High Voltage Engineering- OVER VOLTAGES IN ELECTRICAL POWER SYSTEMS
Joints ppt devesh
1. ASSIGNMENT ON CONCRETE
JOINTS IN BUILDINGS
SUBMITTED TO –
AR.RICHA GUPTA
SUBMITTED BY- DEVESH TRIPA
B – ARCH 4TH YEAR
CONSTRUCTION AND MATERIALS
2. INTRODUCTION
Any joint, as in a physical break or gap between members, in a concrete
structure or building is a potential weak link which may lead to
serviceability problems, lack of durability or structural failure. Yet seldom,
if ever, is a building constructed without them. In many situations they are
necessary requirement (eg to accommodate anticipated differential
movement between members) and are sometimes regarded as a
necessary evil. Frequently, problems arise because they are given
insufficient attention by designers both in terms of their location and
detail design.
3. Construction Joints
Expansion Joints
Contraction Joints
Isolation Joints
TYPES OF JOINTS IN
CONSTRUCTION
4. CONSTRUCTION JOINTS
They are placed in a concrete slab to define the extent
of the individual placements, generally in conformity
with a pre determined joint layout.
They must be designed in order to allow displacements
between both sides of the slab.
They have to transfer flexural stresses produced in the
slab by external loads.
They must allow horizontal displacement right-angled
to the joint surface that is normally caused by thermal
and shrinkage movement.
At the same time they must not allow vertical or
rotational displacements.
8. EXPANSION JOINTS
They are placed in concrete to prevent expansive
cracks formed due to temperature change.
Concrete undergoes expansion due to high
temperature when in a confined boundary which
leads to cracks.
Expansion joints are provided in slabs, pavements,
buildings, bridges, sidewalks, railway tracks, piping
systems, ships, and other structures.
This article emphases on need of expansion joint in
concrete, characteristics of expansion joints, types of
expansion joint and installation of expansion joints.
9. CRACKS DEVELOPED DUE TO
EXPANSION OF
CONCRETE.
Figure 3 :Joints related to shapes of
Building
10. NEED OF EXPANSION JOINT IN
CONCRETE
Concrete moves during expansion and shrinkage, due to
which the structural elements shift slightly.
To prevent harmful effects due to concrete movement,
several expansion joints are incorporated in concrete
construction, including foundations, walls, roof
expansion joints, and paving slabs.
These joints need to be carefully designed, located, and
installed.
If a slab is positioned continuously on surfaces
exceeding one face, an expansion joint will be necessary
to reduce stresses.
Concrete sealer may be used for the filling of gaps
produced by cracks.
11. CHARACTERISTICS OF
EXPANSION JOINTS
They permits thermal contraction and expansion
without inducing stresses into the elements.
It is designed to absorb safely the expansion and
contraction of several construction materials, absorb
vibrations, and permit soil movements due to
earthquakes or ground settlement.
They are normally located between sections of
bridges, paving slabs, railway tracks, and piping
systems.
They are incorporated to endure the stresses.
It is simply a disconnection between segments of the
same materials.
In the concrete block construction, they are expressed
as control joints.
12. LOCATION OF EXPANSION
JOINT
1.Many designers consider it good practice to place
expansion joints where walls change direction as in L-
T- Y-, and U-shaped structures, and where different
cross sections develop.
Figure 3 :Joints related to shapes of Building
13. 2. Expansion joints may be necessary at the junction of
tall and short buildings (Fig.4) to avoid distress due to
differential settlements
3. When expansion joints are required in nonrectangular
structures,they should always be located at places where
the plan or elevation dimensions change radically.
Figure 4 :Joints related to shapes of Building
14. 4. The simplest expansion joint is one on a column
line with double columns.
Figure 5 :Joints related to shapes of Building
15. 5.Expansion joints without a double column may be
used by introducing them in the third or quarter point
in the slab as in fig 6.
Figure 6 :Joints related to shapes of Building
6. Joints should extend through foundation walls, but column
footings need not be cut at a joint unless the columns are
short and rigid. No reinforcement should pass through these
joints; it should terminate 2 in. from the face of the joint.
Dowels with bond breaker may be used to maintain plane.
16. INSTALLATION OF EXPANSION
JOINTS
The depth of an expansion joint is usually one
fourth of the slab thickness, or more if necessary.
