Structured porous material design for passive flow and noise control of cylinders in uniform flow
Structured porous material design for passive flow and noise control of cylinders in uniform flow
Cylindrical bodies in uniform flows can be coated with a porous medium as a passive flow and noise control method in an effort to reduce the acoustic effects of vortex shedding. To date, the employed open-cell porous materials typically possess a randomized internal structure. This paper presents the design and validation of a novel 3-D printed structured porous coated cylinder that has significant flexibility, in that the porosity and pores per inch of the porous coating can be modified independently and relatively easily. The performance of the structured porous coating design is compared against porous polyurethane and metal foam with the same coating dimensions and similar pores per inch and porosity via an experimental acoustic investigation, revealing strong similarity in the passive noise control performance of each material type. A numerical comparison illustrates the similarities of the wake structure of the 3-D printed porous coated cylinder to an equivalent Darcy–Forchheimer model simulation that represents a randomized internal porous structure. The performance similarities of these different porous material types indicate that a structured porous geometry can be used to understand the internal flow behavior of the porous medium responsible for reducing the cylinder vortex shedding tone that is otherwise extremely difficult or impossible with typical randomized porous structures. Moreover, significant potential exists for the porous structure to be further optimized or smartly tailored by architectural design for different control purposes, coating geometries and dimensions, and working conditions.
Arcondoulis, Elias J. G.
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Liu, Yu
d83ffb4c-fca9-416b-9983-e43a844fdc3d
Li, Zhiyong
c22e9d1b-6581-4018-8a75-f121cbc1182b
Yang, Yannian
6e1259f9-7c9e-489d-be0f-1e5b95fcc2cf
Wang, Yong
dab231ad-cd50-4f93-aedd-7242b75e9b24
4 September 2019
Arcondoulis, Elias J. G.
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Liu, Yu
d83ffb4c-fca9-416b-9983-e43a844fdc3d
Li, Zhiyong
c22e9d1b-6581-4018-8a75-f121cbc1182b
Yang, Yannian
6e1259f9-7c9e-489d-be0f-1e5b95fcc2cf
Wang, Yong
dab231ad-cd50-4f93-aedd-7242b75e9b24
Arcondoulis, Elias J. G., Liu, Yu, Li, Zhiyong, Yang, Yannian and Wang, Yong
(2019)
Structured porous material design for passive flow and noise control of cylinders in uniform flow.
Materials, 12 (18).
(doi:10.3390/ma12182905).
Abstract
Cylindrical bodies in uniform flows can be coated with a porous medium as a passive flow and noise control method in an effort to reduce the acoustic effects of vortex shedding. To date, the employed open-cell porous materials typically possess a randomized internal structure. This paper presents the design and validation of a novel 3-D printed structured porous coated cylinder that has significant flexibility, in that the porosity and pores per inch of the porous coating can be modified independently and relatively easily. The performance of the structured porous coating design is compared against porous polyurethane and metal foam with the same coating dimensions and similar pores per inch and porosity via an experimental acoustic investigation, revealing strong similarity in the passive noise control performance of each material type. A numerical comparison illustrates the similarities of the wake structure of the 3-D printed porous coated cylinder to an equivalent Darcy–Forchheimer model simulation that represents a randomized internal porous structure. The performance similarities of these different porous material types indicate that a structured porous geometry can be used to understand the internal flow behavior of the porous medium responsible for reducing the cylinder vortex shedding tone that is otherwise extremely difficult or impossible with typical randomized porous structures. Moreover, significant potential exists for the porous structure to be further optimized or smartly tailored by architectural design for different control purposes, coating geometries and dimensions, and working conditions.
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Published date: 4 September 2019
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Local EPrints ID: 505932
URI: http://eprints.soton.ac.uk/id/eprint/505932
PURE UUID: fd3c95fb-a08b-4ab6-a5d7-7efdcce7fd98
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Date deposited: 23 Oct 2025 16:56
Last modified: 24 Oct 2025 02:15
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Author:
Elias J. G. Arcondoulis
Author:
Yu Liu
Author:
Zhiyong Li
Author:
Yannian Yang
Author:
Yong Wang
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