Your search keyword '"Yang, Chuanbo"' showing total 4 results

1. Numerical investigation of thermal runaway mitigation through a passive thermal management system.

Author

Li, Qibo, Yang, Chuanbo, Santhanagopalan, Shriram, Smith, Kandler, Lamb, Joshua, Steele, Leigh Anna, and Torres-Castro, Loraine

Subjects

*ALUMINUM plates, *LITHIUM-ion batteries, *THERMAL shock, *PHASE change materials, *THERMAL resistance, *PLATING

Abstract

Prevention of thermal runaway and its propagation remains a technical barrier to the application of lithium-ion batteries. To mitigate thermal runaway in lithium-ion battery packs, heat sinks have been designed using various materials, such as phase-change materials or metal plates. In this study, aluminum plates were assembled into battery modules as heat sinks and the effect of plate thickness on thermal runaway mitigation was numerically investigated. A three-dimensional integrated multiphysics model was validated and calibrated with experimental data. It identified the mechanism and sequence of thermal runaway propagation in detail. Thermal mass and contact resistance are found to be the key design parameters for preventing thermal runaway propagation for the studied battery module configuration. In addition, this study provides further insights into the design of aluminum heat sinks for lithium-ion battery packs. Image 1 • A battery model explained cascading thermal failure and mitigation mechanisms. • Thermal mass is vital for passive control of thermal runaway propagation. • Aluminum fin can be geometrically optimized to enhance conductive heat dissipation. • Thermal contact resistance is valuable in reducing the severity of thermal shock. [ABSTRACT FROM AUTHOR]

Published

2019

2. Compressible battery foams to prevent cascading thermal runaway in Li-ion pouch batteries.

Author

Yang, Chuanbo, Sunderlin, Nathaniel, Wang, Wei, Churchill, Chris, and Keyser, Matthew

Subjects

*FOAM, *LITHIUM-ion batteries, *URETHANE foam, *SURFACE preparation, *FIREPROOFING agents, *STORAGE batteries

Abstract

Lithium-ion battery packs require thermal management to achieve optimum life and safety. This is becoming crucial for battery packs composed of high-energy-density cells. Pouch cells themselves achieve highest packaging efficiency but require additional structural support and thermal management when grouped into modules, especially under abusive conditions such as thermal runaway. Novel foam battery pads have demonstrated to cushion volume changes of pouch cells and are reengineered in this study to mitigate cell-to-cell thermal runaway propagation. The compressible pads are made of polyurethane foams incorporating flame-retardant additives or coatings, including intumescent and fire wall materials. Their performances were evaluated by conducting nail penetration tests on modules composed of pouch cells at 100% state of charge (SOC), with the foams placed in between the cells. Experimental results show cascading thermal runaway was considerably delayed by polyurethane foams incorporating flame-retardant additives or coatings. Complete prevention of cascading failure was achieved with dense polyurethane foams with multilayered coatings of both fire wall and intumescent materials. • A redesigned compressible battery foam prevents pouch cell-to-cell thermal runaway. • Flame-retardant polyurethane foams were directly evaluated with battery abuse tests. • Combined bulk additive and surface treatment methods delivers desired retardancy. • Modeling predicts external cooling has limited contribution on propagation control. [ABSTRACT FROM AUTHOR]

Published

2022

3. Modelling and experiments to identify high-risk failure scenarios for testing the safety of lithium-ion cells.

Author

Finegan, Donal P., Darst, John, Walker, William, Li, Qibo, Yang, Chuanbo, Jervis, Rhodri, Heenan, Thomas M.M., Hack, Jennifer, Thomas, James C., Rack, Alexander, Brett, Dan J.L., Shearing, Paul R., Keyser, Matt, and Darcy, Eric

Subjects

*SHORT circuits, *LITHIUM-ion batteries, *SYNCHROTRON radiation, *THREE-dimensional imaging, *THERMAL properties

Abstract

Abstract Intentionally inducing worst-case thermal runaway scenarios in Li-ion cells on-demand is a definitive way to test the efficacy of battery systems in safely mitigating the consequences of catastrophic failure. An internal short-circuiting (ISC) device is implanted into three 18650 cell designs: one standard, one with a bottom vent, and one with a thicker casing. Through an extensive study of 228 cells, the position at which thermal runaway initiates is shown to greatly affect the tendency of cells to rupture and incur side-wall breaches at specific locations. The risks associated with each failure mechanism and position of the ISC device are quantified using a custom calorimeter that can decouple the heat from ejected and non-ejected contents. Causes of high-risk failure mechanisms, such as bursting and side-wall breaches, are elucidated using high-speed synchrotron X-ray imaging at 2000 frames per second and image-based 3D thermal runaway computational models, which together are used to construct a comprehensive description of external risks based on internal structural and thermal phenomena. [ABSTRACT FROM AUTHOR]

Published

2019

4. Significant life extension of lithium-ion batteries using compact metallic lithium reservoir with passive control.

Author

Colclasure, Andrew M., Li, Xuemin, Cao, Lei, Finegan, Donal P., Yang, Chuanbo, and Smith, Kandler

Subjects

*DISTRIBUTION (Probability theory), *LITHIUM-ion batteries

Abstract

Both traditional graphite-based lithium-ion batteries and next generation silicon-based chemistries suffer significant capacity fade from loss of cyclable lithium due to continued solid-electrolyte interphase growth. A possible engineering solution to maintaining the capacity of cells is incorporating a metallic lithium reservoir and discharging the reservoir into a working electrode to make up for lost cyclable lithium. Here, metallic lithium reservoirs are inserted into both pouch- and cylindrical-format cells. Significant capacity recovery and lifetime extension are demonstrated for traditional graphite and Si/graphite-based cells. A combination of post-mortem characterization and modeling provide insight into how the lithium distribution as a function of position from reservoir vary with recovery rate. The potential of using passive control to potentially eliminate the need for extra wiring for the third electrode is explored using a simple resistor. [ABSTRACT FROM AUTHOR]

Published

2021