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State of the art and research development prospects of energy and resource-efficient environmentally safe chemical process systems engineering

Valeriy Pavlovich Meshalkin 1, 2, 3
Valeriy Pavlovich Meshalkin
Vincenzo G Dovi 4
Vincenzo G Dovi
Vladimir I Bobkov 5
Vladimir I Bobkov
Alexey V Belyakov 3
Alexey V Belyakov
Oleg Borisovich Butusov 3
Oleg Borisovich Butusov
Alexander Vasil'evich Garabadzhiu 2
Alexander Vasil'evich Garabadzhiu
Tatiana F Burukhina 3
Tatiana F Burukhina
Svetlana Mikhailovna Khodchenko 3
Svetlana Mikhailovna Khodchenko
10.1016/j.mencom.2021.09.003
Published 2021-09-08
Focus articleVolume 31, Issue 5, 593-604
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Meshalkin V. P. et al. State of the art and research development prospects of energy and resource-efficient environmentally safe chemical process systems engineering // Mendeleev Communications. 2021. Vol. 31. No. 5. pp. 593-604.
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Meshalkin V. P., Dovi V. G., Bobkov V. I., Belyakov A. V., Butusov O. B., Garabadzhiu A. V., Burukhina T. F., Khodchenko S. M. State of the art and research development prospects of energy and resource-efficient environmentally safe chemical process systems engineering // Mendeleev Communications. 2021. Vol. 31. No. 5. pp. 593-604.
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TY - JOUR
DO - 10.1016/j.mencom.2021.09.003
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2021.09.003
TI - State of the art and research development prospects of energy and resource-efficient environmentally safe chemical process systems engineering
T2 - Mendeleev Communications
AU - Meshalkin, Valeriy Pavlovich
AU - Dovi, Vincenzo G
AU - Bobkov, Vladimir I
AU - Belyakov, Alexey V
AU - Butusov, Oleg Borisovich
AU - Garabadzhiu, Alexander Vasil'evich
AU - Burukhina, Tatiana F
AU - Khodchenko, Svetlana Mikhailovna
PY - 2021
DA - 2021/09/08
PB - Mendeleev Communications
SP - 593-604
IS - 5
VL - 31
ER -
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@article{2021_Meshalkin,
author = {Valeriy Pavlovich Meshalkin and Vincenzo G Dovi and Vladimir I Bobkov and Alexey V Belyakov and Oleg Borisovich Butusov and Alexander Vasil'evich Garabadzhiu and Tatiana F Burukhina and Svetlana Mikhailovna Khodchenko},
title = {State of the art and research development prospects of energy and resource-efficient environmentally safe chemical process systems engineering},
journal = {Mendeleev Communications},
year = {2021},
volume = {31},
publisher = {Mendeleev Communications},
month = {Sep},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2021.09.003},
number = {5},
pages = {593--604},
doi = {10.1016/j.mencom.2021.09.003}
}
MLA
Cite this
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Meshalkin, Valeriy Pavlovich, et al. “State of the art and research development prospects of energy and resource-efficient environmentally safe chemical process systems engineering.” Mendeleev Communications, vol. 31, no. 5, Sep. 2021, pp. 593-604. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2021.09.003.
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Keywords

artificial intelligence
chemical process system
chemical technology
digitalization
energy and resources saving
engineering
environmental impact
heat-exchange system
intensification
optimization
pinch analysis
supply chain
unit operation
Waste

Abstract

In this focus overview, the main types and directions of engineering, methods and techniques of intensification of chemical process systems (CPS) and process optimization of energy- and resource-efficient processes for the representative production of titanium compounds, mining waste processing systems, electrochemical coating technologies, combined technologies for the treatment of industrial effluents and energy-and resource-efficient technologies for cleaning soils from petroleum and chemical pollution products are reviewed. The following issues have been discussed: methods of complex assessment of production energy efficiency and software and information support for automated synthesis of optimal energy-efficient regenerative heat exchange systems using pinch analysis; methods and algorithms for fractal-statistical characteristics analysis of nonstationary gas flows in complex gas pipelines; methods of ecological and economic optimization of production, infrastructure supply chains; methods for assessing and preventing the dangerous environmental impact assessment of chemical pollution; organization and logistics management of business processes engineering for improving the energy efficiency of plants; engineering of problem oriented computer systems, heuristic-computational models and algorithms for intelligent integrated logistics support of the equipment life cycle; engineering developments in the field of digital transformation of energy-efficient CPS and technological production systems; application of methods for optimizing reliability factors optimization, digitalized risk and safety management in the engineering of energy- and resource efficient CPS.

