Application of acoustic agglomeration to enhance air filtration efficiency in air-conditioning and mechanical ventilation (ACMV) systems

Ng, Bing Feng; Xiong, Jin Wen; Wan, Man Pun

doi:10.1371/journal.pone.0178851

Cited by 54 publications

(32 citation statements)

References 139 publications

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“…Acoustic agglomeration, as a preconditioning technique, is a process in which small particles in a suspension collide with one another to form large agglomerates under the action of a sound field. As a result, particle size distribution can shift significantly to a range of larger particulates within a short period of time, and the efficiency of conventional particle removal technologies is greatly improved Sarabia et al 1986;Malherbe et al 1988;Caperan et al 1995;Gallego-Juarez et al 1999;Yuen et al 2014;Ma et al 2017;Ng et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of spatially nonhomogeneous acoustic agglomeration using sectional algorithm

Shang

Wan

et al. 2018

Aerosol Science and Technology

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In the simulation of acoustic agglomeration, the conventional temporal model assumes spatial homogeneity in aerosol properties and sound field, which is often not the case in real applications. In this article, we investigated the effects of spatial nonhomogeneity of sound field on the acoustic agglomeration process through a one-dimensional spatial sectional model. The spatial sectional model is validated against existing experimental data and results indicate lower requirements on the number of sections and better accuracy. Two typical cases of spatial nonhomogeneous acoustic agglomeration are studied by the established model. The first case involves acoustic agglomeration in a standing wave field with spatial alternation of acoustic kernels from nodes to antinodes. The good agreement between the simulation and experiments demonstrates the predictive capability of the present spatial sectional model for the standing-conditioned agglomeration. The second case incorporates sound attenuation in the particulate medium into acoustic agglomeration. Results indicate that sound attenuation can influence acoustic agglomeration significantly, particularly at high frequencies, and neglecting the effects of sound attenuation can cause overprediction of agglomeration rates. The present investigation demonstrates that the spatial sectional method is capable of simulating the spatially nonhomogeneous acoustic agglomeration with high computation efficiency and numerical robustness and the coupling with flow dynamics will be the goal of future work.

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Section: Introductionmentioning

confidence: 99%

Numerical investigation of spatially nonhomogeneous acoustic agglomeration using sectional algorithm

Shang

Wan

et al. 2018

Aerosol Science and Technology

Self Cite

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“…At the same time, constructive ways to increase the efficiency of collecting fine fractions of the most commonly used collectors are practically ex hausted and most of the work is aimed at finding a solu tion to this problem by influencing the fractional compo sition of dust. In works [9,10], it is suggested that the acoustic coagulation of fine dust be made before the col lector, and in the work [11], the high frequency sound waves bands, that provide the best results, are defined. The main drawback of the method is the need to use ad ditional equipment -an acoustic wave generator.…”

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confidence: 99%

Ecologically safe system of cleaning the air from polydisperse dust

Butenko¹,

Smyk²,

Arsiriy³

et al. 2019

NVNGU

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Purpose. Increasing the level of environmental safety of enterprises with directflow aspiration systems by improv ing the quality of air purification from polydisperse dust in systems with standard capture equipment by isolating the flow from the environment. methodology. The purpose of the research was realized by developing a closed twocircuit purification system and assessing its efficiency by the mathematical modeling of the dedusting process of a particular polydisperse flow. Findings. A scheme of a twocircuit closed system of air purification, in which the polydisperse dust is initially divided by fractional sign, is proposed. The coarse dust flow is cleaned in the main circuit and, with a minimum mass of yield, returns to the premise in the area of the collecting equipment operation. The fine dust flow is cleaned due to the repeated passage through the circulation circuit capture equipment. A method of calculation of indicators of the proposed system is developed. Originality. The issue of increasing the level of environmental safety of small industrial enterprises and industries, where there is a need to clean air from dust, is proposed to be solved by replacing the traditional directflow system with a twocircuit closed one. The ecological effect is achieved by separate purification of dust particles with different fractional composition and due to the complete isolation of the system from the environment. The obtained results of mathematical modeling allowed estimating the values of the indicators of the effectiveness of the elements of the sys tem and the nature of their changes during the work. Practical value. The proposed system makes it possible, without significant investment into purchasing expensive highefficiency collecting equipment, to modernize traditional directflow systems for cleaning dust polluted air and at the same time to achieve a significant ecological effect through almost complete elimination of emissions into the atmosphere.

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“…Specifically, increase of indoor bioaerosol concentrations due to bioaerosol emission from the ACMV system has not been observed and bioaerosol emission of the ACMV system is still not quantified and species-identified, which makes it debatable that whether the ACMV system is helping to control indoor bioaerosol level or is worsening indoor air by emitting bioaerosols to indoor space. In addition to being potential bioaerosol emission source for the indoor space, the operation of ACMV systems accounts for nearly half of the total building electricity consumption in buildings under temperate climate and this can reach 70% for buildings in the tropics, where ACMV systems usually operate for longer time in a day compared to their operation in temperate indoor environment (Ng et al, 2017). Therefore, it is necessary to develop new approaches to avoid the significant energy consumption of operation of the ACMV system while control indoor pollutants level effectively.…”

Section: List Of Tablesmentioning

confidence: 99%

“…The operation of ACMV systems accounts for nearly half of the total building electricity consumption in buildings under temperate climate (Pérez-Lombard et al, 2008) and this can reach 70% for buildings in the tropics, where ACMV systems usually operate for longer time in a day compared to their operation in template indoor environment (Ng et al, 2017). In buildings, energy consumption of operation of the ACMV system is predominant compared with other energy use such as lighting and appliance.…”

Section: Conditioning and Mechanical Ventilation Systemmentioning

confidence: 99%

“…In building with ACMV system, filters inside the ACMV system predominantly serves to remove indoor bioaerosols and around 15% to 30% of the system energy consumption is devoted to air distribution, most of which is consumed by fans in the ACMV system to overcome losses (pressure drop) in the distribution ducts and across filters (Ng et al, 2017). The power that a fan spends on overcoming pressure drop of a filter could be calculated by：…”

Section: Application Of Acoustic Agglomeration For Improvement Of Filmentioning

confidence: 99%

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Contribution of bioaerosol emission from air-conditioning and mechanical ventilation system to indoor bioaerosol concentration

Xiong¹

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Application of acoustic agglomeration to enhance air filtration efficiency in air-conditioning and mechanical ventilation (ACMV) systems

Cited by 54 publications

References 139 publications

Numerical investigation of spatially nonhomogeneous acoustic agglomeration using sectional algorithm

Numerical investigation of spatially nonhomogeneous acoustic agglomeration using sectional algorithm

Ecologically safe system of cleaning the air from polydisperse dust

Contribution of bioaerosol emission from air-conditioning and mechanical ventilation system to indoor bioaerosol concentration

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