The Goodheart-Willcox Co., Inc. Tinley Park, Illinois Shaping Our World Technology: PowerPoint...

The Goodheart-Willcox Co., Inc.Tinley Park, Illinois

Shaping Our World

Technology:

PowerPoint Presentations for

6Structures

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Objectives

• Recognize many different types of structures, both natural ones and those made by humans.

• Recall that structures made by humans include bridges, buildings, dams, harbors, roads, towers, and tunnels.

• Identify the loads acting on structures.

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Objectives

• Analyze the forces acting on a structure.

• Demonstrate how structures can be designed to withstand loads.

• Design and make a product that incorporates structural principles.

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Introduction

• Structures are all around us.• We build them to live in or to cross a river.• We build them to carry wires, to receive

radio waves, and to transport people.• Houses, bridges, and towers are not the

only structures; airplanes, boats, and cars are structures, too.

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Introduction

• The main purpose of a structure is to enclose and define a space.

• At times, however, a structure is built to connect two points. This is the case with bridges and elevators.

• Other structures are meant to hold back natural forces, as in the case of dams and retaining walls.

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Introduction

• Living organisms, such as trees and our bodies, are natural structures.

• A giant redwood tree must be rigid enough to carry its own weight. Yet it is able to sway in high winds.

• Grass is flexible, because it springs back after it is stepped on.

• The bones of a skeleton have movable joints.

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Discussion

What structures have you built? What was their intended purpose? What materials and tools did you use?

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Commonalities

• What do all structures have in common?– They all have a number of parts, which are

connected.– The parts provide support so the structures

can serve their purpose.– One important job of all structures is to

support a load.

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Activity

1. Make a list of three animals.

2. Make an illustrated poster showing the structures they create.

3. Include the materials used to build each.

What is the purpose of each structure?

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Loads

• Bridges support vehicles.

• Vehicles support passengers.

• Both also support the materials from which they are built.

(Ford, Ecritek)

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Types of Structures

• Structures vary greatly in size and type.• All structures must be able

to support a load without collapsing.

http://www.skyscraperpage.com/© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

(Ecritek, TEC)

Static Loads

• Static loads may be caused by the weight of the structure itself.

• They are also caused by objects placed in or on the structure.

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Dynamic Loads

• The mass of a person walking across the floor creates a dynamic load.

• Other dynamic loads include the force of a gust of wind pushing against a tall building and a truck crossing a bridge.

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Compression and Tension

• Bending causes compression and tension stress.

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Minimize Bending

• The design and construction of structures must minimize the effects of bending.

• Parts must be shaped so the forces of tension and compression are balanced.

• These energies are then said to be in a state of equilibrium, and there is little chance to bend.

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Discussion

What geometric shapes can you identify in structures? Which geometric shape

appears more often than others?

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Withstanding Loads

What shape appears most often?

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(TEC)

Withstanding Loads

• The top and bottom surfaces of a beam are subject to the greatest compression and tension.

• After members have been shaped to resist compression and tension, they must be connected in a way that minimizes bending.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

The Importance of Triangles

• The frame in the figure is made of four connected members. If a load is applied at A, the frame retains shape.

• However, if a load is applied at a corner, the frame will collapse.

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The Importance of Triangles

• A rigid diagonal member (from corner to corner) has been added.

• The frame now retains its shape when a load is applied at the corners.

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Tie and Strut

• At corner B, the load causes the diagonal to be in tension. A rigid member in tension is called a tie.

• When the load is applied at corner C, the diagonal is in compression. It is a strut.

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Shear

• A third force acting on structures is called shear.

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Bending Bridges

• A major problem with bridges is that they bend.

• One common way to prevent a beam bridge from bending is to support the center with a pier.

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Piers

• Piers may not allow the passage of ships.

• Sometimes the river is too deep, runs too swiftly, or has a soft bed with no firm foundation.

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Other Solutions

• Making the beam thicker would cause it to sag from its own weight.

• The beam could be strengthened in the middle.

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Simple Trusses

• Truss bridges make use of the triangle in their design.

