Bridge Design Project

a) Description

You will design and build a bridge constructed from balsa wood according to the

contest rules listed below. A competition will be held during which the bridges will be tested and judged according to the criteria listed below. Your grade for this part of the course (20% of the total course grade) will be determined by the performance of your bridge.

b) Contest Rules

You will construct your bridge from the following cross sectional sizes of balsa wood:

1/16”, 3/32”, 1/8”, 3/16” and 1/4” square. The joints connecting these balsa members

will be made with five minute epoxy. Glue may only be applied at the joints. Do not use

glue as a structural member of your bridge.

The bridge shall be free-standing (not attached to the loading stand in any way), and

must span a distance greater than 1.0 m between two level surfaces, which are 1.0 m

apart. Support for the bridge shall be from the top of the level surfaces, and their edges

may not be used for support in any way.

ACCEPTABLE

(stand provides only

vertical support)

UNACCEPTABLE

(stand is providing

horizontal support)

The mass (weight) of the bridge shall not exceed 750 grams including the loading

platform and U-bolt.

The maximum vertical depth, from the highest to the lowest point in the structure, shall

not exceed 0.5 m.

The bridge must include a decking of balsa to provide a suitable road surface at least

50.0 mm wide across the full span of the bridge.

The following three conditions must be met:

· Gaps in the bridge deck are not to exceed 2 mm.

· A toy car, which will be supplied by Dr. Hoffman, must be able to pass across the bridge unobstructed from end to end.

· All parts of the unloaded bridge deck must be within 3 cm of a line drawn between the ends of the bridge deck (i.e. deck must go straight across).

An official “loading platform” made of 1/4 inch fibreboard with a metal hook attached,

must be obtained from Dr. Hoffman. The loading platform must be located at the center of the bridge, at the same level as the bridge deck. The loading platform cannot be altered

in any way.

Any bridge structure below the loading platform shall not exceed a depth of 5 cm.

To provide for attaching loads to the bridge, a loading platform must be part of the

structure. The only contact between the load and the bridge shall be at the U-bolt. To

facilitate attaching the loads to the bridge, there must be clear area around the loading

U-bolt of approximately 4 cm x 4 cm square.

All bridges will be weighed. No work can be done on the bridge in the competition area,

but a repair area will be provided in the vicinity. Any bridge that is worked on must be

re-weighed before the competition. No repairs or modification will be allowed after the

competition begins. All bridges will be inspected to insure that all contestants have met

with the bridge building rules. Non-complying bridges will be disqualified at this point.

All bridges will be placed on two level, smooth topped platforms with an open space of

1.0 m between them. The owner of a bridge will be responsible for positioning of the

bridge and removal after testing in a reasonable amount of time.

The magnitude of the load for each cycle of loading will be established by the judges.

The loading shall be for a ten second period as determined by an official timekeeper.

Bridges may not be touched while loaded.

The maximum load may be considered to have been reached when displacement of the bridge deck reaches 1/2 inch, or when the bridge fails, at the choice of the bridge owner.

c) Judging Criteria

The following scheme will be used to determine the points awarded (subjectively by Dr. Hoffman) for your bridge design.

1. Aesthetic Qualities (20%) – Completely subjective rating based on the feelings

of the judging panel.

2. Economics (20%) – How economical is this design? A total cost will be

awarded for the bridge design as follows:

a. Materials cost – the cost of all the raw materials used in your bridge design. This is calculated by (1) determining the total mass of the bridge, and (2) multiplying by $1 for each gram .

b. Connection cost – this accounts for the labor costs associated with your bridge design. It will be calculated by (1) determining the total number of joints in your bridge and (2) multiplying by $1 for each joint.

3. Accuracy of predictions (20%) – before your bridge is tested, you will be

required to disclose your predictions for (1) the total weight that your bridge

will support before breaking, and (2) where you predict it will break.

4. Brute Strength (20%) – ranked in order of total bridge strength.

5. Formal Presentation (20%) – your formal PowerPoint presentation should include explanation of (1) how you made decisions about your design (in terms of each of the criteria listed above), and (2) the technical analysis. You must also be prepared to answer questions from your classmates.