Why would you need freshwater to go through a canal that connects two bodies of water? This seems like very poor planning and infrastructure creation. why can't they pump sea water through the locks?
Because the locks were built where they were over 100 years ago without the need for any pumps since there was an existing lake. The number of pumps, installation time, and power needed to run the locks (in both directions since the middle is at the top) would be huge. I could still happen, but take a decade to build out.
The vertical rise is about 26meters and there are 3 10meter locks (33mx300m in size) in each direction. 40 ships travel through each day (~3ksec per fill bidirectional) and each fill is ~1Billion liters or 250Million gallons in less than an hour. Lifting 1B liters through 30m would need 100MW to power 100% efficient pumps continuously for leakless locks. The solar/hydro power of rain is significant.
Also, everything in the lake would die once it was contaminated with sea water, and you would be contaminating the Pacific with Atlantic water, vice versa, or both.
Drake Passage doesn't pose the same ecological risk, of course because the ecosystems are acclimatized to such a passage being there, but also because it's in the southern ocean surrounded by strong currents and cold water that mostly does not mix with the Atlantic and Pacific oceans. So many of the species at higher latitudes are essentially trapped on their respective side.
Just to add some the last piece of data: According to https://www.global-climatescope.org/markets/pa/, Electricity prices in Panama (in 2021) were $153/MWh, so the costs for each fill would be about $15,300
That sounds like a lot until you realize the largest ships are charged up to $150,000 for a transit.
A 10% price increase is nothing to scoff at, but it's not outlandish to deal with congestion...
Remember that it's not a single lock ships go through. If I understand correctly, ships are lifted in 3 locks and lowered in another 3. That would make it $45k+.
But once you’re talking about anything near 100% efficient pumps, you can have generators too, and a lot of that water is, in principle, recoverable. A bigger issue may be doing any of this without bringing too much salt along with the upward-moving ships.
(Hmm. How about picking up the ships, sans water? I wonder if a way to do this safely could be engineered. Sounds quite challenging.)
Remember, that's 100% efficient continuous 100MW. Realistically, you're looking at 3-5x that for peak power. With the current 10m drop, the head is too low to have anything like an efficient generator. Even the full 86ft drop would be terribly inefficient at the flow rates required.
However, there are solutions to things like this called a "water slope" and one has been built (notably 100x smaller than needed for Panama) and they would (need to) be much quicker as well. Basically, they push a giant slug of water up hill. Notably, one could probably make this regenerative (and you could likely reuse most of the water). That's important since it would certainly be in the multiple GW of power, but it could push/pull (two moving locks up/dn) in <1000sec so traffic through the canal could be more than 5x higher. Of course it would require massive widening, completely new infrastructure (a new giant power plant), and completely new technology.
Here's video of one (and a link to the original) with an explanation. My point is not that this is easily doable, but if you're going to spend the many $10Bs of you might as well get more boats through.
Would it be practical to integrate pumped hydroelectric energy storage into a canal lock mechanism? Pump water up to lower the water level; harness water flowing back down for electricity; and arrange the timing partly towards grid supply & demand.
Maybe dig a third reservoir adjacent to the lock mechanism, as a buffer between the two levels, to give you more flexibility with the timings.
[late edit]: Apparently this is in fact a thing, in some cases:
- "The hydraulic cylinders enable the water used by the locks to be pumped back. Up to 48,000 cubic metres of water are displaced in a single lockage operation. In periods of low discharge on the Meuse, the screws can pump back the water lost due to the passage of a ship through the lock to the upper canal reach. In normal periods of enough discharge at the Meuse, the screws are used to to generate green electricity from hydropower."
It would require about 14 MWh to lift a single ship to the upper level
Calculating the approximate wattage to lift all that water 26m:
9.8 w/s * 200000000 Liters * 26 m /60/60/1000/1000
200 000 000 liters was reported on wikipedia as amount of water used.
Its a very crude calculation probably of by quite a bit.
It's allot of electricity but the cost of that electricity would be essentially nothing when compared to what they charge. So I don't know why they don't install massive pumps. Maybe they don't want to contaminate the lake with salt water, but you would get small amounts of salt water with the current system to.
I did it myself, it's about 10MW continuous assuming there are 40 ships each taking about 3000 seconds to traverse the locks. Each lock is ~30x330x10 cubic meters or 1Billion liters (conservatively).
A Watt is 1 meter(lift) x 1 Newton / second.
There are 30 meters of lift. Each liter is 1kg and gravity (9.8m/sec2) makes that about ~10 Newtons (9.8N due to gravity).
So you get 10^9kg x 10N/kg x 30m / 3000 sec = 100MW continuous. That's about 100, 000 horsepower. Each lock would need more than 16MW of pumping.
Solar/hydro power from the rain in lake Gatun is well over 100MW. Due to leakage it's probably 5-10x that or equivalent to a larger nuclear power plant.
Because those connecting fresh water bodies are higher than the sea. So the cheap solution is to fill progressively higher boxes with water from the fresh water, until you are at fresh water. And then do same thing in reverse.
Perfectly fine when you have enough fresh water, you can even somewhat optimize by using same water multiple times. But if you run out of fresh water at high point you will have trouble.
They could likely retrofit to do so but there'd be a lot of ecological concerns along with the infrastructure and energy cost of pumping billions of gallons of water from sea level.
Ecological concerns wouldn't just be pumping seawater into a large freshwater lake but questions of where to intake water, cross contact between the Atlantic and Pacific oceans there at a new location, etc. Not a trivial set of issues.
Speculation: You probably don't need it, but it could be a lot easier if the lake has some elevation (so you don't need to spend so much energy pumping), and being freshwater means less corrosion to contend with. And whatever the reasons, it was probably built like that way back when and retrofitting it now is, again, possible but hard/expensive.
It's much easier to use direct hydraulic power from inland upstream fresh water bodies. That's how most locks work, you just let gravity do the work. This is super basic technology that can still reliably move up million ton cargo ships.
Why would you need freshwater to go through a canal that connects two bodies of water? This seems like very poor planning and infrastructure creation. why can't they pump sea water through the locks?