Search

Your search keyword '"Kishore, Ravi Anant"' showing total 156 results
Start Over Author "Kishore, Ravi Anant" Publication Year Range Last 50 years
156 results on '"Kishore, Ravi Anant"'

1. Model-driven development of durable and scalable thermal energy storage materials for buildings

Author

Cui, Shuang, Kishore, Ravi Anant, Kolari, Pranvera, Zheng, Qiye, Kaur, Sumanjeet, Vidal, Judith, and Jackson, Roderick

Subjects
Engineering, Materials Engineering, Affordable and Clean Energy, Durability, Thermal energy storage, Shape -stabilized phase change materials, Tunable thermal properties, Thermal modeling, Mechanical Engineering, Resources Engineering and Extractive Metallurgy, Interdisciplinary Engineering, Energy, Electrical engineering, Fluid mechanics and thermal engineering, Mechanical engineering
Abstract

The energy impact of integrating phase change materials (PCMs) in buildings for thermal energy storage has been modeled by various whole-building simulation programs, demonstrating that PCM incorporation can reduce energy consumption, provide grid flexibility and resilience, and reduce CO2 emissions. The models assume that the PCMs are in perfect operating condition and underestimate the impact of actual phase change behavior (e.g., enthalpy curve shape) on thermal load shifting in practical deployment. In this paper, we bridge the gap between theory and practice when evaluating the energy impact of PCMs by using a model-driven approach to develop durable thermal energy storage materials with desired phase change properties. For ease of integration, we fabricate shape-stabilized PCMs (ss-PCMs) by encapsulating solid-liquid polyethylene glycol (PEG) consisting of different molecular weights within mesoporous magnesium oxide (MgO) matrices. Learning from the modeling results, we manipulate phase change properties such as peak melting temperature and temperature glide of PEG-MgO ss-PCMs during the synthesis process to achieve desired properties. As such, the energy density is maximized within the optimum operating temperature range, which is critical to boosting energy efficiency. Compared to a case with no PCM, a layer of PEG-MgO ss-PCM integrated into the wall provides a 50% reduction in the peak load and also exhibits a repeatable phase change behavior for up to 1000 thermal cycles without leakage, showing durability of this material. We also show that this lab-scale synthesis process is easy to be scaled up by 100 times for a demonstration of large-scale industrial production. The synthetic tunability of transition temperature of ss-PCMs also extends their applicability beyond buildings.

Published
2023

9. Contributors

Author

Cheng, Chun, primary, Clark, Ruby-Jean, additional, Du, Minzhi, additional, Duan, Jiangjiang, additional, Farid, Mohammed, additional, Feng, Shien-Ping, additional, Garcia, Santiago, additional, Jiang, Wan, additional, Kang, Tae June, additional, Kim, Ju Hyeon, additional, Kishore, Ravi Anant, additional, Li, Wei, additional, Liu, Yuchen, additional, Lu, Chunhong, additional, Ni, Meng, additional, Shu, Gequn, additional, Sun, Tingting, additional, Tian, Hua, additional, Wang, Lianjun, additional, Wang, Jilong, additional, Wang, Shiren, additional, Wang, Sijia, additional, Wang, Hui, additional, Wang, Weiguang, additional, Yu, Boyang, additional, Zhang, Kun, additional, Zheng, Yuanyuan, additional, Zhou, Jun, additional, Zhu, Xiuping, additional, and Zhuang, Xinyan, additional

Published
2022
Full Text
View/download PDF

15. Sustainable cooling solutions

Author

Ghaddar, Nesreen, Kishore, Ravi Anant, Menberg, Kathrin, Ndukwu, Macmanus Chinenye, Hou, Huilong, Islam, Rashedul, Sahin, Ezgi Bay, Sett, Soumyadip, and Mandal, Jyotirmoy

Abstract

In this warming world, excessive heat is burning cities from the south to the north. Cooling technologies have been available for decades, but many, like air conditioners, can themselves be a source of heat and emissions that exacerbate local heat island effects and contribute to climate change. Furthermore, cooling solutions are often out of reach for the most vulnerable people. This Voices asks: what is the path to sustainable cooling technologies for all?

