:
- Vertical reinforcement:
a)
0.0012 of cross sectional area for deformed bars not
larger than 16mm in diameter and with characteristic strength 415 N/mm^2 or
greater.
b)
0.0015 of cross sectional area for other types of
bars.
c)
0.0012
of cross sectional area for welded fabric not larger than 16mm in diameter.
Maximum horizontal spacing for the
vertical reinforcement shall neither exceed three times the wall thickness nor
450mm.
- Horizontal reinforcement.
a)
0.0020
of cross sectional area for deformed bars not larger than 16mm in diameter and
with characteristic strength 415 N/mm^2 or greater.
b)
0.0025 of cross sectional area for other types of
bars.
c)
0.0020
of cross sectional area for welded fabric not larger than 16mm in diameter.
Maximum vertical l spacing for the
vertical reinforcement shall neither exceed three times the wall thickness nor
450mm.
NOTE: The minimum reinforcement may
not always be sufficient to provide adequate resistance to effects of shrinkage
and temperature.
2. The He/t for a RCC wall shall
not exceed 30 as per IS:456=2000, where He
is the effective height of the wall and t is the thickness of the RC wall. He
for a braced wall will be :
a)
0.75
H, if
the rotations are restrained at the ends by floors where h is the height of the
wall.
b)
1.0h
.
MISCELLANEOUS:
Ref: (Principle of structures by Ariel
Hanaor).
1. TRUSS:
The
Depth to span ratio for a truss is h/L=10. Beyond a certain optimal value,
increase in structural depth increases weight. The same principle applies to
trusses. An optimal
depth/span ratio for a planar truss is
approximately 1/10. Although forces in the CHORDS decrease with increasing
depth, forces in the WEB are practically UNCHANGED and
increasing the depth increases the
lengths of these members. Approximately half the web members are in COMPRESSION
and increasing their lengths reduces their efficiency
due to the increased susceptibility to
BUCKLING.
- VIERENDEEL GIRDER:
The span to depth ratio=1/8 to 1/10 are
typical.
The compression on top chord or
tension in the bottom chord for a UDL loading is C=T= qL^2/8h where q is the
udl and h is the depth.
- CABLE:
A structure in pure TENSION having
the funicular shape of its load is termed as Cable.
4.ARCH:
Let us now invert the shape of a cable under a
given load, that is the sag at any point is turned into a rise. The point is
now above the chord joining the end points by the
same amount it was previously below it. A
structure built according to the funicular shape in COMPRESSION is termed as an ARCH.
The optional rise to span ratio for an
arch is in the range of 1/6-1/4. The depth to span ratio of an arch is usually
in the range of 1/40 -1/70.
- FOLDED PLATE:
The typical depth /span ratio is in the range from 1/15 to 1/10.
- FLATE PLATE:
A typical depth of a solid FLAT PLATE
is 1/22 -1/18 of the effective span.
- TWO-WAY RIBBED SLAB:
Supported on continuous stiff
supports are in the range of 1/30-1/25 of the lesser effective span.
- FLAT PLATE RIBBED SLAB:
Typical depth of flat plate ribbed slabs are in the range of 1/20-1/17
of the lesser effective span.
- DOMES:
The structural depth of DOMES is the full height of the dome from base
to crown. Depth to span ratio range from as low as 1/8 for shallow domes to ½
for deep domes.
A depth /span ratio of 1/5-1/4 is a common value which is near optimal
for many applications.
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