References

1.
The early history of chemical engineering: a reassessment
Cohen C.
British Journal for the History of Science, 1996
2.
C. Flavell-While, The Chemical Engineer, 2012, no. 849, 52, https://www.thechemicalengineer.com/features/cewctw-george-e-davis-meet-the-daddy/, retrieved 23.01.2021.
3.
10.1016/j.mencom.2021.09.003_b0015
Meshalkin
Chem. Eng. Trans., 2009
4.
Process Systems Engineering: Academic and industrial perspectives
Grossmann I.E., Harjunkoski I.
Computers and Chemical Engineering, 2019
7.
10.1016/j.mencom.2021.09.003_b0035
Meshalkin
2009
8.
European Roadmap for Process Intensification, https://efce.info/efce_ media/-p-531.pdf, retrieved 21.01.2021.
10.
An industrial view of process intensification
Becht S., Franke R., Geißelmann A., Hahn H.
Chemical Engineering and Processing: Process Intensification, 2009
11.
CEFIC, Chemical Industry Image 2004, Pan-European survey (2004) ECN, 12 July, p. 27.
13.
10.1016/j.mencom.2021.09.003_b0065
Segovia-Hernández
in Process Intensification in Chemical Engineering: Design Optimization and Control, eds, 2016
15.
An overview of process intensification methods
Sitter S., Chen Q., Grossmann I.E.
Current Opinion in Chemical Engineering, 2019
16.
10.1016/j.mencom.2021.09.003_b0080
Zanaveskin
Tsvetnye Metally, 2017
17.
Activation of quartz-leucoxene concentrate for processing into titanium tetrachloride
Zanaveskin K.L., Zanaveskina S.M., Maslennikov A.N., Politova E.D., Vlasenko V.I., Zanaveskin L.N.
Russian Journal of Applied Chemistry, 2016
18.
Leaching SiO2 and Al2O3 Impurities from Leucoxene from the Yaregskoe Deposit by Sodium Hydroxide Solution
Zanaveskin K.L., Maslennikov A.N., Zanaveskina S.M., Dmitriev G.S., Zanaveskin L.N., Politova E.D., Vlasenko V.I.
Theoretical Foundations of Chemical Engineering, 2019
19.
10.1016/j.mencom.2021.09.003_b0095
Zanaveskin
Obogashchenie Rud (Mineral Processing), 2016
20.
Chlorination of Quartz-Leucoxene Concentrate of Yarega Field
Zanaveskin K.L., Meshalkin V.P.
Metallurgical and Materials Transactions B, 2020
21.
10.1016/j.mencom.2021.09.003_b0105
Bustillo
Mineral Resources: From Exploration to Sustainability Assessment, 2018
22.
Total Value of Phosphorus Recovery
Mayer B.K., Baker L.A., Boyer T.H., Drechsel P., Gifford M., Hanjra M.A., Parameswaran P., Stoltzfus J., Westerhoff P., Rittmann B.E.
Environmental Science & Technology, 2016
23.
Investigation of the structural and mineralogical changes of Tunisian phosphorite during calcinations
Elgharbi S., Horchani-Naifer K., Férid M.
Journal of Thermal Analysis and Calorimetry, 2014
25.
Influence of sucrose substitutes and agglomeration on volatile compounds in powdered cocoa beverages
Kowalska J., Kowalska H., Cieślak B., Majewska E., Ciecierska M., Derewiaka D., Lenart A.
Journal of Food Science and Technology, 2019
26.
Improvement on slurry ability and combustion dynamics of low quality coals with ultra-high ash content
Hu S., Li J., Yang X., Chen Y., Li F., Wang J., Wu C., Weng L., Liu K.
Chemical Engineering Research and Design, 2020
27.
Recovery of iron rich residues from integrated steel making process by hydrated lime/molasses pressurised cold agglomeration
De Gisi S., Romaniello L., Dalessandro M., Todaro F., Notarnicola M.
Journal of Cleaner Production, 2019
28.
Study of the thermal characteristics of phosphate raw materials in the annealing temperature range
Bobkov V.I., Borisov V.V., Dli M.I., Meshalkin V.P.
Theoretical Foundations of Chemical Engineering, 2017
31.
10.1016/j.mencom.2021.09.003_b0155
Bobkov
Policy, 2018
33.
