Dr. Parimal Bhambare

Scopus Publications

Simulation and analysis of heat transfer in counter-flow helical double-pipe heat exchangers using CFD
Anant Sidhappa Kurhade, Gulab Dattrao Siraskar, Parimal Sharad Bhambare, Govindarajan Murali, Sushil Vijaykumar Deshpande, Pushparaj Sunil Warke, Shital Yashwant Waware
International Journal of Modern Physics C, 2025
Heat exchangers play a vital role in industrial applications by facilitating efficient thermal energy exchange between two distinct fluid streams. These fluids are separated by a solid barrier, which prevents mixing, conserves energy and reduces operational costs. To enhance the efficiency of heat exchangers, wire inserts are often incorporated into the fluid paths. These inserts increase turbulence, improve fluid mixing, and boost heat transfer rates, making the system more effective. In this study, a counter-flow helical double-pipe heat exchanger was analyzed using Computational Fluid Dynamics (CFD) through the simulation software Ansys CFX. The simulations were conducted for cold fluid temperatures ranging from 12°C to 22°C and hot fluid temperatures between 32°C and 52°C, with Reynolds numbers varying from [Formula: see text] to [Formula: see text] to capture a broad spectrum of flow behaviors. The CFD model demonstrated excellent agreement with experimental results, achieving high correlation coefficients of 0.96 for the hot fluid and 0.95 for the cold fluid. This high level of accuracy validates the robustness of the model in predicting real-world heat transfer dynamics. The inclusion of wire inserts within the cold fluid flow path played a critical role in enhancing heat exchanger performance. By inducing turbulence, the wire inserts disrupted the thermal boundary layer, allowing for greater heat transfer between the hot and cold streams. This resulted in a substantial improvement in heat transfer rates, reaching a 25% increase under optimized conditions. This also led to an improved temperature difference between the fluid at the inlet and outlet, optimizing the thermal performance of the exchanger. Alternative materials such as aluminum or titanium could also be considered for wire inserts, potentially improving thermal efficiency at varying costs.
Numerical Simulation and Investigation of Flow Patterns Around Three Side-by-Side Cylinders Arranged in Line with an Oscillating Central Cylinder
Akshay Manikjade, Nitin Ambhore, Sandeep Kore, Dattatraya Nalawade, Disha Wankhede, Vidya Gaikwad
Cfd Letters, 2025
A flow past three cylinders arranged in a vertical row in a side-by-side configuration in which both side cylinders were kept fixed and an oscillatory movement provided to the middle cylinder was simulated. This particular configured setup holds significant importance in engineering and presents a compelling resemblance to numerous real-world scenarios especially in electricity production using oscillatory motion. In the present study, free-stream flow across three side-by-side cylinders with a transversely oscillating middle cylinder, was simulated using the commercial CFD software tool ANSYS 2021 R2 at a low Reynolds number (Re) = 100, with non-dimensional cylinder spacing (s/d) = 2;. For the middle cylinder, non-dimensional amplitude (amplitude ratio), A/d = 0.5 and a frequency ratio of fe/fo=0.8, 1 and 1.2 were considered (fe/fo, where fe is the cylinder oscillation frequency and fo is the corresponding vortex shedding frequency for stationary cylinders). In this study, re-meshing was done using the dynamic mesh technique, and pre-defined oscillatory motion was provided with the help of an additionally hooked User Defined Function (UDF) in the commercial CFD software tool. The objective of the present study was to investigate the effect of governing parameters on flow physics and wake nature, as well as the effect of the flow transition on engineering parameters. The interesting finding to report here that for oscillation frequency fe/fo= 1 there exist synchronous flow confirmed from wake diagram having comparatively more drag with that of other two higher fe/fo= 1.2 and lower oscillation frequency ratio fe/fo= 0.8 for cylinder spacing (s/d) = 2.
