Pouch Cells

Pouch cells look like an aluminium jiffy bag with +ve and -ve terminals protruding from the edge.

LG Chem pouch cell

They need to be supported mechanically and need a controlled pressure applied to the surface to deliver the power and energy over their lifetime. This is normally achieved by mechanically fixing and supporting the pouches in a well constructed module.

Pros

  • pouch cell with tab at each end offers one of the lowest internal resistance cell geometries
  • very high energy density at cell level

Cons

  • easy to damage as cell case offers little protection
  • maximum thickness of active material stack limited to ~15mm
  • difficult to seal around +ve and -ve tabs and hence limits tab thickness

A module will be required that can mechanically support the cells. This needs to maintain the required pressure, support electrical interconnections and manage the venting / failure of the cells in a controlled manner.

Cooling

A strong thermal interface to the cell is difficult to design. There are examples in industry of every possible cooling arrangement for pouch cells.

Stacking versus Winding

Some of the smaller pouch cells have traditionally used a jelly roll of active layers that are then flattened before being wrapped in the pouch cell case. This is low cost, but is not optimal for energy or power density.

Example Applications

  • 2021 Audi e-tron GT quattro – LG Chem pouch cell in an LG Chem module
  • Nissan Leaf – since the release of the very first Nissan Leaf it has used an AESC pouch cell supported in a “sardine tin” module case.

References

  1. Dai, F., Cai, M. Best practices in lithium battery cell preparation and evaluationCommun Mater 3, 64 (2022)