Hybrid Fuzzy Differential-Production Model of the Dynamic Drying of a Pellet under Uncertainty
Meshalkin V.P., Bobkov V.I., Borisov V.V., Dli M.I.
Doklady Chemistry, 2020
35.
Optimizing the Energy Efficiency of a Local Process of Multistage Drying of a Moving Mass of Phosphorite Pellets
Meshalkin V.P., Bobkov V.I., Dli M.I., Belozerskii A.Y., Men’shova I.I.
Doklady Chemistry, 2019
36.
Thermally Activated Chemical Technology Processes of Agglomeration of Phosphorites
Bobkov V.I., Borisov V.V., Dli M.I., Meshalkin V.P.
Theoretical Foundations of Chemical Engineering, 2018
37.
Computer-visual model of thermophysical processes in electrothermal reactor
Panchenko S.V., Dli M.I., Borisov V.V., Meshalkin V.P.
Tsvetnye Metally, 2015
38.
10.1016/j.mencom.2021.09.003_b0190
Vinokurov
Tekhnologiya Metallov, 2020
40.
System analysis of the efficiency and competitiveness of chroming technologies
Vinokurov E.G., Meshalkin V.P., Vasilenko E.A., Nevmyatullina K.A., Burukhina T.F., Bondar’ V.V.
Theoretical Foundations of Chemical Engineering, 2016
41.
Development of a Power-and-Resource-Saving Combined Low-Temperature Chemical Engineering Process of Crystalline Phosphatizing
Meshalkin V.P., Vagramyan T.A., Mazurova D.V., Grigoryan N.S., Abrashov A.A., Khodchenko S.M.
Doklady Chemistry, 2020
43.
10.1016/j.mencom.2021.09.003_b0215
Vinokurov
Prot. Met., 1992
44.
Aqueous Solutions of Cr(III) Sulfate: Modeling of Equilibrium Composition and Physicochemical Properties
Vinokurov E.G., Kuznetsov V.V., Bondar' V.V.
Russian Journal of Coordination Chemistry/Koordinatsionnaya Khimiya, 2004
45.
V. V. Kuznetsov, E. G. Vinokurov, O. E. Azarko and V. N. Kudryavtsev, Russ. J. Electrochem., 1999, 35, 698 (Elektrokhimiya, 1999, 35, 779).
46.
Physicochemical model for choosing complexes for chromium-plating solutions based on Cr(III) compounds
Vinokurov E.G., Demidov A.V., Bondar? V.V.
Russian Journal of Coordination Chemistry/Koordinatsionnaya Khimiya, 2005
48.
Logistic model for choosing ligands for alloy electrodeposition
Vinokurov E.G., Bondar’ V.V.
Theoretical Foundations of Chemical Engineering, 2007
49.
Concentration criterion for classifying resource-saving compositions of solutions for metal electroplating
Vinokurov E.G., Burukhina T.F., Kolesnikov V.A., Fadina S.V.
Theoretical Foundations of Chemical Engineering, 2012
51.
Analysis of the Physicochemical Efficiency of the Electroflotation Recovery of Titanium Tetrachloride Hydrolysis Products from Industrial Waste
Meshalkin V.P., Kolesnikov A.V., Savel’ev D.S., Kolesnikov V.A., Belozerskii A.Y., Men’shova I.I., Maslyannikova D.V., Sycheva O.V.
Doklady Physical Chemistry, 2019
53.
Logical-Information Model of Energy-Saving Production of Organic Sulfur Compounds from Low-Molecular Sulfur Waste Fuel Oil
Meshalkin V., Shinkar E., Berberova N., Pivovarova N., Ismagilov F., Okhlobystin A.
Energies, 2020
56.
10.1016/j.mencom.2021.09.003_b0280
Mohammadi
Desalination, 2021
57.
10.1016/j.mencom.2021.09.003_b0285
Kruglikov
Galvanotekhnika i Obrabotka Poverkhnosti, 2018
58.
New directions in the implementation of Pinch Methodology (PM)
Klemeš J.J., Varbanov P.S., Walmsley T.G., Jia X.
Renewable and Sustainable Energy Reviews, 2018
59.
10.1016/j.mencom.2021.09.003_b0295
Meshalkin
Teor. Osn. Khim. Tekhnol., 2012
60.
10.1016/j.mencom.2021.09.003_b0300
Ulyev
Chem. Eng. Trans., 2020
61.
10.1016/j.mencom.2021.09.003_b0305
Kanischev
Chem. Eng. Trans., 2018
62.
