FEA Analysis of Double Tube Heat Exchanger on Variable Baffle Pitch for Optimizing Thermal Efficiency
DOI:
https://doi.org/10.24113/ijoscience.v6i6.291Keywords:
CFD, helical baffle, ANSYS, heat exchangerAbstract
The main objective of this work is to compare different configurations of helical baffles in the cold fluid side of a double tube heat exchanger. For this analysis double pipe heat exchangers are divided into three different domains such as two fluid domains hot fluid in the inner tube and cold fluid in the outer pipe and a solid domain as helical baffles on inner tube of hot fluid. The hot water flows inside the heat exchanger tube, while the cold fluid flows in the outer side in the direction of counter flow. Mass flow rate cold fluid was varied from 0.1 kg/s to 0.3 kg/s while the flow rate in the inner tube i.e. hot water was kept constant at 0.1 kg/s. the inlet temperature of hot fluid taken as 40oC while Cold fluid inlet temperature taken as 15oC. The fluent software is used to calculate the fluid flow and heat transfer in the computational domains. The governing equations are iteratively solved by the finite volume formulation with the SIMPLE algorithm. Results show that that the maximum temperature drop of 10.9 oC for hot fluid and the maximum temperature rise of 11.9 oC for cold fluid are observed at 0.3 kg/sec mass flow rate for double pipe heat exchanger with double helical baffles. It has been also observed that the heat transfer coefficient increasing with the increasing in the mass flow rate of cold fluid. The overall heat transfer coefficients differ significantly by 20.4 % at same mass flow rate, because the considerable difference between heat transfer surface area on the inner and outer side of the tube resulting in a prominent thermal enhancement of the cold fluid.
Downloads
References
[2] Ganesh Kumar Poongavanam at el. “Experimental investigation on heat transfer and pressure drop of MWCNT - solar glycol based nanofluids in shot peened double pipe heat exchanger” Accepted on: 18 January 2019.
[3] Rafa? Andrzejczyk, Tomasz Muszynski & Przemyslaw Kozak “Experimental investigation of heat transfer enhancement in straight and Ubend double-pipe heat exchanger with wire insert” Chemical Engineering & Processing: Process Intensification, Vol. 136, year 2019, page from 177–190.
[4] Anas El Maakoul at el. “Numerical design and investigation of heat transfer enhancement and performance for an annulus with continuous helical baffles in a double-pipe heat exchanger” Energy Conversion and Management, vol. 133, year 2017, page from 76–86.
[5] Yadav, S., & Sahu, S. K. “Heat transfer augmentations in double pipe water to air counter flow heat exchanger with helical surface disc turbulators” Chemical Engineering and Processing: Process Intensification. Vol. 135, year 2019, page from 120–132.
[6] M. Sridharan, R. Devi, C.S. Dharshini & M. Bhavadarani “IoT based performance monitoring and control in counter flow double pipe heat exchanger” Internet of Things Vol. 5, Year 2019, page from 34–40.
[7] Xue Chen at el. “Conjugated heat transfer analysis of a foam filled double-pipe heat exchanger for high-temperature application” International Journal of Heat and Mass Transfer Vol. 134, Year 2019, Page from 1003–1013.
[8] Wei Wang, Yaning Zhang, Kwan-Soo Lee & Bingxi Li “Optimal design of a double pipe heat exchanger based on the outward helically corrugated tube” International Journal of Heat and Mass Transfer Vol. 135, Year 2019, page from 706–716.
[9] Heydar Maddah at el. “Factorial experimental design for the thermal performance of a double pipe heat exchanger using Al2O3-TiO2 hybrid nanofluid” International Communications in Heat and Mass Transfer, Vol. 97, year 2018, page from 92–102.
[10] Mohammad Mahdi Heyhat, Adel Abdi & Ali Jafarzad “Performance Evaluation and Exergy Analysis of a Double Pipe Heat Exchanger under Air Bubble Injection” Accepted on: 27 July 2018, Applied Thermal Engineering, 2018.
Downloads
Published
Issue
Section
License
Copyright (c) 2020 Anil Kumar, Rashmi dwivedi, Sanjay Chhalotre
This work is licensed under a Creative Commons Attribution 4.0 International License.
IJOSCIENCE follows an Open Journal Access policy. Authors retain the copyright of the original work and grant the rights of publication to the publisher with the work simultaneously licensed under a Creative Commons CC BY License that allows others to distribute, remix, adapt, and build upon your work, even commercially, as long as they credit you for the original creation. Authors are permitted to post their work in institutional repositories, social media or other platforms.
Under the following terms:
-
Attribution — You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use.
- No additional restrictions — You may not apply legal terms or technological measures that legally restrict others from doing anything the license permits.
