Activity 2.1.1 Aerospace Materials Investigation
Tyler SalleeActivity 2.1.1 Aerospace Materials InvestigationIntroductionWithin aerospace design, material selection has a large impact on overall design performance as well as production and maintenance costs. Aerospace designers and developers must always be aware of the impact that material selection has on design specifications ranging from propulsion requirements to environmental factors.In this activity you will investigate properties of materials in several categories. Within each category you will consider the suitability of the materials in aerospace applications. EquipmentComputer with Internet accessEngineering notebookPencilProcedureOpen the PBS Forces Lab at the following link : the Forces tab along the top.Click Squeezing option. Click and drag the slider and observe the effect on the material.Observe images by clicking See It In Real Life.Repeat this exploration for each force and use what you learned to complete the following table.ForcesEngineering term(look above the block)Definition(in your own words)Two examples of how this force can affect airplanes (your ideas)SqueezingCompressionForce that shrinks an objectGravity squeezes it before takeoffThe wheels are compressed before takeoffStretchingTensionForce that enlarges an objectDrag creates tensionLift and gravity create tensionBendingBendingForce that makes a straight object curvedDrag bends the wings backLift vs. gravity bend the wingsSlidingShearForce that causes one part to Slide past anotherThe engine want to shear offThe cargo try to shear through the bottomTwistingTorsionForce that bends an object two or more directionsThe wind will bend it a different direction than gravityLift will pull different from windNow that you understand forces, let’s observe various materials used in aerospace applications. Click on the tab labeled Materials.MetalsClick on each material shown below and move the slider until the material cracks. Use the tick marks on the scale to assign a number to the force, cost and weight. Record this number on the following table. Move the slides completely to the maximum to see a message about the material. Complete the table below using what you learn.Type of MaterialStrength in Tension (Stretching)Strength in Compression (Squeezing)CostWeightPros and ConsApplicationsAluminum4493Pros: Light, no rust, strongCons; ExpensiveWings, boats, cars, skyscrapersSteel43.579Pros:strongCons: rust, not temperature resistantCables, trusses, beams, columnsBased on your results, in which loading condition (tension or compression) are metals strongest?CompressionEven though steel is an exceptionally strong metal, why wouldn’t it be a good choice for use inside jet engines?It doesn’t preform well in high temperaturesPolymersClick on the material shown below and move the slider until the material cracks. Use the tick marks on the scale to assign a number to the force, cost and weight. Record this number on the following table. Move the slides completely to the maximum to see a message about the material. Complete the table below using what you learn.Type of MaterialStrength in Tension (Stretching)Strength in Compression (Squeezing)CostWeightPros and ConsApplicationsPlastic4491.5Pros: Flexible, lightweight, long-lasting, stoneCons: expensiveUmbrellas, inflatable roofsAs noted in the investigation, plastics are strong and very light, both of which are desirable characteristics to engineers. However, watch carefully as you apply tension and compression to the plastic. Note how it behaves. Based on your observations, would plastic be a suitable alternative to aluminum for airplanes, or steel for buildings? Why or why not?No, it has a higher elasticity, it bends far moreCeramicsClick on the material shown below and move the slider until the material cracks. Use the tick marks on the scale to assign a number to the force, cost and weight. Record this number on the following table. Move the slides completely to the maximum to see a message about the material. Complete the table below using what you learn.Type of MaterialStrength in Tension (Stretching)Strength in Compression (Squeezing)CostWeightPros and ConsApplicationsBrick1.542.14Pros: cheap, strong (compressionCons: Heavy, weak (tension)Walls, domesBased on your observations, in which method of loading (tension or compression) are ceramics strongest? In your opinion, why do you think ceramics behave this way? Compression, there is more air in the object to be pushed out, but it increases cracks made by tensionSince ceramics can be so strong (and relatively inexpensive), why aren’t they used to make aircraft or other transportation machines? Why do we only seem them used in buildings or structures?They do not take tension wellWhy wouldn’t brick be used to make the cables which hold up a suspension bridge?Cables rely on tensionCompositesClick on each material shown below and move the slider until the material cracks. Use the tick marks on the scale to assign a number to the force, cost and weight. Record this number on the following table. Move the slides completely to the maximum to see a message about the material. Complete the table below using what you learn.Type of MaterialStrength in Tension (Stretching)Strength in Compression (Squeezing)CostWeightPros and ConsApplicationsWood2.532.11Pros: Cheap light, moderately strongCons: Rot, swells, burnsBridges, houses, roller coastersReinforced Concrete444.56Pro’s: cheap, fireproof, weatherproof, molds, strongCons: Can crack as it coolsBridges, Dams, Domes, Beams, columnsNote the arrangement of the steel rods in the reinforced concrete and the fibers of the wood. Why were these materials strongest pulled along the rods and fibers?Because those are what hold them togetherIn your opinion, what would have happened if we would have pulled on the wood/reinforced concrete from the top and bottom instead of the sides? Why?They would break into segments based on where the rods, or fibers wereClick on the unreinforced concrete and perform a tension/compression test. How does adding the steel rods improve the strength of the concrete (and in which mode, tension or compression)? Explain.It gives something for the concrete to hold onto.As noted in the investigation, wood and reinforced concrete are relatively strong and inexpensive. Why don’t we use these particular composite materials to construct aircraft or other transportation vehicles?Wood is not nearly as strong, and concrete cracks in forming.The PBS Forces Lab is a resource designed to show qualitative comparisons between broad material categories. Engineers need accurate material properties to design safe and predictable products. These material properties were measured using stringent testing standards. These properties are published in sources for reference such as MatWeb . Use this site or a similar site to find properties of the materials shown below.MaterialDensity or Specific GravityTensile Strength(Yield)Elongation at Break(if available)Steel(AISI Type S14800 Stainless Steel condition A)8.05 g/cm30.290824700707875lb/in358,000–80,000 psi19.44%Aluminum(6061-T8)0.0975 lb/in?>= 67000 psi14%Plastic(PVC, Extruded)0.0198 lb/in?7,3005%Wood(American Sitka Spruce)0.0112 lb/in?40Based on the information from the table rank the material for selection for an aircraft material choice for best strength to weight ratio. Use density as a substitute for weight. Show calculations.0.290824700707875lb/in3/80,000 psi=3.6*10^-60.0975 lb/in?/67000 psi=1*10^-60.0198 lb/in?/7,300=3*10^-60.0112 lb/in?/40=2.8*10^-4ConclusionWhat role does material selection have in aerospace design?If inadequate materials are chosen, the plane will not last long.Why would an aerospace designer specify an inferior material compared to other materials if both materials meet the design specifications?Because the inferior material has a lower cost. ................
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