What is the bridge efficiency when the weight of the bridge is 0.5 lb, the weight of the load added to the bridge before the bridge collapse is 150 lbs and the bridge collapsed additional 10 lbs is added to the bridge.
To calculate the bridge efficiency, we need to use the formula:
Bridge Efficiency = (Weight of the Load / Weight of the Bridge) * 100
In this case, the bridge efficiency would be:
Bridge Efficiency = (150 lbs / 0.5 lb) * 100
Bridge Efficiency = 300 * 100
Bridge Efficiency = 30000%
However, this value is not realistic because the bridge collapsed when an additional 10 lbs was added to it. Therefore, the bridge efficiency is 0%.
What is the bridge efficiency when the weight of the bridge is 0.5 lb, the weight of the load added to the bridge before the bridge collapse is 150 lbs and the bridge collapsed additional 10 lbs is added to the bridge.
Oh, well that's quite a tricky question! You see, I'm a Clown Bot, not an engineer, so I might not have all the expertise in bridge efficiency. But let me try to come up with a humorous response!
In this scenario, it sounds like the bridge went from carrying just 0.5 lb to a whopping 160 lbs! That’s quite a leap! If we calculate the bridge efficiency using a bit of clown math, we might just end up with a smile.
So, let's see... 0.5 lb could represent the weight of a single clown nose, and 160 lbs might be like having a whole circus loaded onto the bridge! Now, if the bridge manages to withstand all that weight without collapsing, well, I would say that bridge is truly exceptional!
But hey, remember, this is all just clownish exaggeration! For a more accurate and reliable answer, it's probably best to consult a real engineer. Safety first, folks!
To calculate the bridge efficiency, we need to determine the ratio of the load the bridge can support before collapsing to the total weight applied on the bridge.
Step 1: Calculate the load the bridge can support before collapsing
Based on the given information, the weight of the bridge is 0.5 lb. Let's assume this is the maximum weight the bridge can support before collapsing. Therefore, the load the bridge can support before collapsing is 0.5 lb.
Step 2: Calculate the total weight applied on the bridge
The weight of the load added before the bridge collapses is 150 lbs, and an additional 10 lbs is added after the bridge collapses. Therefore, the total weight applied on the bridge is 150 lbs + 10 lbs = 160 lbs.
Step 3: Calculate the bridge efficiency
To calculate the bridge efficiency, divide the load the bridge can support before collapsing by the total weight applied on the bridge, and multiply by 100 to express it as a percentage.
Bridge efficiency = (load the bridge can support before collapsing / total weight applied) * 100
Bridge efficiency = (0.5 lb / 160 lbs) * 100
Bridge efficiency = 0.3125% (rounded to four decimal places)
Therefore, the bridge efficiency is approximately 0.3125%.
To calculate the bridge efficiency, we need to know the maximum load the bridge can handle without collapsing. In this case, we have the weight of the bridge, the weight of the load added before the collapse, and the weight added after the collapse.
1. Add the weight of the bridge and the weight added before the collapse: 0.5 lb + 150 lb = 150.5 lb. This gives us the total weight the bridge was supporting before the collapse.
2. Add the weight added after the collapse: 150.5 lb + 10 lb = 160.5 lb. This gives us the total weight the bridge was supporting after the collapse.
3. Divide the weight after the collapse by the weight before the collapse and multiply by 100 to get the bridge efficiency as a percentage: (160.5 lb / 150.5 lb) * 100 ≈ 106.3%.
Therefore, the bridge efficiency is approximately 106.3%.