Technology Category/Market
Chemical Engineering: Energy/Infrastructure & Environmental Engg
Industry: Electrochemical, Clean Energy
Applications: improve electrolyte circulation in electrochemical cells such as redox flow batteries, fuel cells  and electrolyzers.
Market: Expanding at a CAGR of 4%, the global electrochemical instruments market projects increase US$ 2.56 billion in 2022 to US$ 3 billion by the end of 2026.
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Problem Statement
Electrochemical devices depend on heterogeneous electrochemical reactions carried out on planar surfaces  over which the electrolyte is circulated and uniform  distribution of the electro-active species through the  reaction zone improves the discharge energy efficiency  of these electrochemical devices. The major limitations of  these electrochemical devises include:
- Maldistribution/uneven distribution of reactant fluids,
- heavy pressure drop leading to heavy energy loss,
- poor velocity, unwanted bypassing & channel blockage
- regions of low through flow at the electrode.
Hence there is a need to develop an improved method to  overcome above-mentioned issues.
Technology
An electrochemical cell with serpentine flow field,  wherein the entire flow field is divided into multiple  independent segments with the individual entry/exit  streams extending between a common inlet manifold  and a common outlet manifold, characterized in:
- The serpentine flow field is a flip-flop  serpentine flow field;
- The direction of the electrolyte flow in the  porous electrode associated with adjacent  segments of said flow field is opposite, &  the direction of the electrolyte flow in the  porous electrode associated with  alternate segments of said flow field is  the same; Creating a flip flop  characteristic between each segment of  said flow field;
- Said segments comprising of ribs of  varying widths at various points of the  said flow
- Each segment having same serpentine path  length within the flow field so as to  maintain uniform flow split among the  segments.
- The flow field comprises parallel serpentine channels of equal length except at locations where wider ribs are provided.
- The ribs of varying widths are provided at locations near the entry and exit of each serpentine flow field segment.
- The ribs located at the entry and the exit of the serpentine flow field segments are wider than the ribs located at other points of the  serpentine flow field segments.
FIG 1 illustrates a schematic arrangement of flow path in the flip-flop serpentine flow field.
FIG 2 illustrates bar graphs showing relative  performance for an operating current density of 90  mA/cm² and flow rate of 0.62 ml/min/cm² of four  serpentine flow fields.
Key Features/Value Proposition
Technical Perspective
- Improved electrolyte circulation in electrochemical cells such as redox flow batteries, fuel cells and electrolyzers by preventing unwanted early bypassing of  electrolyte through the flow channels and  electrode region.
- Reduced flow maldistribution over the electrode region and reduced residence time of electrolyte in the electrode region for quick  evacuation of the used electrolyte.
User Perspective
- Improved overall performance of the  electrochemical cell.
Industrial Perspective
- The said invention overcomes the problem of high pressure drop in single serpentine flow field, by proposing a new flow field design  with a pattern called as Flip-Flop pattern.
- The said flow field pattern is designed in such a manner that the uniformity of cross-flow in the electrode region is preserved while ensuring  a short flow path over the cell area.
Questions about this Technology?
Contact for Licensing
Research Lab
Prof: Sreenivas Jayanti
Department of Chemical Engineering
Intellectual Property
- IDF Ref: 1982
- IN Patent No. 409784 (Granted)
- PCT Application No. PCT/IN2021/050122
Technology Readiness Level
TRL- 4
Proof of concept ready Stage