Earthquake Tip 25: Load Paths in Buildings PDF

Summary

This document discusses the importance of load paths in earthquake-resistant buildings. It explains how inertia forces are transferred through structural elements to the foundation. Horizontal and vertical diaphragm elements, connections, and foundations are key components of load paths.

Full Transcript

Learning
Earthquake Design
Earthquake Tip 25 and
Construction
Why are Load Paths Important in Buildings?
What are Load Paths?
Mass is present all through in a building - from Column
Floor
roof parapet to foundation. Earthquake ground Slab
Beam-Column
shaking induces inertia forces in a building where Joints
mass is present. These inertia forces are transferred
downwards through horizontally and vertically Floor

aligned structural elements to foundations, which, in
turn, transmit these forces to the soil underneath. The Beam
Shear
Wall
paths along which these inertia forces are transferred Braced
Frame Bay
through building are Load Paths (Figure 1a). Buildings
may have multiple load paths running between locations
Z
of mass and foundations. Load paths are as much a Y Foundation

concern for transmitting vertical loads (e.g., self-
X Soil
weight, occupancy load, and snow; Figure 1b) as for (a)
Inertia Force
horizontal loads (e.g., earthquake and wind; Figure 1c). in Y-direction
Structural elements in buildings that constitute load
paths include:
(a) Horizontal diaphragm elements laid in horizontal
plane, i.e., roof slabs, floor slabs or trussed roofs
and bracings;
(b) Vertical elements spanning in vertical plane along
height of building, i.e., planar frames (beams and
columns interconnected at different levels), walls
(usually made of RC or masonry), & planar trusses; Not loaded
Loaded
(c) Foundations and Soils, i.e., isolated and combined
Loaded Ground movement
footings, mats, piles, wells, soil layers and rock; and (b) in Y-direction (c)
(d) Connections between the above elements. Figure 1: Load paths for different load actions –
Importance of Load Paths (a) key structural elements constituting load
Buildings perform best in earthquakes, when paths, (b) vertical load paths, and (c) lateral load
inertia forces generated in them are transmitted to paths
foundation by continuous and direct load paths
without being bent or interrupted. When some structural
elements are discontinued along a direct load path,
This edge
loads have to bend and take detours to other load elongates
paths; buildings with discontinuous or indirect load paths
are undesirable, because brittle damage can occur in
structural elements at the interruptions or bends.
Horizontal Diaphragms
No edge shortens
Floor and roof slabs are thin, wide structural or elongates
elements laid in a horizontal plane at different levels.
They transfer inertia forces induced by their own Wall
masses, to vertical elements on which they rest. During
This edge
earthquake shaking, horizontal diaphragms act like shortens
beams in their own horizontal plane and transmit inertia (b)
forces to vertical elements, such as structural walls or
planar frames. Slabs that are long in plan (i.e., flexible in
their own plane), bend and undergo undesirable
stretching along one edge and shortening along the (a)
other (Figure 2); they perform best when relative Figure 2: In-plane deformation in horizontal
diaphragms – (a) absent, if plan aspect ratio is
deformations are minimal and in-plane stiffness and
up to 3, and (b) present, if plan aspect ratio
strength sufficiently large. In general, slabs should be
exceeds 5
rectangular with plan length/plan width ratio less than 3.
IITK-BMTPC Earthquake Tip 25
Why are Load Paths Important in Buildings? page 2
Horizontal floors can effectively resist and transfer (b) Load path geometry must be simple: Uninterrupted,
earthquake forces through direct load paths, provided direct load paths should be provided at regular
that they do not have significant openings. Large intervals along length and width of the building;
openings or cut-outs in floors interrupt load paths and (c) Load paths must be symmetrical in plan: A building
may prevent smooth, direct transfer of forces to will sway uniformly in two horizontal directions,
vertical elements. Openings in floors are necessary, when structural elements constituting load paths
e.g., to allow for elevator core or staircase to pass are placed symmetrically in plan. Otherwise, it may
through. But, these should be as small as possible, and twist about a vertical axis, which is detrimental to
as few as possible. Their locations should be carefully its earthquake performance.
considered; the ideal location for openings is close to (d) Robust connections are needed between structural
center of floor slabs in plan. elements along load paths: In an earthquake-resistant
Vertical Elements structure, every connection is tested during strong
Typical structural elements (present in vertical earthquake shaking. These connections should be
planes) of buildings are columns, braces and structural stiff and strong to offer continuous load paths
walls or a combination of these (Figure 3). They collect without being damaged during strong earthquake
gravity and (horizontal and vertical) earthquake inertia shaking (Figure 4).
forces from floor diaphragms at different levels, and
bring them down to the foundations below.
It is possible to design and construct earthquake-
resistant buildings with various structural systems,
including Moment Resisting Frames (MRFs), Frames
with Brace Members (called Braced Frames (BFs)),
Structural Walls (SWs; also called Shear Walls), or a
combination of these. Some of these systems require
more advanced knowledge of design and higher
quality control during construction than others, as
reflected by their relative performance during
earthquakes. For instance, buildings with SWs are easy
to design and construct, and generally perform better
during earthquakes, than buildings with MRFs alone.
Photo Courtesy: Sudhir K. Jain

Figure 4: Deficient connection between slabs
and vertical elements – collapse of an RC
frame building during 2001 Bhuj (India)
earthquake

(a) (b) (c) Related - Earthquake Tip
Figure 3: Structural systems in buildings that Tip 5: What are seismic effects on structures?
Tip 6: How architectural features affect buildings during
help resist lateral earthquake-induced inertia earthquakes?
loads – (a) MRFs : moment-resisting frames,
(b) BFs : braced frames, and (c) frame-wall dual
systems Resource Material
Arnold,C., and Reitherman,R., (1982), Building Configuration and
Seismic Design, John Wiley, USA
Key Requirements of Load Paths Ambrose,J., and Vergun,D., (1999), Design for Earthquakes, John
Earthquake performances of buildings are Wiley & Sons, Inc., USA
determined by soundness of their load paths,
independent of the material with which buildings are
built, e.g., masonry, RC or structural steel. Earthquake Authored by:
codes require designers to ensure presence of adequate C.V.R.Murty
lateral load paths in buildings in two horizontal plan Indian Institute of Technology Jodhpur, India
directions. Salient requirements of load paths are: Sponsored by:
(a) Load paths must exist in all directions of a building: Building Materials and Technology Promotion
Earthquake shaking occurs in all directions, and Council, New Delhi, India
can be expressed as a combination of shaking in
one vertical and two (mutually perpendicular) This release is a property of IIT Kanpur and BMTPC. It may
horizontal directions. Hence, adequate load paths be reproduced without changing its contents with due
acknowledgement. Suggestions or comments may be sent
are needed along the vertical and the two mutually to: [email protected]. To see all IITK-BMTPC Earthquake Tips, visit
perpendicular horizontal directions. www.nicee.org or www.bmtpc.org.