Lithium Processing from Lithium Carbonate to Lithium Hydroxide

Discover the filtration essentials in lithium production

The electrical vehicle (EV) market is undergoing a revolution transforming the transportation landscape using lithium-ion battery technology. The demand for electric vehicles is not just increasing; it's projected to skyrocket over five times the 2022 production values by 2031. To meet this challenge, high-purity lithium hydroxide and lithium carbonate are required as essential materials for the formulation of these batteries.

 

The primary sources of lithium are brine lakes (Salars) and mineral deposits, mainly Spodumene ore. The Spodumene ore contains up to 6 % lithium. Conventional mining operations extract minerals from the ground through either underground pit excavation or surface strip mining, depending on the location of the mineral lode.

Lithium Conversion

 

Producing high-quality lithium products for EV batteries is not without its challenges. In many cases, Lithium Carbonate may be produced that is a lower quality than needed for EV batteries. It may also be desirable to use high grade Lithium Hydroxide as part of the cathode materials instead of the carbonate form. However, plants that are designed to produce the lower quality Lithium Carbonate may be difficult to modify to produce a high-quality battery grade material or lack resources such as fresh water needed in the conversion. Despite these challenges, a number of plants currently produce the Lithium Carbonate and then ship this material to plants specially designed to convert the lower grade Lithium Carbonate to a high-quality battery grade Lithium Hydroxide with most of these currently found in China.

  

Process to Convert Lithium Carbonate to Lithium Hydroxide

 

  

Filter

Filtration Value

Separation Product
1
Collect Technical Grade Lithium Hydroxide Product
Automated regenerative cartridge
2
Protect Ion-Exchange (IX) resin and crystallizer from carryover solids
1 - 5 Micron Filter
3
Remove trace solids and Ion Exchange resin fines before crystallizer
1 Micron Filter
4
Collect Battery Grade Lithium Hydroxide Product
Automated regenerative cartridge
5
Protect RO filtration unit from fouling
10 Micron Filter
6
Removal of contaminant from raw water feed to RO & utility water for other uses including flushing out equipment
10 - 20 Mircon Filter

 

Material Purity Specifications

 

Lithium-ion batteries have strict purity requirements for the materials used in their manufacture. Impurities can lead to poor charging performance, including reduced vehicle range of operation, more frequent need to charge, problems with batteries starting at colder temperatures and, in some extreme cases, the batteries catching on fire. A significant issue with the current lithium conversion practice is the reliability of the operation in producing high-quality lithium products. Battery-grade purity specifications for Lithium Hydroxide and Lithium Carbonate are provided in Table 1. Improved filtration and separation can be essential in improving the process reliability for producing consistent high-purity products and improving product yields, reducing product re-work, and reducing operation costs.

 

Battery Grade "LiOH-H₂O" (Lithium Hydroxide Monohydride) Purity Specs
LiOH, wt% 56.5 min
CO2, wt% 0.35 max
Cl, wt% 0.0020 max
SO4, wt% 0.010 max
Ca, wppm 15 max
Fe, wppm 5 max
Na, wppm 20 max
Al, wppm 10 max
Cr, wppm 5 max
Cu, wppm 5 max
K, wppm 10 max
Ni, wppm 10 max
Si, wppm 30 max
Zn, wppm 10 max
Heavy metals as Pb 10 max
Acid Insolubles, wt% 0.010 max

 

EV Battery Value Chain

Effective filtration and separation are crucial at each stage of the electric vehicle (EV) battery value chain to ensure successful yield, purity, and reliability processes. For base materials, mining and unique material processing are required for Nickel, Cobalt and Aluminium and lithium. Active materials involve treating chemicals, specialty chemicals, and polymers to make the essential battery components: the separator, electrolyte, and anode/cathode. The battery cells also use chemicals and specialty chemicals that must be at rigorous purity levels to prepare the casing, filling operations, and slurries.

 

Pall Corporation is your filtration and separation needs partner and has experience throughout the EV battery value chain. Pall has over 400 qualified Engineers and Scientists who can provide prototype testing, on-site pilot testing, best practice training, process optimization, audits, contaminant analysis, application troubleshooting, validation services, presentations at scientific forums, and journal publications.

Base materials

  • Mining
  • Material processing

Active materials

  • Chemicals 
  • Specialty chemicals
  • Polymers

Battery cells

  • Chemicals
  • Specialty chemicals
  • Nickel
  • Lithium
  • Cobalt 
  • Aluminium
  • Separator
  • Electrolyte
  • Anode/cathode

 

  • Casing
  • Filling
  • Slurry

 

Applications in the EV Battery Value Chain

Maximize your lithium production efficiency with our efficient filtration solutions. Contact our experts and let us help you take your process to the next level.

By clicking the ‘Register Now’ button below and proceeding I confirm that I have reviewed and agree with the Terms of Use and the Privacy Policy.

1