Use solar power for desalination. It is very easy and, with some engineering work, I expect it could be made economical.
I learned to do this in the boy scouts: dug a hole, piss in the hole, put a cup in the bottom of the hole, cover the hole with a sheet of clear plastic then weight down the center of the plastic with a small stone.
The air inside the hole/plastic container will be quite a lot warmer than the outside air. Eventually water droplets will condense on the underside of the plastic then run down the slope and drip into the cup.
I can think of all kinds of ways to scale this up to industrial capacity.
Much of California is either desert or quite arid, but much of the arid area is right next to the ocean.
To replace that water with desal would require 7E9 sq meters or 7 379 sq. km or 2849 sq. miles, or about 4x the size of the L.A. metro area. Assuming I didn't drop a few powers of 10.
There isn't the space for that in L.A. There's also pumping costs to get sea water up and through the desal system.
Reverse osmosis seems to be the way that everyone is going. Including indirect RO through solar power. Power is a lot easier to move around than water.
I expect there are ways I can improve upon that though. Note that there are lots of inefficiencies in the method I described, such as the resulting fresh water being hot.
Perhaps with the use of a heat exchanger to recover the waste heat...
- The system is inefficient for how much work is put into it versus the water output
- it is advised to make a solar still to supplement another water source, such as a reverse-osmosis unit or water purification tablets
- Similar sea water stills are included in some life raft survival kits, though manual reverse osmosis desalinators have mostly replaced them
This is a well-studied problem. The question isn't if you can improve on the design in the Boy Scout Handbook, but if you can improve upon the current state of the art.
> In order to evaporate 1 kg of water at a temperature of 30°C about 2.4 × 106 J is required. Assuming an insolation of 250 W/m2, averaged over 24 h, this energy could evaporate a maximum of 9 L/m2/day. In practice heat losses will occur and the average daily yield which might be expected from a solar still is 4–5 L/m2/day. Today’s state-of-the-art single-effect solar stills have an efficiency of about 30–40% [25].
You mentioned a heat exchanger. That paper goes on to say:
> Multiple-effect basin stills have two or more compartments. The condensing surface of the lower compartment is the floor of the upper compartment. The heat given off by the condensing vapor provides energy to vaporize the feed water above. Multiple-effect solar desalination systems are more productive than single effect systems due to the reuse of latent heat of condensation. The increase in efficiency, though, must be balanced against the increase in capital and operating costs. Efficiency is therefore greater than for a single- basin still typically being 35% or more but the cost and complexity are correspondingly higher.
The simulated maximum for a proposed system for this seems to be 25 L/m2/day, which is 8x better than the numbers I used. I don't know if it's been tested.
However, that paper then describes indirect solar desalination were more effective. This includes a real-world desal plant running at 6–13 L/m2/day and a simulated maximum for a proposed system of 25L/m2/day.
Hence, indirect solar seems to be the way to go, and not a direct solar still like you propose. The solar collectors can be placed on cheap land, and brought to the desal plants by the ocean edge.
All of these information is available through a web search. There's little need to handwave.
Yeah, much of the "high cost of desalination" problem is "high energy cost" problem.
Much of the industrial solar capacity will come from gigawatt plants that utilities themselves are building - while small distributed systems are nice, eventually economies of scale play out better https://gigaom.com/2015/01/20/a-special-report-the-rise-of-a...
I learned to do this in the boy scouts: dug a hole, piss in the hole, put a cup in the bottom of the hole, cover the hole with a sheet of clear plastic then weight down the center of the plastic with a small stone.
The air inside the hole/plastic container will be quite a lot warmer than the outside air. Eventually water droplets will condense on the underside of the plastic then run down the slope and drip into the cup.
I can think of all kinds of ways to scale this up to industrial capacity.
Much of California is either desert or quite arid, but much of the arid area is right next to the ocean.