Heat Transfer Analysis of Stratified Chilled Water Storage Tank for District Cooling Systems
Vijay W. Bhatkar, Dhiresh S. Shastri, Dinesh K. Kaithari, Parimal S. Bhambare, Girish L. Allampallewar, Amar A. Meherkar
International Journal of Heat and Technology, 2025
The cooling demand is rising exponentially across the globe due to adverse environmental conditions, Thus, needs more energy-efficient solutions for commercial and residential applications.District Cooling System (DCS) is a cost-effective method for providing comfort to consumers from a central plant through a distribution network improving the efficiency for reliable solutions in densely populated areas.The research work included designing, developing, and fabricating a DCS system for a 0.5 TR refrigeration system for learning thermal stratification in terms of thermocline thickness, figure of merit, and equivalent lost tank height for different volume flow rates of water.The system can perform experiments for charging and discharging operations to study district cooling systems.The system consists of three sections such as chiller, heating, and stratification.The stratification tank has centrally located ten temperature sensors to measure the temperature drop between the cold and warm water to measure the mixing intensity.It is found that the thermocline thickness is 0.175 m, the figure of merit for half-cycle is 0.9, and the equivalent lost tank height is 0.07 for a water flow rate of 100 LPH.Thus, with the DCS system, energy is saved over the conventional cooling methods with less impact on the atmosphere in terms of CO2 and GWP for sustainable growth.The CFD simulations of the thermal stratification phenomenon are performed with ANSYS to predict the performance during charging and discharging operations.CFD results are validated with the actual experimental observations for different flow rates.The relationship between mixing intensity and incoming flow is established to study thermal energy storage by stratification.It is found that a stratified chilled water storage system eliminates shortcomings of conventional ice bank storage systems due to higher power consumption for lower evaporating temperatures.Indian industry has now started using the concept of DCS system over other conventional methods as an energy conservation approach for residential and commercial heating, ventilation, air conditioning and refrigeration applications.
Evaluation measure in automatic generation control of thermal power system using optimization technique
Gulab Dattrao Siraskar, Harish Umashankar Tiwari, Vijaykumar Kisan Javanjal, Ramdas Biradar, Rahul Krishnaji Bawane, Parimal Sharad Bhambare
World Journal of Engineering, 2025
Purpose The thermal power system (TPS) application is used for the present research work to control the processing unit to offer better thermal characteristics. The purpose of this paper is to regulate the error dynamics during continuous peak load prediction. In the past, several research studies have discussed this topic based on automatic generation Control (AGC) with different control approaches, such as optimal intelligent model, gain controller, fuzzy controller and fractional order controller. However, the error dynamics are still not in an optimal status due to the sudden rise in load. So, the present study has aimed to design a novel hybrid controller for regulating the error dynamics during high-load prediction. Design/methodology/approach A novel scheme called Sequence Hyena Optimal Gain Controller (SHOGC) is used as the control mechanism for the AGC-TPS. Here, continuous peak load prediction is the key feature for attaining reduced error statistics. In addition, the incorporation of the hyena’s optimal features has helped to earn the finest optimal error dynamics in different regions. At the first two regions, TPS was designed, then for the evaluation processing, the present novel solution was evaluated for four balanced regions, and the gained error values were compared with those of other traditional models. Findings The evaluation process in the novel solution is determined in terms of settling velocity for IE, ITE, IAE and ITAE. Area 4 has the least settling time of 4.2 s in IE, 23 s in ITE, 4.2 s in IAE and 5.8 s in ITAE. Originality/value Hence, the presented model has reduced the settling time by 5% compared to other models. However, energy efficiency is not studied in this present study; in usual cases, TPS requires high energy constraints.
Artificial intelligence for sustainable environmental management in the mining sector: A review
Parimal S. Bhambare, Anant Kaulage, Milind Manikrao Darade, Govindarajan Murali, Swati Mukesh Dixit, P. S. N. Masthan Vali, Sukhadip Mhankali Chougule, Anant Sidhappa Kurhade, Chaitalee Naresh Mali
Applied Chemical Engineering, 2025
