Osmotic power
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Osmotic power, salinity gradient power or blue energy is the energy available from the difference in the salt concentration between
In 1954, Pattle[1] suggested that there was an untapped source of power when a river mixes with the sea, in terms of the lost osmotic pressure, however it was not until the mid ‘70s where a practical method of harnessing it using selectively permeable membranes by Loeb [2] was outlined.
The method of generating power by pressure retarded osmosis was invented by Prof. Sidney Loeb in 1973 at the Ben-Gurion University of the Negev, Beersheba, Israel.[3] The idea came to Prof. Loeb, in part, as he observed the Jordan River flowing into the Dead Sea. He wanted to harvest the energy of mixing of the two aqueous solutions (the Jordan River being one and the Dead Sea being the other) that was going to waste in this natural mixing process.[4] In 1977 Prof. Loeb invented a method of producing power by a reverse electrodialysis heat engine.[5]
The technologies have been confirmed in laboratory conditions. They are being developed into commercial use in the Netherlands (RED) and Norway (PRO). The cost of the membrane has been an obstacle. A new, lower cost membrane, based on an electrically modified
Basics of salinity gradient power
Salinity gradient power is a specific renewable energy alternative that creates renewable and sustainable power by using naturally occurring processes. This practice does not contaminate or release carbon dioxide (CO2) emissions (vapor pressure methods will release dissolved air containing CO2 at low pressures—these non-condensable gases can be re-dissolved of course, but with an energy penalty). Also as stated by Jones and Finley within their article “Recent Development in Salinity Gradient Power”, there is basically no fuel cost.
Salinity gradient energy is based on using the resources of “osmotic pressure difference between fresh water and sea water.”[9] All energy that is proposed to use salinity gradient technology relies on the evaporation to separate water from salt. Osmotic pressure is the "chemical potential of concentrated and dilute solutions of salt".[10] When looking at relations between high osmotic pressure and low, solutions with higher concentrations of salt have higher pressure.
Differing salinity gradient power generations exist but one of the most commonly discussed is pressure-retarded osmosis (PRO). Within PRO seawater is pumped into a pressure chamber where the pressure is lower than the difference between fresh and salt water pressure. Fresh water moves in a semipermeable membrane and increases its volume in the chamber. As the pressure in the chamber is compensated a turbine spins to generate electricity. In Braun's article he states that this process is easy to understand in a more broken down manner. Two solutions, A being salt water and B being fresh water are separated by a membrane. He states "only water molecules can pass the semipermeable membrane. As a result of the osmotic pressure difference between both solutions, the water from solution B thus will diffuse through the membrane in order to dilute solution A".[11] The pressure drives the turbines and power the generator that produces the electrical energy. Osmosis might be used directly to "pump" fresh water out of The Netherlands into the sea. This is currently done using electric pumps.
Efficiency
A 2012 study on efficiency from Yale University concluded that the highest extractable work in constant-pressure PRO with a seawater draw solution and river water feed solution is 0.75 kWh/m3 (2.7 kJ/L) while the free energy of mixing is 0.81 kWh/m3 (2.9 kJ/L) — a thermodynamic extraction efficiency of 91.0%.[12]
Methods
While the mechanics and concepts of salinity gradient power are still being studied, the power source has been implemented in several different locations. Most of these are experimental, but thus far they have been predominantly successful. The various companies that have utilized this power have also done so in many different ways as there are several concepts and processes that harness the power from salinity gradient.
