Design of a scaling reduction system for geothermal applications

Pardelli, Paolo Taddei; Tempesti, Claretta; Mannelli, Andrea; Kravos, Albert; Sabard, Alex; Fanicchia, Francesco; Paul, Shiladitya; Şengün, Raziye; Sahiller, Hakan Alp; Halaçoğlu, Ural; Pekdüz, Ismail; Stefánsson, Andri; Galeczka, Iwona

doi:10.1051/e3sconf/202123801014

Cited by 2 publications

(1 citation statement)

References 12 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Release of steam increases ion concentrations in the remaining brine, which can further promote scale formation. Other factors influencing scale formation are pH, redox conditions, contact time, ionic strength, fluid dynamics, and the presence of existing precipitants (Pardelli et al, 2021). Scaling can reduce fluid flow through pipes, reduce heat transfer, and have other negative consequences on process operations in power plants and other industries Brown, 2013;132 Harrar et al, 1979a;Jamero et al, 2018;MidAmerican Energy Holding Co., 2003;Pambudi et al, 2015;von Hirtz, 2016).…”

Section: Scale Control Processes and Chemical Usementioning

confidence: 99%

Characterizing the Geothermal Lithium Resource at the Salton Sea

Dobson,

Araya,

Brounce

et al. 2023

View full text Add to dashboard Cite

The energy transition towards a more sustainable and renewable future is a pivotal global endeavor. Central to this shift for the United States is the critical role of domestically sourced lithium, a key mineral in the production of high-performance batteries essential for electric vehicles and renewable energy storage systems. This has driven the United States to invest heavily in a domestic supply chain for batterygrade lithium to enhance energy security, reduce supply chain vulnerabilities, and foster economic growth by tapping into local resources. A notable example is the Biden Administration's "American Battery Materials Initiative," which was included in the $2.8-billion Bipartisan Infrastructure Law (The White House, 2022).The "Salton Sea Known Geothermal Resource Area" in Imperial County, California has been identified as a potential domestic U.S. resource of lithium due to the brine-hosted lithium in the deep subsurface geothermal reservoir. An analysis funded by the U.S. Department of Energy provides an overview of opportunities and challenges associated with developing the lithium resource in the Salton Sea geothermal reservoir, as well as potential environmental and societal impacts to the county and surrounding region.The geologic history of the region suggests that lithium in the subsurface brines could have come from multiple sources, including water and sediments from the Colorado River, which have been periodically deposited over the past several million years; rocks from the mountain ranges surrounding the Imperial Valley; and lithium-bearing volcanic rocks and igneous intrusions from past geologic events. Further, several processes may have concentrated lithium in the brine over time, including evaporative concentration of lithium-bearing water that flowed into the basin and leaching of lithium from the sediments and rocks by the circulating geothermal brines.Geothermal brine production at the Salton Sea Geothermal Field, the area with existing geothermal power plants, has averaged just over 120 million metric tons per year since 2004. Using an approximate lithium brine concentration of 198 parts per million (ppm), the amount of dissolved lithium contained in these produced brines is estimated to be 127,000 metric tons of lithium carbonate equivalent (LCE) per year. The total dissolved lithium content in the well-characterized portion of the Salton Sea Geothermal Reservoir is estimated at 4.1 million metric tons of LCE, and the estimated total resource increases to 18 million metric tons of LCE if assumptions for porosity and total reservoir size are increased to reflect the probable resource extent.Analysts measured lithium concentrations in the reservoir rocks, which were shown to vary with depth and mineralogy. These data were used to help refine conceptual and computer models of the reservoir; specifically, two complementary computer models of the reservoir were developed. Analysts used the first model to simulate the approximate 30-year history of geothermal power production in the area u...

show abstract

Section: Scale Control Processes and Chemical Usementioning

confidence: 99%

Characterizing the Geothermal Lithium Resource at the Salton Sea

Dobson,

Araya,

Brounce

et al. 2023

View full text Add to dashboard Cite

show abstract

Investigation of Scaling and Materials’ Performance in Simulated Geothermal Brine

Martelo,

Holmes,

Kale

et al. 2024

Materials

View full text Add to dashboard Cite

Geothermal energy generation faces challenges in efficiency, partly due to restrictions on reinjection temperatures caused by scaling issues. Therefore, developing strategies to prevent scaling is critical. This study aims to simulate the scaling tendencies and corrosion effects of geothermal fluids on various construction materials used in scaling reactor/retention tank systems. A range of materials, including carbon steel, austenitic stainless steel, duplex stainless steel, two proprietary two-part epoxy coatings, and thermally sprayed aluminium (TSA), were tested in a simulated geothermal brine. Experiments were conducted in a laboratory vessel designed to replicate the wall shear stress conditions expected in a scaling reactor. The tests revealed varying scaling tendencies among the materials, with minimal corrosion observed. The dominant scale formed was calcium carbonate, consistent with geochemical modelling. The findings suggest that despite the high operating temperatures, the risk of corrosion remains low due to the brine’s low chloride content, while the wettability of materials after immersion may serve as a useful indicator for selecting those that promote scaling.

show abstract

Design of a scaling reduction system for geothermal applications

Cited by 2 publications

References 12 publications

Characterizing the Geothermal Lithium Resource at the Salton Sea

Characterizing the Geothermal Lithium Resource at the Salton Sea

Investigation of Scaling and Materials’ Performance in Simulated Geothermal Brine

Contact Info

Product

Resources

About