Over the last century, and especially during the last few decades, desalination has become significantly more energy efficient. As we pointed out in our blog, A brief history of the energy intensity of desalination, since the first desalination plant appeared in 1928, technological innovation has driven down the specific energy consumption (SEC) from nearly 30 kWh/m3 for multi-stage flash thermal distillation to about 2 kWh/m3 for SWRO.
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But as much of the installed base of desalination plants was built before the latest energy-saving technology was developed – in particular isobaric energy recovery devices (ERDs) and the most efficient high-pressure pumps – a good share of existing desalination capacity is more energy-intensive than it could be. In fact, much more.
In an article we created for Global Water Intelligence, we calculated the potential savings if the worldwide installed base of desalination plants (21,755 plants in all, with a combined capacity of 128 million m3) was as energy-efficient as it could be, i.e., with an SEC of 2 kWh/m3, the current “state of the art.” Of course, this exercise was based on some assumptions, and the results must be taken with a grain of salt. Nonetheless, this ballpark estimate reveals the striking potential of retrofitting for energy efficiency:
In addition to these very significant energy savings, there are other good reasons to retrofit older SWRO plants. For example, the latest membrane technologies require less pressure than their predecessors. In addition, their higher recovery rates mean that less feed water is used and fewer chemicals are required for backwashing, reducing desalination’s impact on marine environments.
Everything mechanical eventually wears out and needs to be repaired or replaced. But retrofits for energy-saving focus on a handful of equipment types and configurations.
Given the striking potential of retrofits to save energy, one would think that all desalination plant owners with older technology would already have switched out their old technology for the latest, best-in-class alternatives. Indeed, many have, and even more will do so in the future. Still, many others continue to wait.
Why? Poor awareness of the benefits of retrofitting, reluctance to be an early adapter of new technology, and the inertia of not fixing what hasn’t broken all matter. But the biggest reasons are CAPEX and payback time. As the old saying goes, it takes money to save money.
For some plant owners, access to the capital required to retrofit their plant is problematical. For others, a payback time of anything more than a year raises doubts – even though they could save energy, money, and CO2 over a longer time horizon. As we pointed out in our blog, Understanding SWRO’s total cost of ownership, relatively small CAPEX investments can have an outsized impact on OPEX and TCO. Still, not all desalination investment decisions are made with a TCO mindset.
As the world is increasingly focused on energy efficiency and having enough water for growing populations and industry, retrofits of desalination plants will be increasingly relevant in the future. Much of the installed base would benefit from them, as money saved is money earned, just as CO2 emissions that are prevented do not add to global warming.
Climate change and growing awareness of the critical importance of decarbonization make the case for retrofits increasingly compelling. If the financial reasons outlined in this blog do not motivate owners and operators to retrofit for greater energy efficiency, carbon pricing and other forms of governmental regulation will likely add additional incentives.
Indeed, subsidies are already one way to encourage retrofits. Government action is important to shift attitudes and encourage action – see for example our blog, Energy-efficient SWRO should be part of the European Green Deal, to learn more about how the EU, for example, could encourage the transition from low-efficiency to high-efficiency desalination.
Although just one percent of worldwide water consumption currently derives from desalinated seawater, desalination is responsible for an outsized share of water treatment’s global energy usage.
Seawater reverse osmosis (SWRO) is growing worldwide to bridge the gap between increased demand and climate-driven water scarcity. However, compared to other sources such as ground and surface water, fresh water from SWRO is relatively expensive.
The first active ERD for medium and large plants, the MPE 70 integrates highly effective isobaric pressure exchangers with a low-voltage motor to eliminate the risk of rotor overspin, reduce mixing and biofouling, and facilitate smarter automation. Covering train sizes from 1,500 m3/day and above.
The range of high-pressure APP pumps is optimized for both landbased, off-shore and marine sea water reverse osmosis applications. Available with or without motor.
With a 3-in-1 design that integrates highly effective isobaric pressure exchangers with positive displacement booster pumps and electrical motors, active iSave® ERDs deliver big energy savings in small spaces. Covering train sizes from 200-3,000 m3/day
VLT® AQUA Drive FC 202 controls all types of pumps and comes equipped with a cascade controller.
For use in corrosive environments and with aggressive media, Danfoss offers the robust DST P40I pressure transmitter made of Titanium and with ceramic pressure sensing element. DST P40I is optimized for use in applications such as desalination systems, seawater cooling, and chemical processing.
Compact and energy efficient pump from Danfoss replaces obsolete centrifugal pump. After 20,000 hours no maintenance has been needed and energy costs are reduced by 20%.
A reduction of 57% on the energy consumption was achieved by retrofitting with Danfoss pump and iSave ERD.
For a resort in Bahamas APP pump and iSave ERD were selected to supply fresh water. Both components are well-known for long service intervals, high reliability and energy efficiency. They eliminate risk of oil contamination on the plant site, as they use the pumped medium for lubrication.
Simplified maintenance, high energy cost savings and low TCO are keeping fresh water flowing 24/7 - those are the advantages a luxury resort in Cabo San Lucas has achieved by retrofitting a reciprocating pump with the Danfoss APP pump.
38% reduction in the energy costs and an outstanding reduction of carbon emissions are benefits perceived by an Hawaiian golf course community using Danfoss APP pumps in their irrigation system.
SK Watermakers has selected oil-free APP pumps for many of their marine applications due to proven reliability, easy maintenance and long service intervals.
TSG is a water and wastewater treatment plant specialist with extensive experience in meeting the challenges of coastal and island environments.
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