Published
2024
Full Text
View/download PDF

22. Linear thermomagnetic energy harvester for low-grade thermal energy harvesting.

Author

Kishore, Ravi Anant, Singh, Deepa, Sriramdas, Rammohan, Garcia, Anthony Jon, Sanghadasa, Mohan, and Priya, Shashank

Subjects
*ENERGY harvesting, *MAGNETISM, *THERMOMAGNETIC effects, *POWER density, *WASTE heat, *HEAT, *FREQUENCIES of oscillating systems
Abstract

Low-grade thermal energy, either from waste heat or from natural resources, constitutes an enormous energy reserve that remains to be fully harvested. Harvesting low-grade heat is challenging because of the low Carnot efficiency. Among various thermal energy harvesting mechanisms available for capturing low-grade heat (temperature less than 100 °C), the thermomagnetic effect has been found to be quite promising. In this study, we demonstrate a scalable thermomagnetic energy harvester architecture that exhibits 140% higher power density compared to the previously published spring–mass designs. The alternating force required to oscillate the thermomagnetic mass is generated through the interaction between two magnetic forces in opposite directions. We employed numerical modeling to illustrate the behavior of a thermomagnetic device under different operating conditions and to obtain the optimal hot-side and cold-side temperatures for continuous mode operations. A miniaturized thermomagnetic harvester was fabricated and experiments were conducted to systematically evaluate the performance. The prototype was found to exhibit an oscillation frequency of 0.33 Hz, a work output of 0.6 J/kg/cycle, and a power density of 0.2 W/kg of gadolinium under the temperature difference of 60 K. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

31. 3D printed graphene-based self-powered strain sensors for smart tires in autonomous vehicles

Author

Mechanical Engineering, Materials Science and Engineering, Electrical and Computer Engineering, Institute for Critical Technology and Applied Science, Center for Tire Research, Maurya, Deepam, Khaleghian, Seyedmeysam, Sriramdas, Rammohan, Kumar, Prashant, Kishore, Ravi Anant, Kang, Min-Gyu, Kumar, Vireshwar, Song, Hyun-Cheol, Lee, Seul-Yi, Yan, Yongke, Park, Jung-Min (Jerry), Taheri, Saied, Priya, Shashank, Mechanical Engineering, Materials Science and Engineering, Electrical and Computer Engineering, Institute for Critical Technology and Applied Science, Center for Tire Research, Maurya, Deepam, Khaleghian, Seyedmeysam, Sriramdas, Rammohan, Kumar, Prashant, Kishore, Ravi Anant, Kang, Min-Gyu, Kumar, Vireshwar, Song, Hyun-Cheol, Lee, Seul-Yi, Yan, Yongke, Park, Jung-Min (Jerry), Taheri, Saied, and Priya, Shashank

Abstract

The transition of autonomous vehicles into fleets requires an advanced control system design that relies on continuous feedback from the tires. Smart tires enable continuous monitoring of dynamic parameters by combining strain sensing with traditional tire functions. Here, we provide breakthrough in this direction by demonstrating tire-integrated system that combines direct mask-less 3D printed strain gauges, flexible piezoelectric energy harvester for powering the sensors and secure wireless data transfer electronics, and machine learning for predictive data analysis. Ink of graphene based material was designed to directly print strain sensor for measuring tire-road interactions under varying driving speeds, normal load, and tire pressure. A secure wireless data transfer hardware powered by a piezoelectric patch is implemented to demonstrate self-powered sensing and wireless communication capability. Combined, this study significantly advances the design and fabrication of cost-effective smart tires by demonstrating practical self-powered wireless strain sensing capability. Designing efficient sensors for smart tires for autonomous vehicles remains a challenge. Here, the authors present a tire-integrated system that combines direct mask-less 3D printed strain gauges, flexible piezoelectric energy harvester for powering the sensors and secure wireless data transfer electronics, and machine learning for predictive data analysis.

Published
2020

32. Taguchi optimization of bismuth-telluride based thermoelectric cooler.

Author

Kishore, Ravi Anant, Kumar, Prashant, Sanghadasa, Mohan, and Priya, Shashank

Subjects
*THERMOELECTRIC generators, *THERMOELECTRIC cooling, *BISMUTH telluride, *HEAT, *ELECTRICAL energy, *ENERGY conversion
Abstract

In the last few decades, considerable effort has been made to enhance the figure-of-merit (ZT) of thermoelectric (TE) materials. However, the performance of commercial TE devices still remains low due to the fact that the module figure-of-merit not only depends on the material ZT, but also on the operating conditions and configuration of TE modules. This study takes into account comprehensive set of parameters to conduct the numerical performance analysis of the thermoelectric cooler (TEC) using a Taguchi optimization method. The Taguchi method is a statistical tool that predicts the optimal performance with a far less number of experimental runs than the conventional experimental techniques. Taguchi results are also compared with the optimized parameters obtained by a full factorial optimization method, which reveals that the Taguchi method provides optimum or near-optimum TEC configuration using only 25 experiments against 3125 experiments needed by the conventional optimization method. This study also shows that the environmental factors such as ambient temperature and cooling coefficient do not significantly affect the optimum geometry and optimum operating temperature of TECs. The optimum TEC configuration for simultaneous optimization of cooling capacity and coefficient of performance is also provided. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

