Unpublished
Alessia Romani*, Abolfazl Taherzadeh Fini, Megan Cockburn, Anthony Straatman, Joshua M. Pearce
SSRN, 2026 Jan
SSRN, 2026 Jan
DOI:
10.2139/ssrn.6126577
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APA
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Romani*, A., Fini, A. T., Cockburn, M., Straatman, A., & Pearce, J. M. (2026, January). Design and Validation of Cost-effective Customizable 3-D Printed Phase-Change Material-based Thermal Energy Storage Modules. SSRN. https://doi.org/10.2139/ssrn.6126577
Chicago/Turabian
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Romani*, Alessia, Abolfazl Taherzadeh Fini, Megan Cockburn, Anthony Straatman, and Joshua M. Pearce. “Design and Validation of Cost-Effective Customizable 3-D Printed Phase-Change Material-Based Thermal Energy Storage Modules.” SSRN, January 2026.
MLA
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Romani*, Alessia, et al. “Design and Validation of Cost-Effective Customizable 3-D Printed Phase-Change Material-Based Thermal Energy Storage Modules.” SSRN, Jan. 2026, doi:10.2139/ssrn.6126577.
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@unpublished{alessia2026a,
title = {Design and Validation of Cost-effective Customizable 3-D Printed Phase-Change Material-based Thermal Energy Storage Modules},
year = {2026},
month = jan,
journal = {SSRN},
doi = {10.2139/ssrn.6126577},
author = {Romani*, Alessia and Fini, Abolfazl Taherzadeh and Cockburn, Megan and Straatman, Anthony and Pearce, Joshua M.},
month_numeric = {1}
}
Abstract
The increasing demand for thermal energy in residential and industrial sectors highlights the need for reliable and efficient thermal energy storage solutions. Phase-change material-based thermal energy storage systems offer high-density heat retention, but laboratory-scale setups often rely on expensive hardware, limiting customization for iterative experimental testing and validation. This work presents the design, fabrication, and validation of a cost-efficient, customizable, open-source phase-change material-based thermal energy storage unit based on parametric modeling and fused filament fabrication 3D printing. After developing the parametric 3D model, a customized module was fabricated to validate the approach through thermal, numerical, and economic analyses. The parametric model enables rapid iterative customization using low-cost 3D printers, commercially available materials, and off-the-shelf components. Experimental validation demonstrated its reliability under hydrostatic leakage tests and repeated thermal cycles, using circular finned tubes as heat transfer elements and n-octadecane as the storage material. Increasing the heat transfer fluid flow rate from 0.0033 kg·s⁻¹ to 0.0105 kg·s⁻¹ enhanced heat transfer performance and reduced melting and solidification times by approximately 36% and 39%, whereas thermal imaging confirmed uniform temperature propagation within the cavity. A calibrated numerical model reproduced melting and solidification behavior with 13% and 14% prediction error. The complete prototype costs 644.88 USD, with 3D-printed parts below 4% of the total and a cost per cycle of 6.45 USD over 100 cycles. The results demonstrate an accessible approach to experimental research on phase-change material-based thermal energy storage, addressing the need for affordable, customizable setups for sustainable and renewable energy applications. 1
Romani, A., Taherzadeh Fini, A., Cockburn, M., Straatman, A., and Pearce, J.M., 2026. Design and Validation of Cost-effective Customizable 3-D Printed Phase-Change Material-based Thermal Energy Storage Modules. Available at SSRN. DOI: 10.2139/ssrn.6126577
Resources and links
Romani, A., Taherzadeh Fini, A., Cockburn, M., Straatman, A., and Pearce, J.M., 2026. Design and Validation of Cost-effective Customizable 3-D Printed Phase-Change Material-based Thermal Energy Storage Modules. Available at SSRN. DOI: 10.2139/ssrn.6126577
Romani, A., Taherzadeh Fini, A., Cockburn, M.R., Straatma, A.G., Pearce, J.M. 2024. Design and manufacturing of a customizable 3D printable phase-change material based thermal battery module. Project repository. Available at OSF.io. LINK: https://osf.io/rucqy/overview
The Customizable Thermal Energy Storage Module is an Open Source Hardware Educational Tool certified by OSHWA (Open Source Hardware Association), released under the CERN-OHL-S-2.0 (hardware and documentation) and GNU General Public License (GPL) 3.0. (software).
- ✅ Certified Open Hardware - OSHWA UID CA000071 (Certification, license, and links) 4
Western University - FAST Lab. 2026. Open-Source Customizable Thermal Energy Storage Module for experimental research. Certification. Available at OSHWA.org. Link: https://certification.oshwa.org/ca000071.html
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Romani, A., Taherzadeh Fini, A., Cockburn, M., Straatman, A., and Pearce, J.M., 2026. Design and Validation of Cost-effective Customizable 3-D Printed Phase-Change Material-based Thermal Energy Storage Modules. Available at SSRN. DOI: 10.2139/ssrn.6126577 ↩
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Romani, A., Taherzadeh Fini, A., Cockburn, M., Straatman, A., and Pearce, J.M., 2026. Design and Validation of Cost-effective Customizable 3-D Printed Phase-Change Material-based Thermal Energy Storage Modules. Available at SSRN. DOI: 10.2139/ssrn.6126577 ↩
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Romani, A., Taherzadeh Fini, A., Cockburn, M.R., Straatma, A.G., Pearce, J.M. 2024. Design and manufacturing of a customizable 3D printable phase-change material based thermal battery module. Project repository. Available at OSF.io. LINK: https://osf.io/rucqy/overview ↩
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Western University - FAST Lab. 2026. Open-Source Customizable Thermal Energy Storage Module for experimental research. Certification. Available at OSHWA.org. Link: https://certification.oshwa.org/ca000071.html ↩