 # Efficiency Score

To help clear up any confusion when I talk about the “efficiency” or “efficiency score” of the bridges I build. This is a mathematical equation to determine how well a bridge performed.

Simply take the mass that the bridge held, and divide that by the mass of the bridge.

Mass held
________ = Efficiency

Mass of bridge

Some confusion comes up when I weigh the bridge in grams while add weight to the bridge in pounds. These units do not have the same base, and cannot be divided against each other. I usually convert pounds to kilograms (1kg = 2.2 pounds) and then multiply the number of kilograms by 1000 to get grams.

So if my bridge held 54 pounds, I would convert that to kilograms. 54 pounds equals 24.54 kilograms. That equals 24540 grams.

To get the efficiency, I take 24540 and divide that by the mass of the bridge, which was, say, 33 grams. The efficiency score is then 744.

### 5 thoughts on “Efficiency Score”

1. Let me know if I got anything wrong. This is something I came up with to take span length into account with looking at efficiency.

The length of the bridge affects the efficiency score of the bridge in two ways.
(1) The mass of the bridge increases with span length.
(2) The force applied to structural elements per unit loaded mass increases with span length.

First, let’s change the Efficiency Score from measuring the Absolute Efficiency to the Relative Efficiency of a bridge.

Then let’s fix the Relative Efficiency Score of a bridge to be tested against a Reference Bridge.

For each bridge, we need to know its span, mass, and maximum load mass.

Let’s call these S, M, and L for the Reference Bridge, and s,m, and l for the tested bridge.

We want the Efficiency Score of a Tested Bridge to increase as the mass decreases and the maximum load mass increases, and to increase with span. That is to say:

Absolute Efficiency Score ∝ 1/mass,
Absolute Efficiency Score ∝ maximum load mass,
Absolute Efficiency Score ∝ span, and
Relative Efficiency Score = absolute efficiency score tested bridge / absolute efficiency score reference bridge.

Therefore,

Absolute Efficency Score ∝ (maximum load mass) * span/mass
Relative Efficency Score = Mls / mLS
= ls/(350 m)

Let’s use a solid wooden beam with dimensions 3.66cm x 3.66cm x 1m, with mass 1kg, and maximum loading mass 350kg as the Reference Bridge.

Then, Efficency Score = ls/(350 m).

Now, let’s try examining two bridges with our new formula:

(All numbers are rounded to two significant figures.)

Since both bridges were Science Olympiad, we know that the span of the bridges is between 0.35m and 0.45m.

The Balsa Bridge’s mass 0.0081kg and the Rising Starr Bridge’s mass was 11g.

The Balsa Bridge’s maximum load mass was 13kg, and the Rising Starr Bridge’s maximum load mass was 15kg.

Thus,
13(0.35)/(350*0.0081) ≤ Balsa Bridge Relative Efficiency Score ≤ 13(0.45)/(350*0.0081)
15(0.35)/(350*0.011) ≤ Rising Starr Bridge Relative Efficiency Score ≤ 15(0.45)/(350*0.011)

Which is
1.6 ≤ Balsa Bridge Relative Efficiency Score ≤ 2.1
1.4 ≤ Rising Starr Bridge Relative Efficiency Score ≤ 1.8

2. how do you find the mass of a bridge

3. Just wondering, wouldn’t the span of the bridge have some bearing on the efficiency score of a bridge? ie if the bridge spanned a great distance, but wasnt as strong (but was strong enough) as a solid bridge of more mass which spanned a small distance, how would you compare them?

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