10.1016/j.mencom.2021.09.003_b0310
Ulyev
Chem. Eng. Trans., 2018
63.
10.1016/j.mencom.2021.09.003_b0315
Chibisov
Energosberezhenie i Vodopodgotovka, 2019
64.
10.1016/j.mencom.2021.09.003_b0320
Meshalkin
Energosberezhenie i Vodopodgotovka, 2019
65.
Texture and fractal methods for analyzing the characteristics of unsteady gas flows in pipelines
Butusov O.B., Meshalkin V.P.
Theoretical Foundations of Chemical Engineering, 2006
67.
A Potential-Integral-Index Algorithm for Analyzing the Pressure Fluctuations of Gas Flows in Complex Pipelines
Kantyukov R.R., Meshalkin V.P., Butusov O.B.
Theoretical Foundations of Chemical Engineering, 2020
68.
10.1016/j.mencom.2021.09.003_b0340
Butusov
Komp’yuternyi analiz gidrodinamiki nestatsionarnykh potokov v gazotransportnykh sistemakh (Computer Analysis of Hydrodynamics of Unsteady Flows in Gas Transmission Systems), 2014
70.
10.1016/j.mencom.2021.09.003_b0350
Mallat
A Wavelet Tour of Signal Processing, 2009
71.
10.1016/j.mencom.2021.09.003_b0355
Gimel’farb
Image Textures and Gibbs Random Fields, 1999
72.
10.1016/j.mencom.2021.09.003_b0360
Petrou
Image Processing: Dealing with Texture, 2006
73.
Computer-aided tools for molecular systems engineering and wavelet-morphometric analysis of the texture of nanomaterials
Sarkisov P.D., Butusov O.B., Meshalkin V.P.
Theoretical Foundations of Chemical Engineering, 2011
74.
Wavelet morphometric neural network algorithm for analyzing nanomaterial porous texture
Sarkisov P.D., Butusov O.B., Meshalkin V.P., Sevastianov V.G., Galaev A.B., Vinokurov E.G.
Theoretical Foundations of Chemical Engineering, 2012
75.
Computer-aided method of analysis of nanocomposite structure on the basis of calculations of isolines of fractal dimensionality
Sarkisov P.D., Butusov O.B., Meshalkin V.P., Sevast’yanov V.G., Galaev A.B.
Theoretical Foundations of Chemical Engineering, 2010
76.
10.1016/j.mencom.2021.09.003_b0380
Simulation
From Brain Imaging to Turbulent Flows, ed, 2016
78.
ENHANCEMENTS OF THE SIMPLE METHOD FOR PREDICTING INCOMPRESSIBLE FLUID FLOWS
Van Doormaal J.P., Raithby G.D.
Numerical Heat Transfer, 1984
79.
10.1016/j.mencom.2021.09.003_b0395
Rezaei
Comput. Math., Nat. Sci. Eng. Med., 2012
80.
10.1016/j.mencom.2021.09.003_b0400
Jaberi
Int. J. Heat Mass Transfer, 1827
81.
10.1016/j.mencom.2021.09.003_b0405
Meshalkin
Printsipy promyshlennoi logistiki (Industrial Logistics Principles), 2002
82.
10.1016/j.mencom.2021.09.003_b0410
Van Dam
J. Inst. Pet., 1968
87.
A Lagrangean Decomposition Heuristic for the Design and Planning of Offshore Hydrocarbon Field Infrastructures with Complex Economic Objectives
van den Heever S.A., Grossmann I.E., Vasantharajan S., Edwards K.
Industrial & Engineering Chemistry Research, 2001
88.
Mixed Integer Models for the Stationary Case of Gas Network Optimization
Martin A., Möller M., Moritz S.
Mathematical Programming, 2005
89.
Computer-Aided Simulation Model for Natural Gas Pipeline Network System Operations
Nimmanonda P., Uraikul V., Chan C.W., Tontiwachwuthikul P.
Industrial & Engineering Chemistry Research, 2004
90.
A strategy for simulation and optimization of gas and oil production
Barragán-Hernández V., Vázquez-Román R., Rosales-Marines L., García-Sánchez F.
Computers and Chemical Engineering, 2005
93.
A novel branch and bound algorithm for optimal development of gas fields under uncertainty in reserves
Goel V., Grossmann I.E., El-Bakry A.S., Mulkay E.L.
Computers and Chemical Engineering, 2006
96.
Global optimum search for nonconvex NLP and MINLP problems
Floudas C.A., Aggarwal A., Ciric A.R.