The expansion joint gap depends on the type of
slab, like floating slab floor, vehicle pavement,
sidewalk, or monolithic slab foundation.
It is also influenced by the slab dimensions, type
of concrete, and the reinforcing materials being
used.
Cracks in concrete may occur at the expansion
joints due to improper concrete mix or curing.
These conditions cause shrinkage between the
expansion joints and cracks can be formed.
17. Pre-Concrete Installation
When the site is prepared for the concrete pouring
and the provisioning of the expansion joints in
slabs are made prior to the placing of concrete.
An individual expansion joint is created by the
insertion of a flexible material that runs along the
joint length.
After Concrete Installation
Once the concrete is set, suitable tools are used
for making grooves in the poured concrete for
placing of the joint materials.
18. ISOLATION JOINTS
The joints provided to accommodate the expansion of
adjacent parts in a building are known as expansion
joints.
They allow movement to occur between a concrete
slab and adjoining columns and walls of a building.
They are provided to separate new concrete from
existing or adjacent construction, which might expand
and contract differently or experience different soil
settlement or other movement.
If the fresh concrete were not separated from these
elements by an isolation joint, a crack could form
where the two meet.
The should be 1/4 in. to 1/2 in. wide, and filled with a
molded fiber, cork, or rubber strip that is set 1/4 in.
below the surface.
21. CONTRACTION
JOINTS
• A contraction joint is formed by creating a plane of weakness. Some,
or all, of the reinforcement may be terminated on either side of the
plane. Some contraction joints, termed “partial contraction joints,”
allow a portion of the steel to pass through the joint. These joints,
however, are used primarily in water-retaining structures.
• Contraction joints consist of a region with a reduced concrete cross
section and reduced reinforcement. The concrete cross section should
be reduced by a minimum of 25 percent to ensure that the section is
weak enough for a crack to form
22. CONTRACTION JOINTS
• In terms of reinforcement, there are two types of contraction joints
1. Full contraction joints (ACI 350R).
2. Partial contraction joints (ACI 350R).
• Full contraction joints:
Full Contraction joints are constructed with a complete break in
reinforcement at the joint. Reinforcement is stopped about 2 in.
from the joint and a bond breaker placed between successive
placements at construction joints.
• Partial contraction joints:
A portion of the reinforcement passes through the joint in partial
contraction joints. Partial contraction joints are also used in liquid
containment structures.
23. CONTRACTION
JOINTS
• Water stoppers can be used to ensure water tightness in full and
partial contraction.
• Contraction and expansion joints within a structure should pass
through the entire structure in one plane. If the joints are not aligned,
movement at a joint may induce cracking in an un-jointed portion of
the structure until the crack intercepts another joint.
24. LOCATION OF CONTRACTION
JOINTS
• Table 1.1 shows recommendations for contraction joint spacing.
• Recommended spacing's vary from 15 to 30 ft (4.6 to 9.2 m) and
from one to three times the wall height.
• The Portland Cement Association (1982) recommends that
contraction joints be placed at openings in walls, as illustrated in Fig.
3.1. Sometimes this may not be possible.
27. SEISMIC JOINTS
• Seismic joints are wide expansion joints provide to separate portions
of buildings dissimilar in mass and in stiffness. The seismic joint
coverage must allow movement, and be architecturally acceptable.
• The width of a seismic joint should be equal to the sum of the total
deflections at the level involved from the base of the two buildings,
but not less than the arbitrary rule of 1 in. for the first 20 ft of height
above the ground, plus 1/2 in. for each 10 ft additional height.
• The determination of these deflections will be the summation of the
story drift in addition to the building's flexural deflection to the level
involved. Shear wall buildings, being much stiffer, need a seismic
joint only ,say, half as wide, since the earthquake oscillations of shear
wall buildings will be much smaller than those of framed buildings.
28. SEISMIC JOINTS
(a) Roof parapet separation. (b) Plan at exterior vertical closure.
Seismic separation joint details
29. SEISMIC JOINTS
• Nonsymmetrical configuration with reentrant corners (e.g., L-or H-
shaped buildings) are particularly susceptible to destructive torsional
effects. Primary damage often occurs at the reentrant corners.
• Allowing separate building masses to vibrate independently by using
seismic separator joints that allow free movement to occur generally
improves structural performance.