Importance: The mining industry must balance global resource demand with the urgent need to reduce environmental impacts such as air pollution, water contamination, soil degradation, and greenhouse gas emissions. Artificial Intelligence (AI) offers powerful tools to support sustainable practices by enabling predictive analytics, monitoring, and optimization. Research Gap: While AI’s potential for sustainability is recognized, existing research rarely provides systematic analysis of its specific applications in mining. Gaps remain in evaluating performance benchmarks, addressing integration challenges, and considering ethical and regulatory issues. Objective: This review examines AI applications in mining with a focus on their role in mitigating environmental impacts, identifying both opportunities and limitations in advancing sustainable operations. Methodology: The study synthesizes peer-reviewed literature and case studies, covering AI use in air quality monitoring, water resource management, soil restoration, tailings stability, energy optimization, digital twins, and ecosystem modelling. Key Findings: AI systems have achieved notable results, including >90% accuracy in slope stability prediction, 25% reduction in wastewater treatment costs, and 8–12% fuel savings through reinforcement learning. Persistent barriers include data scarcity, high computational energy demands, integration with legacy systems, and limited interpretability of deep learning models. Implications: This review highlights AI’s potential to significantly reduce the environmental footprint of mining if implemented responsibly. Approaches such as explainable AI, federated learning, and energy-efficient frameworks are essential to ensure transparency, scalability, and sustainable long-term adoption
Enhancing Smartphone Circuit Cooling: A Computational Study of PCM Integration
Anant Sidhappa Kurhade, Gulab Dattrao Siraskar, Parimal Sharad Bhambare, Dinesh Keloth Kaithari, Swati Mukesh Dixit, Shital Yashwant Waware
Journal of Advanced Research in Numerical Heat Transfer, 2024
Modern smartphones are used for a wide range of demanding tasks, such as gaming, high-resolution photography, and internet browsing, which significantly increases their power consumption. This excessive power use leads to higher heat generation within the device, typically between 2 and 6 watts. To manage this heat and maintain optimal performance, smartphones employ various cooling techniques. A new mobile cooling method could use innovative approaches like advanced phase change materials, liquid cooling systems, or emerging technologies such as thermoelectric and microfluidic cooling. This paper proposes a new cooling method using phase change materials. This approach leverages the material's ability to absorb heat by transitioning from a solid to a liquid state and vicecersa. This helps keep the device's temperature below 45 degrees Celsius. In mid-range smartphones, cooling methods such as natural convection, indirect heat-pipe cooling, and forced convection are commonly used, but these methods often fail under high-power usage conditions.
Computational Study on Thermal Management of IC Chips with Phase Change Materials
Anant Sidhappa Kurhade, Parimal Sharad Bhambare, Gulab Dattrao Siraskar, Swati Mukesh Dixit, Pramod S. Purandare, Shital Yashwant x Shital Yashwant Waware
Journal of Advanced Research in Numerical Heat Transfer, 2024
This paper presents an implicit transient numerical formulation for a novel passive thermal management system using minichannels to cool heterogeneous IC chips on a substrate board. The proposed design incorporates phase change materials (PCM) within minichannels situated around the periphery of the IC chips. By direct conduction from the substrate board, the PCM absorbs latent heat, facilitating its phase transition from solid to liquid, thereby enhancing the thermal cooling performance of the system. The study compares the thermal performance of three configurations: a system without PCM, a system with minichannel-coupled PCM, and an optimized single minichannel positioned near the heat source. The effectiveness of different PCMs, namely paraffin wax, N-Eicosane, and ATP 78, is also evaluated. Results indicate that N-Eicosane outperforms the other PCMs in providing effective cooling. Specifically, the implementation of N-Eicosane PCM results in a system temperature reduction from 53.234°C in the generic model to 51.520°C. This constitutes a significant temperature drop of 1.74°C compared to the generic model, with an additional reduction of 0.5°C and 1.35°C when compared to paraffin wax and ATP 78 PCM, respectively.
Investigating the Effect of Heat Transfer Influenced by the Application of Wavy Corrugated Twisted Tape Inserts in Double Pipe Heat Exchangers
Anant Sidhappa Kurhade, Parimal Sharad Bhambare, Vijay Pandurang Desai, Govindarajan Murali, Rahul Shivaji Yadav, Prashant Patil, Tushar Gadekar, Ramdas Biradar, Swanand Kirpekar, Girish Anant Charwad, Shital Yashwant Waware
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2024
This study investigates the heat transfer and friction factor characteristics in a heat exchanger utilizing copper wavy (corrugated) twisted tape inserts. By inducing turbulent flow within the inner tube of the heat exchanger, these inserts generated increased turbulence, thereby enhancing heat transfer and causing a rise in pressure drop. The copper twisted tapes, with various twist ratios (TR=10.7, 8.5, 7.1), measured 1 meter in length and 14 mm in width. The heat exchanger's outer tube was made of mild steel, with an outer diameter of 0.0198 m and an inner diameter of 0.0142 m, while the inner tube was constructed of copper, with an outer diameter of 0.038 m and an inner diameter of 0.032 m. The overall length of the pipe-in-pipe heat exchanger was 1.4 m. Bulk mean temperatures were recorded at different positions for various water flow rates, and new correlations for the Nusselt number and friction factor were derived from the results for the twisted tape inserts. The Reynolds number ranged from 5000 to 17000. Comparative analyses revealed that the wavy twisted tape with a twist ratio of 7.1 provided the highest heat transfer rate, showing a 172% increase in the Nusselt number and a 32.11% increase in the friction factor relative to a smooth tube.