Pressure-retarded osmosis
One method to utilize salinity gradient energy is called pressure-retarded osmosis.[13] In this method, seawater is pumped into a pressure chamber that is at a pressure lower than the difference between the pressures of saline water and fresh water. Freshwater is also pumped into the pressure chamber through a membrane, which increase both the volume and pressure of the chamber. As the pressure differences are compensated, a turbine is spun, providing kinetic energy. This method is being specifically studied by the Norwegian utility Statkraft, which has calculated that up to 2.85 GW would be available from this process in Norway.[14] Statkraft has built the world's first prototype PRO power plant on the Oslo fjord which was opened by Princess Mette-Marit of Norway[15] on November 24, 2009. It aimed to produce enough electricity to light and heat a small town within five years by osmosis. At first, it did produce a minuscule 4 kilowatts – enough to heat a large electric kettle, but by 2015 the target was 25 megawatts – the same as a small wind farm.[16] In January 2014 however Statkraft announced not to continue this pilot.[17] Statkraft found that with existing technology, the salt gradient was not high enough to be economic, which other studies have agreed on.[18] Higher salt gradients can be found in geothermal brines and desalination plant brines,[19] and SaltPower, a Danish company, is now building its first commercial plant with high salinity brine.[20] There is perhaps more potential in integrating Pressure Retarded Osmosis as an operating mode of reverse osmosis, rather than a stand-alone technology.[21]
Reversed electrodialysis
A second method being developed and studied is reversed electrodialysis or reverse dialysis, which is essentially the creation of a salt battery. This method was described by Weinstein and Leitz as “an array of alternating anion and cation exchange membranes can be used to generate electric power from the free energy of river and sea water.”
The technology related to this type of power is still in its infant stages, even though the principle was discovered in the 1950s. Standards and a complete understanding of all the ways salinity gradients can be utilized are important goals to strive for in order to make this clean energy source more viable in the future.
Capacitive method
A third method is
Vapor pressure differences: open cycle and absorption refrigeration cycle (closed cycle)
Both of these methods do not rely on membranes, so filtration requirements are not as important as they are in the PRO & RED schemes.
Open cycle
Similar to the open cycle in ocean thermal energy conversion (OTEC). The disadvantage of this cycle is the cumbersome problem of a large diameter turbine (75 meters +) operating at below atmospheric pressure to extract the power between the water with less salinity & the water with greater salinity.
Absorption refrigeration cycle (closed cycle)
For the purpose of dehumidifying air, in a
Solar pond
At the Eddy Potash Mine in New Mexico, a technology called "salinity gradient
In theory a solar pond could be used to generate osmotic power if evaporation from solar heat is used to create a salinity gradient, and the potential energy in this salinity gradient is harnessed directly using one of the first three methods above, such as the capacitive method.
Boron nitride nanotubes
A research team built an experimental system using boron nitride that produced much greater power than the Statkraft prototype. It used an impermeable and electrically insulating membrane that was pierced by a single boron nitride nanotube with an external diameter of a few dozen nanometers. With this membrane separating a salt water reservoir and a fresh water reservoir, the team measured the electric current passing through the membrane using two electrodes immersed in the fluid either side of the nanotube.
The results showed the device was able to generate an electric current on the order of a nanoampere. The researchers claim this is 1,000 times the yield of other known techniques for harvesting osmotic energy and makes boron nitride nanotubes an extremely efficient solution for harvesting the energy of salinity gradients for usable electrical power.
The team claimed that a 1 square metre (11 sq ft) membrane could generate around 4 kW and be capable of generating up to 30 MWh per year.[23]
At the 2019 fall meeting of the Materials Research Society a team from Rutgers University reported creating a membrane that contained around 10 million BNNTs per cubic centimeter.[24][25]
Using low caloric waste energy by regenerate a high solution ammonium bicarbonate in a solution with a low salinity
At Pennsylvania State University, Dr. Logan tries to use waste heat with low calority using the fact that ammonium bicarbonate decomposes into NH3 and CO2 in warm water to form ammonium bicarbonate again in cold water. So in a RED energy producing closed system the two different gradients of salinity are kept.[26]
Possible negative environmental impact
Marine and river environments have obvious differences in water quality, namely salinity. Each species of aquatic plant and animal is adapted to survive in either marine, brackish, or freshwater environments. There are species that can tolerate both, but these species usually thrive best in a specific water environment. The main waste product of salinity gradient technology is brackish water. The discharge of brackish water into the surrounding waters, if done in large quantities and with any regularity, will cause salinity fluctuations. While some variation in salinity is usual, particularly where fresh water (rivers) empties into an ocean or sea anyway, these variations become less important for both bodies of water with the addition of brackish waste waters. Extreme salinity changes in an aquatic environment may result in findings of low densities of both animals and plants due to intolerance of sudden severe salinity drops or spikes.[27] According to the prevailing environmentalist opinions, the possibility of these negative effects should be considered by the operators of future large blue energy establishments.
The impact of brackish water on ecosystems can be minimized by pumping it out to sea and releasing it into the mid-layer, away from the surface and bottom ecosystems.
