Natrural loads

A structure's main function is to transfer loads.
1. Natural loads

Gravity load: self-weight

Wind: due to regular and continuous change in atmospheric pressure from place to place on earth's surface air flows across the surface of earth, that is wind. All structures built on the earth's surface have to resist the forces from wind.
If an obstruction is placed in the path of the wind it alters the pattern of the wind flow. which is why planes fly and boats sail. If the object is fixed to the earth's surface, like a building, the wind must flow around and over it. How the wind does it depends both on the wind speed and the shape of the object. Although the pattern of wind flow around buildings is complex the resulting loads from the alteration of wind flow are predominantly at right angles to the surface of the building.

Earth pressure: This because the natural surface has found a shape that is at rest ( not over geological time of course ) so, an alteration will cause forces. If dry sand is piled into a heap, there is a maximum slope for the sides. What is happening inside the heap is complex, and is further complicated bye the addition of water, ( which is why sand castle can be made ) if, however, a heap with vertical side is required, forces are needed to keep the heap in the unnatural shape. In buildings, this occurs when the building has a basement, or is built into a sloping site.

Water pressure: Under the surface of the earth, depending on the local geology and climate, there will be, at some level, water. The top level of this water is called the water table. this level may be at the surface or many metres down in desert. if the siting of the building interrupts the natural water table an unnatural water table is created around and under the building. Not only are the walls loaded by the water pressure but it also causes upward loads on the floor. The building is trying to float!

ground movement, earthquake, altering slightly in surface due to climate or geological change.

Temperature: As structure often exposed to the ambient climate their temperature may vary considerably, from a hot summer day to a cold winter night, and in some case this may cause loads by expand and contract at the joint.

A successful structure must be able to resist the effects of some or all of these natural loads for the whole of its useful life. On the whole these loads cannot be avoided and are an integral part of structure's existence.

2.Useful loads: Unlike natural loads. which cannot be avoided and so must be tolerated, useful loads are ones that are welcomed. These loads happen because the building and hence the structure have been constructed for a useful purpose. and unlike the natural loads, there is a choice for useful loads. they can be horizontally like to store sand and grain in basement or water in pool or rather like earthquakes, machinery housed in a building may tend to shake a building sideways like vibrating machine or crane. industrial proceses may increase or reduce the ambient temperature.

3. Accidental loads: The occurrence of it is inextricably bound up with concepts of safety.

Structure is a system for transferring loads from one place to another.
Analysis ...
Analysis is a vital part of the design of safe and cost-effective structures, however it cannot take place until the basic form of the structure has been decided. We firstly need to settle such Qs as "Should we use steel or concrete?", "How many supports to the beam should we provide?" These early decisions are referred to as design and not analysis.
Design:
- Element design
- Detail design
The usual starting point for a project is a client who has a requirement so then design brief comes up.

Structural Design

Structural design is a highly activity! (not just a case of plugging numbers into formulae)
This activity must be done responsibly, in order to produce safe structures. In most of case, there is no prototype stage or modifications same as most manufactured products in mechanical Eng. THE DESIGN MUST BE RIGHT FIRST TIME! and absolutely it MUST be remained safe throughout its project life.

Shear Force & Bending Moment

One way that these diagrams are drawn:
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Clockwise shear (i.e. when the left-hand side of the beam is being pushed upwards and the right-hand side of the beam, is being pushed downwards) are drawn below the zero line.
Anticlockwise shears are drawn above the zero line.
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Bending moments are always drawn on the tensile side of the beam.
therefore:
Hogging moments are drawn above the line.
Sagging moments are drawn below the line.

We can deduce (to reach an answer or a decision by thinking carefully about the known facts) a simple procedure for ensuring that the shear force diagram always complies(to act according to an order, set of rules or request) with our convention:

START AT THE RIGHT-HAND SIDE OF STRUCTURE AND FOLLOW THE DIRECTION OF EACH FORCE AS YOU WORK TOWARDS THE LEFT-HAND SIDE.

BEAM

A beam is a structural member subject to bending and is probably the most common structural element that designers have to cope with. Bending occurs in a member when a component of load is applied perpendicular to the member axis, and some distance from a support. Bending causes curvature of a member. Commonly, beams are horizontal, and load vertically downwards. Most beams span (=If a bridge spans a river, it goes from one side to the other) between two or more fixed points.
- A Simply supported beam
- A cantilever beam
- A simply supported beam with a cantilever end
- A continuous beam
The beam is made up of two flanges (a flat surface sticking out from an object, which is used to fix it to something or to make it stronger) and a web