Computers and Chemical Engineering, 1989
97.
10.1016/j.mencom.2021.09.003_b0485
Osiadacz
Arch. Min. Sci., 2016
98.
10.1016/j.mencom.2021.09.003_b0490
Meshalkin
Komp’yuternaya otsenka vozdeistviya na okruzhayushchuyu sredu magistral’nykh truboprovodov (Computer-aided Assessment of the Environmental Impact of Trunk Pipelines), 2020
100.
Green supply-chain management: A state-of-the-art literature review
Srivastava S.K.
International Journal of Management Reviews, 2007
103.
Multi-objective optimization of environmentally conscious chemical supply chains under demand uncertainty
Ruiz-Femenia R., Guillén-Gosálbez G., Jiménez L., Caballero J.A.
Chemical Engineering Science, 2013
104.
Incorporating environmental impacts and regulations in a holistic supply chains modeling: An LCA approach
Bojarski A.D., Laínez J.M., Espuña A., Puigjaner L.
Computers and Chemical Engineering, 2009
105.
Optimisation of a green gas supply chain – A review
Bekkering J., Broekhuis A.A., van Gemert W.J.
Bioresource Technology, 2010
106.
Global optimization of bilinear programs with a multiparametric disaggregation technique
Kolodziej S., Castro P.M., Grossmann I.E.
Journal of Global Optimization, 2013
107.
10.1016/j.mencom.2021.09.003_b0535
Ferris
Comput. Chem. Eng., 1973
108.
UN General Assembly Working Group Report on Sustainable Development Goals, A-68-970, New York, 2014.
110.
10.1016/j.mencom.2021.09.003_b0550
Krantzberg
Int. J. Sci., 2017
111.
10.1016/j.mencom.2021.09.003_b0555
Finger
J., 2012
112.
10.1016/j.mencom.2021.09.003_b0560
Makarova
Int. J. Qual. Res., 2018
113.
10.1016/j.mencom.2021.09.003_b0565
Makarova
Chem. Eng. Trans., 2017
114.
Systems Analysis of the Efficiency of Imitation Processes of the Chemical Immobilization of Mercury in Waste Using Multivariant Visualization Tools
Makarova A.S., Meshalkin V.P., Fedoseev A.N., Kantyukov R.R., Kolybanov K.Y.
Theoretical Foundations of Chemical Engineering, 2020
115.
S. Hagemann, Technologies for the Stabilization of Elemental Mercury and Mercury-Containing Wastes, Gesellschaft für Anlagen – und Reaktorsicherheit (GRS) Report 252, Germany, 2009.
116.
New materials and ecology: Biocomposites for aquatic remediation
Dedov A.G., Ivanova E.A., Sandzhieva D.A., Lobakova E.S., Kashcheeva P.B., Kirpichnikov M.P., Ishkov A.G., Buznik V.M.
Theoretical Foundations of Chemical Engineering, 2017
117.
10.1016/j.mencom.2021.09.003_b0585
Meshalkin
Chem. Eng. Trans., 2020
118.
Biocomposite Materials for Purification of Aqueous Media Contaminated with Hydrocarbons
Ivanova E.A., Lobakova E.S., Idiatulov R.K., Shapiro T.N., Sandzhieva D.A., Kuznetsova O.V., Zaitseva Y.N., Dzhabrailova K.S., Dedov A.G.
Petroleum Chemistry, 2019
119.
Mechanism of the Intensification of a Heterogeneous Reduction Reaction with the Liberation of Gas Bubbles
Meshalkin V.P., Panchenko S.V., Dli M.I., Bobkov V.I., Chernovalova M.V.
Theoretical Foundations of Chemical Engineering, 2020
120.
Shinkevich A.I., Kudryavtseva S.S., Ershova I.G.
International Journal of Energy Economics and Policy, 2020
122.
Experimental Investigation of the Efficiency of the Electroflotation Recovery of a Mixture of a Poorly Soluble Cerium Group Metal Compounds from Aqueous Solutions
Meshalkin V.P., Kolesnikov A.V., Gaidukova A.M., Achkasov M.G., Kolesnikov V.A., Belozerskii A.Y., Men’shova I.I.
Doklady Physical Chemistry, 2019
123.
Iterative Real-Time Optimization Scheme for Optimal Operation of Chemical Processes under Uncertainty: Proof of Concept in a Miniplant
Hernandez R., Dreimann J., Vorholt A., Behr A., Engell S.