Impingement and entrainment at intake structures are a concern due to large volumes of both river and sea water utilized in both PRO and RED schemes. Intake construction permits must meet strict environmental regulations and desalination plants and power plants that utilize surface water are sometimes involved with various local, state and federal agencies to obtain permission that can take upwards to 18 months.
See also
- Forward osmosis – Water purification process
- Electrodialysis reversal (EDR) – Technique of separating salts from water
- Reversed electrodialysis
- Reverse osmosis – Water purification process
- Semipermeable membrane – Membrane which will allow certain molecules or ions to pass through it by diffusion
- Marine energy – Energy stored in the waters of oceans
- Green energy– Energy that responsibly meets social, economic, and environmental needs
- Renewable energy – Energy collected from renewable resources
- Fugacity – Effective partial pressure
- Concentration cell – galvanic cell that generates a voltage from differing concentrations of the same material
- Solar pond – Solar thermal energy
References
- S2CID 4144672.
- PMID 17838753.
- ^ ^ Israel Patent Application 42658 of July 3, 1973. (see also US 3906250 Erroneously shows Israel priority as 1974 instead of 1973 US 3906250
- ^ ^ Weintraub, Bob. "Sidney Loeb," Bulletin of the Israel Chemical Society, Dec. 2001, issue 8, page 8-9. https://drive.google.com/file/d/1hpgY6dd0Qtb4M6xnNXhutP4pMxidq_jqG962VzWt_W7-hssGnSxSzjTY8RvW/edit
- ^ United States Patent US4171409 Archived 2016-04-06 at the Wayback Machine
- ^ History of osmotic power (PDF) at archive.org
- ^ PMID 19792539.
- S2CID 45143260.
- ^ (Jones, A.T., W. Finley. “Recent developments in salinity gradient power”. Oceans. 2003. 2284-2287.)
- ^ (Brauns, E. “Toward a worldwide sustainable and simultaneous large-scale production of renewable energy and potable water trough salinity gradient power by combining reversed electrodialysis and solar power?” Environmental Process and Technology. Jan 2007. 312-323.)
- ^ (Brauns, E. “Toward a worldwide sustainable and simultaneous large-scale production of renewable energy and potable water through salinity gradient power by combining reversed electrodialysis and solar power?.” Environmental Process and Technology. Jan 2007. 312-323.)
- S2CID 206955094.
- ^ Salinity-gradient power: Evaluation of pressure-retarded osmosis and reverse electrodialysis
- ^ Recent Developments in Salinity Gradient Power Archived 2011-09-01 at the Wayback Machine
- ^ "The world's first osmotic power plant from Statkraft". 27 November 2009. Archived from the original on 2011-08-12. Retrieved 2009-11-27. Statkraft-osmotic-power
- ^ BBC News Norway's Statkraft opens first osmotic power plant
- ^ "Is PRO economically feasible? Not according to Statkraft | ForwardOsmosisTech". 22 January 2014. Archived from the original on 2017-01-18. Retrieved 2017-01-18.
- ISSN 1754-5692.
- S2CID 105934538.
- ^ Saltpower
- ISSN 0011-9164.
- ^ Salinity Gradient Solar Pond Technology Applied to Potash Solution Mining
- ^ "Nanotubes boost potential of salinity power as a renewable energy source". Gizmag.com. 13 March 2013. Archived from the original on 2013-10-28. Retrieved 2013-03-15.
- ^ Service, Robert F. (2019-12-04). "Rivers could generate thousands of nuclear power plants worth of energy, thanks to a new 'blue' membrane". Science | AAAS. Archived from the original on 2019-12-06. Retrieved 2019-12-06.
- ^ "Symposium Sessions | 2019 MRS Fall Meeting | Boston". www.mrs.org. Archived from the original on 2019-11-29. Retrieved 2019-12-06.
- ^ "Energy from Water". Archived from the original on 2017-02-02. Retrieved 2017-01-28.
- ^ Montague, C., Ley, J. A Possible Effect of Salinity Fluctuation on Abundance of Benthic Vegetation and Associated Fauna in Northeastern Florida Bay. Estuaries and Coasts. 1993. Springer New York. Vol.15 No. 4. Pg. 703-717