Wind Rose Analysis of Temperature Variation with Sensor Implantation Technique for Wind Turbine
Anant Sidhappa Kurhade, Pushparaj Warke, Kamalkishor Maniyar, Parimal Sharad Bhambare, Shital Yashwant Waware, Sushil Deshpande, Sunilkumar Harsur, Murlidhar Ingle, Pankaj Kolhe, Prashant Ashok Patil, Pallavi Jadhav, Prajakta Pawar
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2024
This study focuses on analysing the impact of seasonal variations in heat on different parts of a "wind energy system," serving as a representative mechanical system. The proposed methodology utilizes wind rose analysis, offering a straightforward means to assess heat transfer effects, applicable to any mechanical system comprising numerous small heat-dissipating components. Furthermore, this work elucidates the correlation between mechanical component performance and heat dissipation impact, providing breakdown alerts for various wind turbine components. Additionally, it analyses the influence of mechanical part temperatures on energy generation, highlighting how high temperatures can indicate component deterioration, such as bearing damage. Notably, the study focuses on wind speeds ranging from 10 to 15 m/s, a typical operational range for wind turbines. By employing wind rose charts and real-time readings, the graded heat dissipating potential of mechanical parts under various wind velocities and weather conditions is determined. Moreover, the study emphasizes the significance of heat transfer analysis in optimizing wind turbine performance, demonstrating how temperature differentials between mechanical components and the environment, along with increased surface area, affect heat transfer. The proposed analysis underscores the importance of considering heat's impact on each mechanical component in tandem with seasonal environmental temperature fluctuations. The wind rose methodology, integrated with sensor implantation, emerges as a cost-effective tool for studying -level heat variances in mechanical systems, enabling the development of heat profiles for future turbine designs and computational fluid dynamics (CFD) analyses. As heat transfer coefficient increases the wind turbine performance decrease. The heat transfer coefficient decreases 14.28% from rainy to winter season and 42.85% from winter to summer season. The wind rose analysis provides valuable insights into wind patterns and characteristics at a specific location, which can inform decision-making in various fields such as energy, construction, environmental management, and safety planning. As the turbine temperature increases the wind velocity decreases. Here it decreases 28 % from rainy to winter season.
Experimental Investigation of Heat Transfer from Symmetric and Asymmetric IC Chips Mounted on the SMPS Board with and without PCM
Anant Sidhappa Kurhade, Arjun Arun Kadam, Ramdas Biradar, Parimal Sharad Bhambare, Tushar Gadekar, Prashant Patil, Rahul Shivaji Yadav, Shital Yashwant Waware
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2024
In the present study the experiments were conducted on steady-state that incorporated nine symmetric and asymmetric separate discrete integrated circuits (ICs), strategically positioned at different locations on a substrate board, both with and without phase-change material (PCM). These ICs were subjected to varying levels of heat flux. It has been noted that the temperature is highly influenced by variables such as the size and positions of integrated circuits (ICs), the heat flux applied to the ICs. Furthermore, the non-dimensional geometric distance parameter, λ, is notably affected by both the size and positioning of the ICs. It's observed that at a higher value of λ (0.19), the temperature decreases by 18.79% at a velocity of 3 m/s and by 26.48% at a velocity of 5 m/s without PCM. With PCM, the temperature drop is 23.58% at 3 m/s and 32.47% at 5 m/s. The correlation shows a regression of 0.97 and an RMS error of 0.012%. A proposed correlation establishes a connection between θ (non-dimensional temperature) and λ, suggesting that the maximum non-dimensional temperature (θ) decreases with an increase in λ. This implies that the maximum temperature of the integrated circuits (ICs) is reduced at higher λ values. These findings provide valuable insights for thermal design engineers, aiding them in optimizing the placement of integrated circuits (ICs) to improve the reliability and lifespan of the ICs.
