2025 Chicago Regional Bridge Building Specifications


These rules have been developed by the Chicago Regional Bridge Building Committee for the Forty-Ninth Chicago Regional Bridge Building Contest to be held on Tuesday, January 28, 2025, at Illinois Institute of Technology, Chicago IL 60616, USA. If you have a question about these rules, FIRST take a look at the list of Frequently Asked Questions (FAQ) to see if the answer is already there. If you have read the FAQ, and still have a question about the contest rules, then you may contact the Chief Judge, Jamal Grainawi at Jamal.grainawi@wsp.com. For questions on any contest topic EXCEPT the rules please contact Prof. Carlo Segre at segre@iit.edu.

The object of this contest is to see who can design, construct and test the most efficient bridge within the specifications. Model bridges are intended to be simplified versions of real-world bridges, which are designed to permit a load to travel across the entire bridge. In order to simplify the model bridge design process, the number of loading positions is reduced, and to allow the contest to proceed in a reasonable amount of time, only one loading position is actually tested. These simplifications do not negate the requirement that the bridge must be designed to accept a load at any of the positions. Bridges determined by the judges to not meet this requirement will be disqualified and tested as unofficial bridges.


1. Materials
  1. The bridge must be constructed only from 3/32 inch square cross-section basswood and any commonly available adhesive. Kits of basswood are available from the the IIT Office of Admissions, contact Margarita Fraga, fragam@iit.edu, for information.
  2. The basswood may be notched, cut, sanded or laminated in any manner but must still be identifiable as basswood.
  3. No other materials may be used. The bridge may not be stained, painted or coated in any fashion with any foreign substance.
2. Construction
  1. The bridge mass shall be no greater than 25.00 grams.
  2. The bridge (see Figure 1) must span a gap (S) of 300. mm, be no longer (L) than 400. mm, be no wider (W) than 80. mm, and be no taller (H) than 100. mm above the support surfaces. The bridge structure must extend below the support surfaces by no more (B) than 10. mm.
  3. The bridge shall contain an "arch-type" structure below the main support plane (see Figure 1) that spans between the supports. An arch uses curved members for its main load carrying members. For this contest, the arch shall be composed of either curved members or two or more straight segments arranged to approximate an A-frame or a multi-segmented frame. The arch element must make contact with the vertical faces of both support surfaces.
  4. The loading plane shall be horizontal and shall lie a distance (P) between 10. mm and 100. mm above the support surfaces.
  5. The bridge must be constructed to provide for the loading plate (see section 3 below) at each of the two loading points 20. mm and 40. mm on either side of the center of the 300.  mm span along the longitudinal axis of the bridge.
3. Loading
  1. The load will be applied downward, from below, by means of a 40. mm square plate (see Figure 2). The plate will have a thickness (t) of at least 6 mm but less than 13 mm and will have an up to 9.53 mm (3/8 inch) diameter threaded rod attached from below at its center with a standard hex nut. The plate will be horizontal with two sides parallel to the longitudinal axis of the bridge.
  2. The load will be applied on the longitudinal axis of the bridge at one of two loading points: 20. mm and 40. mm on either side of the center of the 300.  mm span.
  3. On the day of the competition, the judges will randomly decide which of the two loading positions will be used; it will be the same for all bridges.
4. Testing
  1. On the day of the competition, contestants will place their bridge on the testing machine support surfaces, adjusting them to ensure contact with the downward projecting portions of the bridge and with threaded rod projecting from below at the designated loading position.
  2. The loading plate will be placed from above on the threaded rod with two sides parallel to the longitudinal axis of the bridge and secured with a hex nut.
  3. The load will be applied from below, with the contestant rotating the Vernier testing machine load wheel until bridge failure is sensed (see 4d). Competition loading will stop at 50. kg.
  4. Bridge failure is defined as the inability of the bridge to carry additional load as sensed by the Vernier testing machine.
  5. The bridge with the highest structural efficiency, E, will be declared the winner. Bridges failing above 50. kg will be considered to have held 50. kg for efficiency calculation.

E = Load supported in grams (50,000g maximum) / Mass of bridge in grams

5. Qualification
  1. All construction and material requirements will be checked prior to testing. Bridges failing to meet these requirements will be disqualified. If physically possible, disqualified bridges may be tested as exhibition bridges at the discretion of the builder and the contest directors.
  2. If, during testing, a condition becomes apparent (i.e., use of ineligible materials, inability to support the loading plate, bridge optimized for a single loading point, etc.) which is a violation of the rules or prevents testing as described above in Section 4, that bridge shall be disqualified.
  3. Decisions of the judges are final; these rules may be revised as experience shows the need. Please check our web site, http://bridgecontest.phys.iit.edu after January 9, 2025, to learn whether any changes have been made.



Last update: October 1, 2024
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For further information, contact: Prof. Carlo Segre - segre@iit.edu, Illinois Institute of Technology
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