I. Decide whether the following statements are true or false according to the text:

1. The primary materials used for bridges have been iron and concrete.

2. Prestressed concrete is made of sand, gravel and cement.

3. Though wood is weak in compression and tension it has been widely used because it is cheap.

4. As stone is strong in tension and weak in compression it has been used in arches and piers.

5. Cast iron was first used during the industrial revolution.

6. Steel is stronger, superior to any iron in both tension and compression.

7. Concrete is strong in tension and weak in compression.

8. As steel carries all the tension, reinforcement allows to use less concrete.

9. The holes for tendons are curved inside.

II. Answer the questions

1. What materials are used for bridges?

2. What are modern bridges built with?

3. Why was wood widely used in the construction of bridges?

4. When was iron first used?

5. What is the difference between cast iron and wrought iron?

6. What is concrete?

7. What is reinforced concrete?

8. What does post-tensioned prestressing involve?

9 What puts the beams into tension?

10 What makes bridges lighter and less expensive?

LANGUAGE FOCUS

III. Match the meaning of the terms with their definition.

Wood, concrete, stone, iron, steel

1 The hard, compact mineral material of which rocks are made up.

2 The hard, fibrous substance beneath the bark of trees and shrubs.

3 An alloy of iron and carbon.

4 A mixture of cement, sand, gravel and water that hardens as it dries.

5 The commonest and most useful metal, from which tools and machinery are made.

IV. Insert the words and translate the sentences.

Ductility, strength, steel, dactile, form, yield, cast iron, difference, tension, spans

Amongst bridge materials … has the highest and most favourable strength. It is therefore suitable for the most daring bridges with the longest … A special merit of steel is its … due to which it deforms considerably before it breaks, because it begins to … above a certain stress level. For bridges high … steel is often preferred. The higher the strength the smaller the proportional … between the yield strength and the tensile strength. This means that high strength steels are not as … as those with normal strength. For building purposes, steel is fabricated in the … of plates by means of rolling when red hot for bearings and some other items … is used for members under … only, like ropes or cables there are special steels

Old Wide Practical Mix Art Hard Build Depend

V. Fill the gaps with the suitable derivatives of the word given on the right.

One of the man’s … building materials is finding its way into a lot of new places these days. Concrete first discovered by the Romans, is now more … used in construction than all other materials together. Concrete is a synthetic stone which can be formed while soft into … any shape the builder wants. Portland cement … with water is the paste that binds sand, gravel, clinker into an … rock that becomes … as the years pass. It was called Portland because Joseph Aspolin, the English … who invented the first … scientifically made cement thought it resembled the rock excavated on the isle of Portland on the Dorset Coast.

VI. Read the passage and answer the question: Why does prestressing significantly reduce the amount of structural materials?

Often concrete is the main construction material in modern bridges. Reinforced concrete to which emplanted steel bars add strength, was introduced in 19^th century; its first significant application was in an arched bridge built in France in 1898. Engineers later learned to apply tension to the bars before pouring the concrete. This process called prestressing significantly reduces the amount of structural materials needed for a bridge. Prestressed concrete bridges often have a graceful look which cannot be achieved by iron and steel bridges with their geometric configurations.

Text 6: PERFORMANCE IN SERVICE

Bridges are designed, first, to carry their own permanent weight, or dead load; second, to carry traffic, or live loads; and, finally, to resist natural forces such as winds or earthquakes.

Live load and dead load. The primary function of a bridge is to carry traffic loads: heavy trucks, cars, and trains. Engineers must estimate the traffic loading. On short spans, it is possible that the maximum conceivable load will be achieved—that is to say, on spans of less than 100 feet (30 metres), four heavy trucks may cross at the same time, two in each direction. On longer spans of several thousand feet, the maximum conceivable load is such a remote possibility (imagine the Golden Gate Bridge with only heavy trucks crossing bumper-to-bumper in each direction at the same time) that the cost of designing for it is unreasonable. Therefore, engineers use probable loads a basis for design. In order to carry traffic, the structure must have some weight, and on short spans this dead load weight is usually less than the live loads. On longer spans, however, the dead load is greater than live loads, and, as spans get longer, it becomes more important to design forms that minimize dead load. In general, shorter spans are built with beams, hollow boxes, trusses, arches, and continuous versions of the same, while longer spans use cantilever, cable-stay, and suspension forms. As spans get longer, questions of shape, materials, and form become increasingly important. New forms have evolved to provide longer spans with more strength from less material. Forces of nature. Dead and live weight are essentially vertical loads, whereas forces from nature may be either vertical or horizontal. Wind causes two important loads, one called static and the other dynamic. Static wind load is the horizontal pressure that tries to push a bridge side­ways. Dynamic wind load gives rise to vertical motion, creating oscillations in any direction. Like the breaking of an overused violin string, oscillations are vibrations that can cause a bridge to fail. If a deck is thin and not properly shaped and supported, it may experience dangerous vertical or torsional (twisting) movements.

The expansion and contraction of bridge materials by heat and cold have been minimized by the use of expansion joints in the deck along with bearings at the abutments and at the tops of piers. Bearings allow the bridge to react to varying temperatures without causing detrimental stress to the material. In arches, engineers sometimes design hinges to reduce stresses caused by temperature movement.

Modern bridges must also withstand natural disasters such as hurricanes and earthquakes. In general, earth­quakes are best withstood by structures that carry as light a dead weight as possible, because the horizontal forces that arise from ground accelerations are proportional to the weight of the structure. (This phenomenon is explained by the fundamental Newtonian law of force equals mass times acceleration.) For hurricanes, it is generally best that the bridge be aerodynamically designed to have little solid material facing the winds, so that they may pass through or around the bridge without setting up dangerous oscillations.

COMPREHENSION CHECK