Performance Analysis of Corrugated Twisted Tape Inserts for Heat Transfer Augmentation
Anant Sidhappa Kurhade, Govindarajan Murali, Pallavi Abhinandan Jadhav, Parimal Sharad Bhambare, Shital Yashwant Waware, Tushar Gadekar, Rahul Shivaji Yadav, Ramdas Biradar, Prashant Patil
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2024
The Impact of Circular Holes in Twisted Tape Inserts on Forced Convection Heat Transfer
Anant Sidhappa Kurhade, Gulab Dattrao Siraskar, Swapna Swapnil Jawalkar, Tushar Gadekar, Parimal Sharad Bhambare, Ramdas Biradar, Rahul Shivaji Yadav, Shital Yashwant Waware, Chaitalee Naresh Mali
Journal of Mines Metals and Fuels, 2024
Numerical Investigation on the Influence of Substrate Board Thermal Conductivity on Electronic Component Temperature Regulation
Anant Sidhappa Kurhade, Gulab Dattrao Siraskar, Parimal Sharad Bhambare, Swati Mukesh Dixit, Shital Yashwant Waware
Journal of Advanced Research in Numerical Heat Transfer, 2024
A Comprehensive Review of Electronic Cooling Technologies in Harsh Field Environments: Obstacles, Progress, and Prospects
Anant Sidhappa Kurhade, Nitin Babanrao Kardekar, Parimal Sharad Bhambare, Shital Yashwant Waware, Rahul Shivaji Yadav, Prajakta Pawar, Swanand Kirpekar
Journal of Mines Metals and Fuels, 2024
Electrode selection and catalyst evaluation in hydrogen production from alkaline water electrolysis: A review
Santosh Walke, Parimal Bhambare, Syed Rizwan, Shabib Al Rashdi
Chemical and Process Engineering New Frontiers, 2024
The Heat Transfer and Fluid Flow Investigations of Single Dimple with Straight and Curved Arch Turbulator within in a Duct
Sandeep Sadashiv Kore, Manoj Kumar Chaudhary, Parimal Sharad Bhambare, Dinesh Keloth Kaithari
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2024
Machine Learning-Based Optimization of Electrolysis Parameters in Green Hydrogen Production
Santosh Walke, Shabib Al Rashdi, Syed Mohammed Rizwan, Parimal Bhambare
2024 International Conference on System Computation Automation and Networking Icscan 2024, 2024
A Comprehensive Study on Calophyllum inophyllum Biodiesel and Dimethyl Carbonate Blends: Performance Optimization and Emission Control in Diesel Engines
Anant Sidhappa Kurhade, Shital Yashwant Waware, Parimal Sharad Bhambare, Ramdas Biradar, Rahul Shivaji Yadav, Vaishali N. Patil
Journal of Mines Metals and Fuels, 2024
Performance enhancement of Scheffler concentrator receiver using Conical type Secondary Reflector (CSR) fitted with toughened glass cover
Khalil Abdullah Saleh AL-Nassri, Parimal S. Bhambare, Sudhir Chitrapady Vishweshwara, Manik C. Majumder
Materials Today Proceedings, 2023
Design aspects of a fixed focus type Scheffler concentrator and its receiver for its utilization in thermal processing units
Parimal Sharad Bhambare, Sudhir Chitrapady Vishweshwara
Energy Nexus, 2022
Technical analysis of Solar Scheffler concentrator for its energy availability, and the weather data conditions at Al Seeb Oman
Parimal S. Bhambare, C. V. Sudhir, Varghese Manapallil Joy
2022 Sardar Patel International Conference on Industry 4 0 Nascent Technologies and Sustainability for Make in India Initiative Spicon 2022, 2022
Experimental determination of forced convection heat transfer over a plate with nozzle plate
Rupesh Yadav, Sandeep Kore, Parimal Bhambare, Dhanpal Kamble, R.N. Todkar
Materials Today Proceedings, 2021
Solar thermal energy utilization using metal fiber reinforced concrete (MFRC) collector for producing hot water in sultanate of Oman
, Talal Mohammed Al Hoqani, Parimal S. Bhambare*, , Dinesh K. Kaithari, and
International Journal of Innovative Technology and Exploring Engineering, 2019
Decentralized stand-alone Multi Effect Desalination (MED) system using fixed focus type Scheffler concentrator for the remote and arid rural regions of Sultanate of Oman
Parimal S. Bhambare, M. C. Majumder, C. V. Sudhir
Iop Conference Series Materials Science and Engineering, 2018
Brine heat recovery unit for Multi Effect Desalination (MED) system based on Scheffler Concentrator using shell and coil heat exchanger
Parimal S. Bhambare, M. C. Majumder, C. V. Sudhir
Iop Conference Series Materials Science and Engineering, 2018
Electrically Operated Multipurpose Trolley
Al Sult Al Kharusi, Dinesh Keloth kaithari, Muhammad Mumtaz Mirza, Parimal S. Bhambare
Iop Conference Series Materials Science and Engineering, 2018
Solar thermal desalination: A sustainable alternative for Sultanate of Oman
International Journal of Renewable Energy Research, 2018

Dr. Parimal Bhambare

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