Monitoring the Strain Evolution of Lithium‐Ion Battery Electrodes using an Optical Fiber Bragg Grating Sensor

Bae, Chang‐Jun; Manandhar, Ashish; Kiesel, P.; Raghavan, Ajay

doi:10.1002/ente.201500514

Cited by 69 publications

(58 citation statements)

References 21 publications

(34 reference statements)

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“…The shift in the Bragg peak wavelength worked as a function of SOC [45]. More noticeable wavelength shifting in both attached and implanted FBG sensors was observed at the end of the Energies 2017, 10, 591 9 of 19 SOC steps; this phenomenon corresponded to the larger volume change in graphite material when Li-ions were completely intercalated or de-intercalated.…”

Section: Fiber Optic Sensormentioning

confidence: 95%

“…The shift in the Bragg peak wavelength worked as a function of SOC [45]. More noticeable wavelength shifting in both attached and implanted FBG sensors was observed at the end of the Measurement of the stress evolution of Li-ion battery electrodes has been performed on Li-ion batteries using FBG sensors.…”

Section: Fiber Optic Sensormentioning

confidence: 99%

“…More noticeable wavelength shifting in both attached and implanted FBG sensors was observed at the end of the Measurement of the stress evolution of Li-ion battery electrodes has been performed on Li-ion batteries using FBG sensors. Bae et al [45] made an FBG sensor attached or built into the graphite anode of a lithium cobalt oxide Li-ion cell to directly detect dimensional changes as shown in Figure 4b. Peak shifting or splitting at the Bragg wavelength was observed with the FBG sensors attached to or implanted within the battery anode at the fully charged state (100% SOC).…”

Section: Fiber Optic Sensormentioning

confidence: 99%

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In Situ Stress Measurement Techniques on Li-ion Battery Electrodes: A Review

Cheng

Pecht

2017

Energies

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Li-ion batteries experience mechanical stress evolution due in part to Li intercalation into and de-intercalation out of the electrodes, ultimately resulting in performance degradation. In situ measurements of electrode stress can be used to analyze stress generation factors, verify mechanical deformation models, and validate degradation mechanisms. They can also be embedded in Li-ion battery management systems when stress sensors are either implanted in electrodes or attached on battery surfaces. This paper reviews in situ measurement methods of electrode stress based on optical principles, including digital image correlation, curvature measurement, and fiber optical sensors. Their experimental setups, principles, and applications are described and contrasted. This literature review summarizes the current status of these stress measurement methods for battery electrodes and discusses recent developments and trends.

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Section: Fiber Optic Sensormentioning

confidence: 95%

“…The shift in the Bragg peak wavelength worked as a function of SOC [45]. More noticeable wavelength shifting in both attached and implanted FBG sensors was observed at the end of the Measurement of the stress evolution of Li-ion battery electrodes has been performed on Li-ion batteries using FBG sensors.…”

Section: Fiber Optic Sensormentioning

confidence: 99%

Section: Fiber Optic Sensormentioning

confidence: 99%

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In Situ Stress Measurement Techniques on Li-ion Battery Electrodes: A Review

Cheng

Pecht

2017

Energies

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“…Lithium‐ion cells are seeing increased utilisation in portable electronics, electric vehicles and grid storage . This is due to a number of advantages over alternative technologies, such as high energy and power density, low self‐discharge, high output voltage and limited memory effects . However, the market expectations and consumer demands go further requiring better performance.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Thermo‐Electrochemical In Situ Instrumentation for Lithium‐Ion Energy Storage

Amietszajew

Fleming

Roberts

et al. 2019

Batteries & Supercaps

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Current "state-of-the-art" monitoring and control techniques for lithium-ion cells rely on full-cell potential measurement and occasional surface temperature measurements. However, Li-ion cells are complex multi-layer devices and as such these techniques have poor resolution, limiting applicability. In this work we develop hybrid thermo-electrochemical sensing arrays placed within the cell. The arrays are integrated into A5 pouch cells during manufacture and are used to create thermal maps in parallel with anode and cathode electrochemical data. The sensor array can be adapted to a range of cell formats and chemistries and installed into commercial or other industrially relevant cells, incorporating enhanced thermal and electrochemical diagnostic capability into a standard cell build.[a] Dr.

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“…Additionally, due to the small fiber diameter of 125 µm, FBG sensors can be integrated in many areas that are usually inaccessible for electric sensors e.g., in a battery system consisting of many densely stacked cells. FBG, applied as external strain sensors for monitoring lithium-ion cells with a flexible casing (also referred to as pouch cells), have been demonstrated several times already [25][26][27]. This observable strain variation during operation is of great interest for an improved state estimation because none of the aforementioned methods used in practice are capable of delivering information about the mechanical behavior of the cells, e.g., swelling due to aging effects.…”

Section: Introductionmentioning

confidence: 99%

Development of a Polymeric Arrayed Waveguide Grating Interrogator for Fast and Precise Lithium-Ion Battery Status Monitoring

et al. 2019

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We present the manufacturing and utilization of an all-polymer arrayed waveguide grating (AWG) interacting with a fiber Bragg grating (FBG) for battery status monitoring on the example of a 40 Ah lithium-ion battery. The AWG is the main component of a novel low-cost approach for an optical interrogation unit to track the FBG peak wavelength by means of intensity changes monitored by a CMOS linear image sensor, read out by a Teensy 3.2 microcontroller. The AWG was manufactured using laser direct lithography as an all-polymer-system, whereas the FBG was produced by point-by-point femtosecond laser writing. Using this system, we continuously monitored the strain variation of a battery cell during low rate charge and discharge cycles over one month under constant climate conditions and compared the results to parallel readings of an optical spectrum analyzer with special attention to the influence of the relative air humidity. We found our low-cost interrogation unit is capable of precisely and reliably capturing the typical strain variation of a high energy pouch cell during cycling with a resolution of 1 pm and shows a humidity sensitivity of −12.8 pm per %RH.

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Monitoring the Strain Evolution of Lithium‐Ion Battery Electrodes using an Optical Fiber Bragg Grating Sensor

Cited by 69 publications

References 21 publications

In Situ Stress Measurement Techniques on Li-ion Battery Electrodes: A Review

In Situ Stress Measurement Techniques on Li-ion Battery Electrodes: A Review

Hybrid Thermo‐Electrochemical In Situ Instrumentation for Lithium‐Ion Energy Storage

Development of a Polymeric Arrayed Waveguide Grating Interrogator for Fast and Precise Lithium-Ion Battery Status Monitoring

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