A review of energy storage technologies for demand-side management in industrial facilities

Elio, Joseph; Phelan, Patrick E.; Villalobos, J. René; Milcarek, Ryan J.

doi:10.1016/j.jclepro.2021.127322

Cited by 56 publications

(17 citation statements)

References 10 publications

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“…These include applications in air separation, ammonia production, chlor‐alkali production, and glass processing, all of which are cited in Table 3. Other studies considered the advantages of different types of storage in manufacturing facilities as a means of load shifting 93 as well as the integration of renewable sources for demand response 94 . The US Department of Energy's Better Plants Program has defined a demand response hierarchy in which eliminating load is defined as having the greatest impact on facility demand, but generation allows for the most future load growth with efficiency upgrades and load shifting in the middle 10 .…”

Section: Five Improvement Areasmentioning

confidence: 99%

Grid‐responsive smart manufacturing: A perspective for an interconnected energy future in the industrial sector

Billings

Powell

2022

AIChE Journal

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With the growing amount of renewable energy sources, the grid has become responsible for accounting for intermittency and the flexibility needed to utilize dynamic sources. Expensive peaking plants and energy storage systems have been proposed as ways to mitigate those problems. There is a large group of energy consumers that can respond to grid conditions. Historically, these consumers have been residential and commercial users, but with modern innovations and practices, industrial consumers have the potential to become a major player in this space. Grid‐responsive smart manufacturing can be used to utilize modern tools in manufacturing innovation as enablers for grid response. These modern tools already exist but are not widely used for industrial grid‐side energy management. This article defines grid‐responsive smart manufacturing, identifies five major barriers to its widespread implementation, and portrays the path to getting industrial users to be key players in grid stability and flexibility.

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Section: Five Improvement Areasmentioning

confidence: 99%

Grid‐responsive smart manufacturing: A perspective for an interconnected energy future in the industrial sector

Billings

Powell

2022

AIChE Journal

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“… [1] In the current competition to meet the accelerating demand for energy storage technologies, sodium‐ion (Na‐ion) battery development lags that of lithium ion (Li‐ion), Zn‐Air, and redox flow batteries. [2] Na‐ion batteries have several advantages that make them worth pursuing, and they could avoid supply constraints and cost increases as the demand for Li‐ion batteries increases exponentially with the move to electrify vehicle fleets across the world. Alongside cost and supply issues, the use of materials with lower embodied energy and higher abundance than in Li‐ion batteries reduces their environmental impact of manufacture.…”

Section: Introductionmentioning

confidence: 99%

Process‐Structure‐Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review

Sawhney

Wahid²,

Griffin

et al. 2022

ChemPhysChem

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Before the viability of a cell formulation can be assessed for implementation in commercial sodium ion batteries, processes applied in cell production should be validated and optimized. This review summarizes the steps performed in constructing sodium ion (Na‐ion) cells at research scale, highlighting parameters and techniques that are likely to impact measured cycling performance. Consistent process‐structure‐performance links have been established for typical lithium‐ion (Li‐ion) cells, which can guide hypotheses to test in Na‐ion cells. Liquid electrolyte viscosity, sequence of mixing electrode slurries, rate of drying electrodes and cycling characteristics of formation were found critical to the reported capacity of laboratory cells. Based on the observed importance of processing to battery performance outcomes, the current focus on novel materials in Na‐ion research should be balanced with deeper investigation into mechanistic changes of cell components during and after production, to better inform future designs of these promising batteries.

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“…Energy storage can solve the above issues and has drawn a lot of attention in the last decades. Depending on the form of energy to be stored, different forms of energy storage technologies have been developed, including electrical energy storage, mechanical energy storage, and thermal energy storage . Among these technologies, thermal energy storage has been considered as an important pathway toward enhanced energy efficiency and decarbonization because 90% of the total energy use is related to the generation or utilization of heat. , …”

Section: Introductionmentioning

confidence: 99%

“…Depending on the form of energy to be stored, different forms of energy storage technologies have been developed, including electrical energy storage, mechanical energy storage, and thermal energy storage. 2 Among these technologies, thermal energy storage has been considered as an important pathway toward enhanced energy efficiency and decarbonization because 90% of the total energy use is related to the generation or utilization of heat. 3,4 In the application of solar thermal energy utilization for domestic heating supply, thermal energy storage is the most suitable and direct way, which can be further classified into sensible heat storage, latent heat storage, and thermochemical heat storage.…”

Section: Introductionmentioning

confidence: 99%

High-Performance Absorption Thermal Storage with Once-Through Discharging

Wang

2022

ACS Sustainable Chem. Eng.

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Absorption thermal storage is attractive for stable storage of solar thermal energy. However, traditional cycle considers discharging higher than a certain temperature, which neglects the temperature matching between the discharging process and the external heat source. This limits its performance under heat output with a large temperature glide from two aspects: large temperature lift and high irreversible loss. To solve this issue, an absorption thermal storage cycle with once-through discharging is proposed. Solution is circulated from a fully charged state to a fully discharged state during the once-through absorption, resulting in large concentration and temperature glides. Higher energy storage density (ESD), better temperature matching, and stable output temperature can be achieved. Modeling results show that the proposed cycle with LiBr–water obtains a coefficient of performance of 0.89 and an ESD of 764 kJ/kg under typical conditions, which are 4.9 and 21.8 times higher than those of the conventional cycle. The proposed cycle with superior performance as well as the joint consideration of the thermodynamic cycle and heat exchange in absorption thermal storage could be helpful for future studies.

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A review of energy storage technologies for demand-side management in industrial facilities

Cited by 56 publications

References 10 publications

Grid‐responsive smart manufacturing: A perspective for an interconnected energy future in the industrial sector

Grid‐responsive smart manufacturing: A perspective for an interconnected energy future in the industrial sector

Process‐Structure‐Formulation Interactions for Enhanced Sodium Ion Battery Development: A Review

High-Performance Absorption Thermal Storage with Once-Through Discharging

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