33. Dual Phase Change Thermal Diodes with High Rectification for Thermal Management near Room Temperature.

Author

Kommandur, Sampath, Kishore, Ravi Anant, Booten, Chuck, Cui, Shuang, Wheeler, Lance M., and Vidal, Judith

Subjects
*THERMORESPONSIVE polymers, *COMPOSITE materials, *DIODES, *PHASE change materials, *CALCIUM chloride, *THERMAL resistance
Abstract

Thermal diodes are passive systems that modulate their thermal resistance depending on the direction of temperature gradient, thereby allowing preferential directional heat flow. A dual phase thermal diode consists of a junction between two phase change materials that have opposing temperature‐dependent thermal conductivity trends, and whose performance (i.e., rectification ratio) is related to the ratio of the thermal conductivities of the different phases. In this work, a dual phase change diode with a rectification ratio of ≈3.5 for an applied temperature bias of ≈40 K is presented, which is among the highest‐performing junction diodes based on phase change materials at the macroscale for near room temperature applications. The diode is composed of an aqueous solution of poly(N‐isopropylacrylamide), a thermo‐responsive polymer, and calcium chloride hexahydrate—a solid‐liquid phase change material. Experimental insights are provided into the contributions of different heat transfer mechanisms, conduction, and convection, and the effect of concentration of the thermo‐responsive polymer. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

36. Low-grade Thermal Energy Harvesting and Waste Heat Recovery

Author

Kishore, Ravi Anant, Mechanical Engineering, Priya, Shashank, Stokes, David, Mahajan, Roop L, and Vick, Brian L.

Subjects
Optimization, Energy harvesting, Heat recovery, Power, Thermoelectric, Taguchi, Efficiency, Thermal energy, Neural network, Thermomagnetic
Abstract

Low-grade heat, either in the form of waste heat or natural heat, represents an extremely promising source of renewable energy. A cost-effective method for recovering the low-grade heat will have a transformative impact on the overall energy scenario. Efficiency of heat engines deteriorates with decrease in hot-side temperature, making low-grade heat recovery complex and economically unviable using the current state-of-the-art technologies, such as Organic Rankine cycle, Kalina cycle and Stirling engine. In this thesis, a fundamental breakthrough is achieved in low-grade thermal energy harvesting using thermomagnetic and thermoelectric effects. This thesis systematically investigates two different mechanisms: thermomagnetic effect and thermoelectric effect to generate electricity from the low-grade heat sources available near ambient temperature to 200°C. Using thermomagnetic effect, we demonstrate a novel ultra-low thermal gradient energy recovery mechanism, termed as PoWER (Power from Waste Energy Recovery), with ambient acting as the heat sink. PoWER devices do not require an external heat sink, bulky fins or thermal fluid circulation and generate electricity on the order of 100s μW/cm3 from heat sources at temperatures as low as 24°C (i.e. just 2°C above the ambient) to 50°C. For the high temperature range of 50-200°C, we developed the unique low fill fraction thermoelectric generators that exhibit a much better performance than the commercial modules when operated under realistic conditions such as constant heat flux boundary condition and high thermally resistive environment. These advancements in thermal energy harvesting and waste heat recovery technology will have a transformative impact on renewable energy generation and in reducing global warming. PHD Energy is essential to life. While most living organisms utilize natural resources directly to meet their energy requirements, humans need electricity. Unarguably, electricity has made our lives easy; however, it is an expensive form of energy. Every year, a tremendous amount of fossil fuels is burnt to meet the ever-growing energy demand. While we are concerned due to the escalating energy prices, depleting fossil resources, and negative environmental impact, it is devastating to know that more than half of the useable energy generated from various renewable and non-renewable sources are ultimately discarded to atmosphere as byproduct, mostly in form of wasted heat. Utilizing waste heat, particularly when it occurs at low temperature, is usually complex and cost-ineffective. A cost-effective method for recovering the low-grade heat will have a transformative impact on the overall energy scenario. In this thesis, a fundamental breakthrough is achieved in developing the new/improved thermal energy harvesting methods to generate electricity from low-grade heat.