• The mass of a truck crossing causes the bridge roadway to bend. Member “A” moves down. This pulls down on “B” and “C,” pulling them toward the end of the bridge.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

Trusses

• Most truss bridges are more complex than the simple truss.

• Many triangular frames are used to construct them.

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Stays

• Stays are cables that provide support from above.

• Notice that the pylons are in compression and the stays are in tension.

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Suspension Bridges

• The bridge deck is suspended from hangers attached to a continuous cable.

• Cables secured to the ground transfer mass from the deck to the top of the towers.

• Compression transfers the mass to the ground.

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Other Bridges

• There are many other types of bridges.

• Their design follows the same general principle: try to reduce bending.

• Two of the most common types are arch bridges and cantilever bridges.

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Arch Bridges

• Mass is transferred outward along two curving paths.

• The supports where the arch meets the ground are called abutments.

• They resist outward thrust and keep the bridge up.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

(Ecritek)

Cantilever Bridges

• A beam can support a load at one end provided that the opposite end is anchored or fixed.

• A cantilever bridge has two cantilevers with a short beam to complete the span.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

(Ecritek)

Steel and Concrete

• The most common bridge materials are steel and concrete.

• Steel is fairly inexpensive, strong under compression and tension, but needs maintenance to prevent corrosion.

• Concrete is economical and resists fire and corrosion but is weak under tension.

• It can be strengthened with steel rods.

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Steel

• Steel cables made of wire rope are used to support the mass of the roadway and the traffic load on it.

• The towers of many bridges are made of steel.

• Steel trusses give rigidity to the bridge deck.

• They also resist bending.

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Reinforced Concrete

• To overcome the weakness of concrete, it is reinforced with steel rods wherever it is in tension.

• Reinforced concrete is used in many bridges.

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Activity

1. Go to http://www.pbs.org/

2. Search for “Building Big.”

3. Click on “Bridges.”

4. Click on “The Bridge Challenge.”

5. Do one of the bridge challenges and write a page on a real-life bridge that would work like the one in the activity.

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Review

Both skeletal systems and scaffolds are ________.

structures

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Review

Name some man-made structures.

Bridges, buildings, dams, harbors, roads, towers, tunnels, airplanes, boats, and cars.

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Review

List and explain the two types of loads.

Static loads are unchanging or slow changing.

Dynamic loads are always moving and changing.

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Review

Explain the three forces that act on structures.

Tension stretches out a structure.

Compression squeezes the structure.

Shear includes parallel and opposite sliding motions.

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Review

Name one way to prevent a bridge from bending.

Support the center with a pier.

Strengthen the beam at the middle.

Use trusses.

Use cables to distribute the load.

Use arches and abutments.

Apply the principle of a cantilever.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

Review

Why are steel rods used to reinforce concrete?

Steel rods can resist tension, unlike concrete.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

End of Chapter 6

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Glossary

• Abutments– The supports where a bridge arch meets the

ground; they resist the outward thrust (push) and keep the bridge up.

• Arch bridge– A type of bridge in which the compressive

stress created by the load is spread over the arch as a whole.

• Cantilever bridge– A type of bridge in which a beam is capable of

supporting a load at one end when the opposite end is anchored or fixed.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

Glossary

• Compression– A squeezing force.

• Dynamic load– A load on a structure that is always changing.

• Load– The weight, mass, or force placed on a structure.

• Pier– A structure used to support the center of a

bridge. © Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

Glossary

• Reinforced concrete– Concrete in which steel rods have been embedded

to increase the concrete’s resistance to tension.

• Shear– A multidirectional sliding and separating force.

• Static load– A load that is unchanging or changes slowly.

• Stays– Cables that support a bridge deck from above.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

Glossary

• Structure– Something that encloses and defines a space; also,

an assembly of separate parts that is capable of supporting a load.

• Strut– A rigid structural member that is in compression.

• Suspension bridge– A bridge in which the deck is suspended (hung)

from hangers attached to a continuous cable, which passes over towers and is anchored to the ground at each end.

© Goodheart-Willcox Co., Inc. Permission granted to reproduce for educational use only.

Glossary

• Tension– A pulling force.

• Tie– A rigid structural member that is in tension.

• Truss– A structural element made up of a series of

triangular frames.

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