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MIT Unveils Portable, Solar-Powered Water Desalination System

Posted by Soulskill on from the water-the-chances dept.

An anonymous reader writes "A team from the Massachusetts Institute of Technology's Field and Space Robotic Laboratory has designed a new solar-powered water desalination system to provide drinking water to disaster zones and disadvantaged parts of the planet. Desalination systems often require a lot of energy and a large infrastructure to support them, but MIT's compact system is able to cope due to its ingenious design. The system's photovoltaic panel is able to generate power for the pump, which in turn pushes undrinkable seawater through a permeable membrane. MIT's prototype can reportedly produce 80 gallons of drinking water per day, depending on weather conditions."

14 of 117 comments (clear)

  1. 80 US gallons by MichaelSmith · · Score: 4, Interesting

    Thats 300 liters. Maybe enough for ten people if you are careful. Or a hundred people if you only need drinking water to keep them alive.

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    http://michaelsmith.id.au
    1. Re:80 US gallons by afidel · · Score: 5, Interesting

      FTFA 24 of them will fit on a C130 and provide water for "more than 10,000 people", so I'm thinking more like 500 people per large unit and that's under ideal conditions. That's as opposed to a more traditional unit about the size of a cargo container that can do 200k gallons a day or enough for 40-50k people. Personally I think for large scale disasters it makes a LOT more sense to drop 2 of those and two fuel/generator sets and supply 10x more people with fresh water since every cargo flight counts.

      --
      There are 4 boxes to use in the defense of liberty: soap, ballot, jury, ammo. Use in that order. Starting now.
    2. Re:80 US gallons by sempir · · Score: 4, Funny

      Getting random creeks into a C130 has it's own inherent problems...leakage being one. Stacking is another, causes apeshittedness big time.

      --
      A closed mouth gathers no foot.
    3. Re:80 US gallons by deimtee · · Score: 3, Funny

      And you really have to be careful not to cross the streams.

      --
      I'm guessing that wasn't on their radar screen...
  2. Damn you, science jornalism. by kurokame · · Score: 5, Insightful

    Pump-fed nanofilters are sort of an old idea at this point. The summary leaves off some critical points like how much it costs and how long the filter lasts.

    According to the article, it costs $8000, which is a lot for some things but probably accessible for others. Let's just say it's not going to solve the world's water problem overnight, but it might be handy for relief efforts.

    Surfing through to the parent MITnews article, we get a bit more information, but it's still lacking anything about how long the system can operate or what its maintenance costs and requirements are. Does it last a week then you're out most of another $8000? Does it require a lot of technical expertise to maintain? It doesn't say...

  3. Optional attachments... by canatech · · Score: 3, Insightful

    And for about 8 more dollars, they could attach a big funnel and bucket for those days when it rains and the solar part doesn't work so well.

  4. Boats by WindBourne · · Score: 5, Insightful

    To get the price down, they need production of this. One simple way to do that, is to adopt it to boats in the western world. By doing this, the boats will be able to have clean water on-board available from offshore. Then as production increases, the costs go down. Then it allows these units to be produced CHEAPLY.

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  5. Question by Prune · · Score: 4, Insightful

    Can someone comment on the comparative efficiencies of photovoltaic and solar thermal sources of energy? How much better is this really than using thermal-driven evaporative desalination? I mean, other than lacking in the "new and cool" factor

    --
    "Politicians and diapers must be changed often, and for the same reason."
    1. Re:Question by L4t3r4lu5 · · Score: 3, Interesting

      More's the point, why the hell isn't their a manual pump? You don't need sunlight to hand-crank a piston. Some form of centrifugal brake* will prevent exceeding the maximum pressure of the filter, and it can run indoors with a hose out to the salt water.

      * - I don't know if this is the correct term. The faster you turn the crank, a set of weighted brake shoes (or similar) move out towards a high friction surface. The faster you spin, the harder it becomes to continue. Or some such.

      --
      Finally had enough. Come see us over at https://soylentnews.org/
    2. Re:Question by Biogenesis · · Score: 3, Interesting

      Here's a quick and dirty stab at some calculations:

      Wikipedia claims that reverse osmosis requires 6kWh to produce 1000L of water, or 21.6 kJ/L.

      To evaporate water already at 100C requires ~41kJ/mol, or 2.3kJ/L. To heat 1L of water from 20C to 100C requires 33.6kJ. So, by this very simplistic model it would require ~34kJ/L to desalinate water by boiling.

      Now the efficiency of PV vs thermal in a solar powered system depends on the efficiencies of the collectors. PV is ~25%, at best, solar insolation -> electricity. Heating water to evaporate it is a much more difficult calculation. Basically water doesn't have to be at 100C to evaporate and the losses in a thermal system would increase as the temperature differential (system->ambient) increased but in the end I'm not really educated enough to comment accurately. Hopefully the numbers above will give you some feel for the problem though.

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      ...just so Google finds it.
  6. Re:Cost by sempir · · Score: 3, Insightful

    Yup...that car and garden water could be better put to use in ..MAKING BEER!

    --
    A closed mouth gathers no foot.
  7. Sigh... by SmallFurryCreature · · Score: 4, Informative

    Is reading that hard? DISASTER relief. You can't go around digging wells in a hurry. This system is designed to be put aboard an aircraft and flown to a disaster zone in a hurry to be used until normal operations can be resumed.

    It is NOT a permanent solution.

    Maybe if you could grasp this from the summary YOU could have gone to MIT and wouldn't be so upset.

    What really is so hard to understand about the difference between disaster relief techonology and permanent solutions?

    --

    MMO Quests are like orgasms:

    You may solo them, I prefer them in a group.

  8. Innovation????? by abarrow · · Score: 3, Insightful

    Sorry, but this just looks like a bog-standard boat desalinization system hooked up to some solar cells. I fail to see what is so earth-shattering about it.

  9. Longevity and Recreational Marine Use by JimMcc · · Score: 4, Informative

    The photo of the unit shows what appears to be a Clark Pump as used in Spectra Watermaker systems. (http://www.spectrawatermakers.com) These are popular in recreation long distance sailboats as they require less power for a given output than traditional RO systems.

    As for reliability and longevity, much depends on the design. If you keep pressures reasonable, and flow excess raw water back to its source, the RO membranes will last many years and thousands of hours of use. The key is not running pressures so high that the membrane gets clogged with solids from the raw water. Pre filtering the raw water also is critical to not fouling the membranes. We run a 30 micron then 10 micron filter before out high pressure pump. The prefilters only need to be changed when fouled so their life span depends on the turbidity of the raw water.

    We live aboard our boat and run a watermaker instead of using shoreside water sources. The unit is not as energy efficient as the MIT units. We have used it for years, have over 500 hours on it, and it has had near zero maintenance. In cold water, currently seawater is about 48F, we get 15gph, at 55F+ we get 18gph which is the max rated output, and above that we need to run at lower pressures to not saturate the membrane. We can get greater throughput by adding additional membranes. Adding a second membrane would double our output. (Sorry for the non metric units.) The Clark Pump system will get lower output, but the longevity of the membranes should be comparable. Membrane prices vary, but are typically in the US$250-US$500 range.