Published
2018

38. Energy scavenging from ultra-low temperature gradients

Author

Kishore, Ravi Anant, primary, Davis, Brenton, additional, Greathouse, Jake, additional, Hannon, Austin, additional, Emery Kennedy, David, additional, Millar, Alec, additional, Mittel, Daniel, additional, Nozariasbmarz, Amin, additional, Kang, Min Gyu, additional, Kang, Han Byul, additional, Sanghadasa, Mohan, additional, and Priya, Shashank, additional

Published
2019
Full Text
View/download PDF

40. Preface

Author

Kishore, Ravi Anant, primary, Stewart, Colin, additional, and Priya, Shashank, additional

Published
2018
Full Text
View/download PDF

45. 1 Introduction

Author

Kishore, Ravi Anant, primary, Stewart, Colin, additional, and Priya, Shashank, additional

Published
2018
Full Text
View/download PDF

47. A Review on Low-Grade Thermal Energy Harvesting: Materials, Methods and Devices

Author

Kishore, Ravi Anant, Priya, Shashank, Kishore, Ravi Anant, and Priya, Shashank

Abstract

Combined rejected and naturally available heat constitute an enormous energy resource that remains mostly untapped. Thermal energy harvesting can provide a cost-effective and reliable way to convert available heat into mechanical motion or electricity. This extensive review analyzes the literature covering broad topical areas under solid-state low temperature thermal energy harvesting. These topics include thermoelectricity, pyroelectricity, thermomagneticity, and thermoelasticity. For each topical area, a detailed discussion is provided comprising of basic physics, working principle, performance characteristics, state-of-the-art materials, and current generation devices. Technical advancements reported in the literature are utilized to analyze the performance, identify the challenges, and provide guidance for material and mechanism selection. The review provides a detailed analysis of advantages and disadvantages of each energy harvesting mechanism, which will provide guidance towards designing a hybrid thermal energy harvester that can overcome various limitations of the individual mechanism.

Published
2018
Full Text
View/download PDF

48. Combinatory Finite Element and Artificial Neural Network Model for Predicting Performance of Thermoelectric Generator

Author

Kishore, Ravi Anant, Mahajan, Roop L., Priya, Shashank, Kishore, Ravi Anant, Mahajan, Roop L., and Priya, Shashank

Abstract

Thermoelectric generators (TEGs) are rapidly becoming the mainstream technology for converting thermal energy into electrical energy. The rise in the continuous deployment of TEGs is related to advancements in materials, figure of merit, and methods for module manufacturing. However, rapid optimization techniques for TEGs have not kept pace with these advancements, which presents a challenge regarding tailoring the device architecture for varying operating conditions. Here, we address this challenge by providing artificial neural network (ANN) models that can predict TEG performance on demand. Out of the several ANN models considered for TEGs, the most efficient one consists of two hidden layers with six neurons in each layer. The model predicted TEG power with an accuracy of ±0.1 W, and TEG efficiency with an accuracy of ±0.2%. The trained ANN model required only 26.4 ms per data point for predicting TEG performance against the 6.0 minutes needed for the traditional numerical simulations.

Published
2018
Full Text
View/download PDF

49. Combinatory Finite Element and Artificial Neural Network Model for Predicting Performance of Thermoelectric Generator

Author

Center for Energy Harvesting Materials and Systems (CEHMS), Mechanical Engineering, Institute for Critical Technology and Applied Science, Kishore, Ravi Anant, Mahajan, Roop L., Priya, Shashank, Center for Energy Harvesting Materials and Systems (CEHMS), Mechanical Engineering, Institute for Critical Technology and Applied Science, Kishore, Ravi Anant, Mahajan, Roop L., and Priya, Shashank

Abstract

Thermoelectric generators (TEGs) are rapidly becoming the mainstream technology for converting thermal energy into electrical energy. The rise in the continuous deployment of TEGs is related to advancements in materials, figure of merit, and methods for module manufacturing. However, rapid optimization techniques for TEGs have not kept pace with these advancements, which presents a challenge regarding tailoring the device architecture for varying operating conditions. Here, we address this challenge by providing artificial neural network (ANN) models that can predict TEG performance on demand. Out of the several ANN models considered for TEGs, the most efficient one consists of two hidden layers with six neurons in each layer. The model predicted TEG power with an accuracy of ±0.1 W, and TEG efficiency with an accuracy of ±0.2%. The trained ANN model required only 26.4 ms per data point for predicting TEG performance against the 6.0 minutes needed for the traditional numerical simulations.

Published
2018

Catalog

Books, media, physical & digital resources
See catalog results