Specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier

The vector of industrial development at the present stage is associated with a further increase in energy needs, which is associated with the modernization of existing and the development of new energy-efficient generating equipment. A significant share in the energy balance is still occupied by pow...
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Autor*in:	D. S. Protsko [verfasserIn] S. Y. Panov [verfasserIn] E. A. Shipilova [verfasserIn] O. M. Belykh [verfasserIn] A. A. Khvostov [verfasserIn]

Format:	E-Artikel
Sprache:	Russisch

Erschienen:	2022

Schlagwörter:	flue gases, aerosol mechanics, electrostatic deposition, perforated grating, filtration

Übergeordnetes Werk:	In: Вестник Воронежского государственного университета инженерных технологий - Voronezh State University of Engineering Technologies, 2016, 83(2022), 4, Seite 295-301
Übergeordnetes Werk:	volume:83 ; year:2022 ; number:4 ; pages:295-301

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc Journal toc

DOI / URN:	10.20914/2310-1202-2021-4-295-301

Katalog-ID:	DOAJ043043429

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callnumber-first	T - Technology
author	D. S. Protsko
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topic_title	TP368-456 Specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier flue gases, aerosol mechanics, electrostatic deposition, perforated grating, filtration
topic	misc TP368-456 misc flue gases, aerosol mechanics, electrostatic deposition, perforated grating, filtration misc Food processing and manufacture
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title	Specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier
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title_full	Specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier
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title_sort	specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier
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title_auth	Specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier
abstract	The vector of industrial development at the present stage is associated with a further increase in energy needs, which is associated with the modernization of existing and the development of new energy-efficient generating equipment. A significant share in the energy balance is still occupied by power plants that use fuel combustion and have significant environmental costs. The results of a theoretical and experimental study of the mechanisms of trapping flue gas particles of power plants by perforated filter baffles in order to reduce the load of emissions on the atmosphere are presented. Formulas for calculating the trapping coefficient under the action of various particle trapping mechanisms are systematized and proposed. The dominant role of the inertial trapping mechanism (?Stk) at the beginning of the filtration process and the gearing effect (?R) in the subsequent stage is determined. The issues of formation of the sediment layer require taking into account the adhesive properties of materials (parameter T) and the introduction of an effective Stokes coefficient (Stkeff). A special role is noted for increasing the efficiency of deposition of flue gas particles under the action of an electrostatic field (?E). In the future, the obtained research results can be used in the development and design of combined gas cleaning devices using the combined action of filtration and the action of an electrostatic field.
abstractGer	The vector of industrial development at the present stage is associated with a further increase in energy needs, which is associated with the modernization of existing and the development of new energy-efficient generating equipment. A significant share in the energy balance is still occupied by power plants that use fuel combustion and have significant environmental costs. The results of a theoretical and experimental study of the mechanisms of trapping flue gas particles of power plants by perforated filter baffles in order to reduce the load of emissions on the atmosphere are presented. Formulas for calculating the trapping coefficient under the action of various particle trapping mechanisms are systematized and proposed. The dominant role of the inertial trapping mechanism (?Stk) at the beginning of the filtration process and the gearing effect (?R) in the subsequent stage is determined. The issues of formation of the sediment layer require taking into account the adhesive properties of materials (parameter T) and the introduction of an effective Stokes coefficient (Stkeff). A special role is noted for increasing the efficiency of deposition of flue gas particles under the action of an electrostatic field (?E). In the future, the obtained research results can be used in the development and design of combined gas cleaning devices using the combined action of filtration and the action of an electrostatic field.
abstract_unstemmed	The vector of industrial development at the present stage is associated with a further increase in energy needs, which is associated with the modernization of existing and the development of new energy-efficient generating equipment. A significant share in the energy balance is still occupied by power plants that use fuel combustion and have significant environmental costs. The results of a theoretical and experimental study of the mechanisms of trapping flue gas particles of power plants by perforated filter baffles in order to reduce the load of emissions on the atmosphere are presented. Formulas for calculating the trapping coefficient under the action of various particle trapping mechanisms are systematized and proposed. The dominant role of the inertial trapping mechanism (?Stk) at the beginning of the filtration process and the gearing effect (?R) in the subsequent stage is determined. The issues of formation of the sediment layer require taking into account the adhesive properties of materials (parameter T) and the introduction of an effective Stokes coefficient (Stkeff). A special role is noted for increasing the efficiency of deposition of flue gas particles under the action of an electrostatic field (?E). In the future, the obtained research results can be used in the development and design of combined gas cleaning devices using the combined action of filtration and the action of an electrostatic field.
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title_short	Specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier
url	https://doi.org/10.20914/2310-1202-2021-4-295-301 https://doaj.org/article/a63d3993e5a74bcb939297467b1c210e https://www.vestnik-vsuet.ru/vguit/article/view/2932 https://doaj.org/toc/2226-910X https://doaj.org/toc/2310-1202
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Specificity of separate dispersed phase particles from flue gas flows by perfo-rated filter barrier

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