Improving the structural schemes of optical dust measuring instruments

Authors

  • Дмитро Григорович Корнієнко National Technical University of Ukraine «Kyiv Polytechnic Institute», Ukraine, 03056, Kyiv-56, Victory Avenue, 37, Ukraine https://orcid.org/0000-0002-2683-2775

DOI:

https://doi.org/10.15587/2312-8372.2016.71766

Keywords:

dust, particle, dust measuring instrument, air, method, detector, measure instrument, optics, photometer, gravimetry

Abstract

This article describes the structural schemes of the next optical dust measuring instruments: single-channel, dual-channel, fixed, mobile, application features and specifications. The main aim of research is to improve the accuracy of measuring the dust concentration and reduce the measurement error due to the invariant schemes of construction of the optical dust measuring instruments.

Use of optical dust measuring instruments is important to monitor the protection of the environment, including health standards, certification of workplaces. It is cause of both periodic and continuous monitoring of the dust concentration with automatic dust measuring instruments that implement different methods of dust measurement in visibility on the operating conditions, operating mode, measuring range, requirements for speed and reliability.

The choice of structural construction of dust measuring instruments is proved depending on the range of dust concentration. Proposed Use of invariant schemes for construction of dust measuring instruments: gravimetric and optical with physical equivalents.

Author Biography

Дмитро Григорович Корнієнко, National Technical University of Ukraine «Kyiv Polytechnic Institute», Ukraine, 03056, Kyiv-56, Victory Avenue, 37

Graduate student

Department of scientific, analytical and ecological devices and systems

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Published

2016-05-26

How to Cite

Корнієнко, Д. Г. (2016). Improving the structural schemes of optical dust measuring instruments. Technology Audit and Production Reserves, 3(2(29), 24–30. https://doi.org/10.15587/2312-8372.2016.71766

Issue

Vol. 3 No. 2(29) (2016): Systems and Control Processes. Technology Transfer in the Transport Industry. Information and Control Systems

Section

Systems and Control Processes: Original Research

License

Copyright (c) 2016 Дмитро Григорович Корнієнко

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