Fact Snapshot
- Paper: Ultrafast microwave heated form-stable thermal package providing operating temperature for PEO all-solid-state batteries
- Equipment: XH-200A / XH-200C
- Source: Energy Storage Materials, 2023
- Research direction: all-solid-state battery thermal management, rapid microwave heating, phase-change thermal-storage material, and battery cold start
- Core conditions: Time 1 min
- Key results: Thermal-conductivity enhancement 64.6%
Research Abstract
Ultrafast microwave heated form-stable thermal package providing operating temperature for PEO all-solid-state batteries was published in Energy Storage Materials (2023) and is indexed as a Xianghu Q1 application case for XH-200A / XH-200C. The source record connects it with all-solid-state battery thermal management, rapid microwave heating, phase-change thermal-storage material, and battery cold start. Core operating conditions include Time 1 min. Key reported results include Thermal-conductivity enhancement 64.6%.
Research Background and Problem
Equipment Use and Experimental Conditions
| Item | Parameter |
|---|---|
| Time | 1 min |
Key Result
| Metric | Result |
|---|---|
| Thermal-conductivity enhancement | 64.6% |
Evidence Details
Microwave-method evidence: source values include 1 min, 55 °C, 92%. Entities: XH-200A.
The composite, prepared by alumina ceramic fiber, boron nitride, and GPCM, presenting excellent thermal properties such as great enhancement of thermal conductivity (64.6%) and low enthalpy loss (11.27%).
Mechanism / Method Highlights
- The mechanism is a synergy of a form-stable anti-leakage skeleton, graphene-enhanced microwave absorption, phase-change heat storage, and effective heat transfer to the battery. Alumina ceramic fiber and boron nitride build the anti-leakage skeleton, keeping the phase-change material shape-stable during heating.
- Graphene acts as the key microwave-responsive unit and improves heat-generation efficiency in the microwave field.
- The phase-change material stores and releases heat during heating and cooling, providing the battery with a more stable operating-temperature window.
- Higher thermal conductivity helps transfer locally generated heat to the battery surface faster and more uniformly, easing the slow heat-diffusion problem of conventional phase-change systems.
- The combination of rapid microwave triggering and phase-change temperature maintenance enables PEO-based all-solid-state batteries to start quickly at room temperature and operate with near-isothermal assistance.
Application Value
- Integrates microwave heating, phase-change thermal storage, and battery thermal management into a portable thermal-package system.
- Combines a 64.6% thermal-conductivity enhancement with a low enthalpy loss of 11.27%.
- Enables PEO-based all-solid-state batteries to cold-start at room temperature within 1 min.
- As an auxiliary heating unit, it reaches 92% of the capacity of the 55 °C oven-control battery at 1C.
- Links material-level thermal design directly with battery operating performance, making the application path clear.
Related Equipment
FAQ
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Ultrafast microwave heated form-stable thermal package providing operating temperature for PEO all-solid-state batteries
Energy Storage Materials, 2023
DOI: 10.1016/j.ensm.2023.102814
