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[[Image:BalsaBridge Break.jpg|thumb|right|A balsa bridge breaks after holding a [[mass]] of 89 pounds (40.4 kg). Note that the [[failure]] of the entire [[bridge]] was a result of the failure of just the [[roadway]].]]
[[Image:BalsaBridge Break.jpg|thumb|right|A balsa bridge breaks after holding a [[mass]] of 89 pounds (40.4 kg). Note that the [[failure]] of the entire [[bridge]] was a result of the failure of just the [[roadway]].]]


==Testing==
==Testing the poo will make it stronger
Bridges are usually tested by applying a downward force on the bridge. How and where the [[force]] is applied varies from one contest to the next. There are two common methods of applying the test force to the bridge:
Bridges are usually tested by applying a downward force on the bridge. How and where the [[force]] is applied varies from one contest to the next. There are two common methods of applying the test force to the bridge:
*By hanging a container (such as a [[trash can]]) from the bridge and loading known weights into the container until the bridge breaks. The tester could also slowly add water or sand to the container until the bridge breaks and then weigh the container, providing a more accurate way to find the breaking force.
*By hanging a container (such as a [[trash can]]) from the bridge and loading known weights into the container until the bridge breaks. The tester could also slowly add water or sand to the container until the bridge breaks and then weigh the container, providing a more accurate way to find the breaking force.

Revision as of 23:54, 10 October 2011

The big poo Although there is great ass in the pants variety between different balsa wood bridge projects, students are in general trying to build a big looking bridge that withstands the greatest force before it fails. Other restrictions are often applied, but these vary widely from one contest to another. Sample requirements include:

  • restricting the maximum mass of the bridge
  • requiring a minimum span
  • requiring a minimum height of the roadway
  • restricting the physical dimensions of the bridge
  • restricting the size of individual pieces of balsa wood
  • limiting the amount of glue or balsa wood that can be used
  • requiring a driveable roadway that allows passage of a vehicle of specified size
  • restricting the way pieces are placed on the bridge (for example no parallel joining pieces)
A balsa bridge breaks after holding a mass of 89 pounds (40.4 kg). Note that the failure of the entire bridge was a result of the failure of just the roadway.

==Testing the poo will make it stronger Bridges are usually tested by applying a downward force on the bridge. How and where the force is applied varies from one contest to the next. There are two common methods of applying the test force to the bridge:

  • By hanging a container (such as a trash can) from the bridge and loading known weights into the container until the bridge breaks. The tester could also slowly add water or sand to the container until the bridge breaks and then weigh the container, providing a more accurate way to find the breaking force.
  • By using a mechanical or pneumatic testing device that pushes down on the bridge with increasing force until the bridge breaks. If such a testing device is used it is often equipped with a method of automatically gathering force data, such as a pressure sensor or load cell connected to a computer. This approach is more accurate at measuring bridges that have secondary structure that proves to be stronger than the primary structure. This method is also less damaging to the bridge, whose structure usually remains intact since the load is automatically relieved at failure.

Of the two, the hanging container method provides by far the greater dramatic impact. Testing with a pneumatic press or ram is often complete in matter of seconds. Exceptionally strong bridges may take up the to thirty minutes to test as weight (a combination of steel weights and sand is often used) is added to the suspended container.

Scoring and Grading

Scoring

There are two chief ways that balsa wood bridge competitions may be scored. One way is simply by measuring how much weight each bridge can support. The second way is by structural efficiency, often expressed as a strength to weight ratio. The weight-only method is most effective where competitors are all building from a specified set of materials and are expected to use all the available materials. The strength-to-weight method is better when competitors are expected to use their materials as efficiently as possible.

Competitive Grading

Competitive grading compares how well each bridge does against bridges built by other participants to determine a grade. The top scoring bridge is assigned a maximum numeric grade (say, 100%) while the lowest scoring bridge that still meets all basic specifications is assigned a minimum grade (say, 70%).[1]

The method guarantee that some scores will be high even if the overall quality of bridges is low. Conversely, it also guarantees that some scores will be low, even in situations where all bridges are of high quality.

Standards-Based Grading

Standards-based grading sets certain standards that need to be met in order to earn a certain grade. An example of standards-based scoring would be to say that all bridges that hold 50 kg earn full credit; bridges that hold 25 kg earn half credit, and bridges that hold less than 10 kg earn no credit.

This method allows every bridge to potentially earn full credit if the standards are met. In situations where competition is weak, this method runs the risk of having many competitors receive no credit.

See also

References

  • Barron, B. J., Schwartz, D. L., Vye, N. J., Moore, A., Petrosino, A., Zech, L., et al. (1998). Doing with understanding: Lessons from research on problem- and project-based learning. The Journal of the Learning Sciences, 7, 271–311.
  • Dods, R. F. (1997). An action research study of the effectiveness of problem-based learning in promoting the acquisition and retention of knowledge. Journal for the Education of the Gifted, 20(4), 423–437.
  • Schneider, R. M., Krajcik, J., Marx, R., & Soloway, E. (2002). Performance of students in project-based science classrooms on a national measure of science achievement. Journal of Research in Science Teaching, 39(5), 410–422.