Industrial & Engineering Chemistry Research, 2018
124.
10.1016/j.mencom.2021.09.003_b0620
Malysheva
J. Anal. Chem., 2017
125.
Intelligent Logical Information Algorithm for Choosing Energy- and Resource-Efficient Chemical Technologies
Bogomolov B.B., Boldyrev V.S., Zubarev A.M., Meshalkin V.P., Men’shikov V.V.
Theoretical Foundations of Chemical Engineering, 2019
126.
10.1016/j.mencom.2021.09.003_b0630
Shinkevich
Mater. Sci. Eng., 2020
127.
10.1016/j.mencom.2021.09.003_b0635
Sahin
J. Intell. Manuf., 1827
128.
Environmental Certification and Technical Efficiency: A Study of Manufacturing Firms in India
Sahu S.K., Narayanan K.
Journal of Industry, Competition and Trade, 2015
129.
Flexicurity and relocation of manufacturing
Stentoft J., Mikkelsen O.S., Jensen J.K.
Operations Management Research, 2016
130.
Computer simulation of transient gas flows in complex round pipes
Butusov O.B., Meshalkin V.P.
Theoretical Foundations of Chemical Engineering, 2008
131.
Working mode in aircraft manufacturing based on digital coordination model
Guo F., Zou F., Liu J., Wang Z.
International Journal of Advanced Manufacturing Technology, 2018
132.
Project management in the nanotechnology industry: Specifics and possibilities of taking them into account
Meshalkin V.P., Stoyanova O.V., Dli M.I.
Theoretical Foundations of Chemical Engineering, 2012
134.
Computer-based logistics support system for the maintenance of chemical plant equipment
Moshev E.R., Meshalkin V.P.
Theoretical Foundations of Chemical Engineering, 2014
135.
Development of Models and Algorithms for Intellectual Support of Life Cycle of Chemical Production Equipment
Moshev E., Meshalkin V., Romashkin M.
Studies in Systems, Decision and Control, 2019
136.
10.1016/j.mencom.2021.09.003_b0680
Shcherbakov
Commun. Comput. Info. Sci., 2017
137.
10.1016/j.mencom.2021.09.003_b0685
Kozunova
Commun. Comput. Info. Sci., 2019
139.
10.1016/j.mencom.2021.09.003_b0695
Dascalu
Commun. Comput. Info. Sci., 2019
140.
10.1016/j.mencom.2021.09.003_b0700
Kohlert
IOS Press, 2012
142.
Big Data Analysis in Film Production
Chistyakova T.B., Kleinert F., Teterin M.A.
Studies in Systems, Decision and Control, 2019
143.
10.1016/j.mencom.2021.09.003_b0715
Meshalkin
Ekspertnye sistemy v khimicheskoi tekhnologii (Expert Systems in Chemical Technology), 1993
144.
Multipurpose Computer Model for Screw Processing of Plastics
Wilczyński K., Nastaj A., Lewandowski A., Wilczyński K.J.
Polymer-Plastics Technology and Engineering, 2012
145.
Residence time distributions in a co-kneader: A chemical engineering approach
Monchatre B., Raveyre C., Carrot C.
Polymer Engineering and Science, 2015
147.
Siemens Digital Industries Softuare, https://www.plm.automation. siemens.com/global/ru/our-story/glossary/digital-twin/24465, retrieved 21.01.2021.
148.
T. Stauffer, N. Sands and D. Dunn, Alarm Management and ISA-18 – a Journey, not a Destination, deTexas A&M Instrumentation Symposium, 2000, https://www.researchgate.net/figure/Safety-layers-of-protection-from-Stauffer-et-al-2000_fig1_319453633, retrieved 22.01.2021.
149.
Wavelet-neuro-heuristics complex procedure of diagnostics of point defects of sheet glass
Meshalkin V.P., Petrov D.Y.
Theoretical Foundations of Chemical Engineering, 2014
150.
J. W. Vasquez Capacho, M. A. Mayorga, A. Cortez and A. Bustos, Tecciencia, 9, no.16 Bogotá Jan./June 2014, http://www.scielo.org.co/ scielo.php?script=sci_arttext&pid=S1909-36672014000100002 1/17, retrieved 22.01.2021.
151.
G. Gruhn, V. V. Kafarov, V. P Meshalkin and W. Neumann, Zuverlässigkeit von Chemieanlagen, Leipzig, 1979.
152.
Risk and reliability assessment in chemical process industries using Bayesian methods
Roy A., Srivastava P., Sinha S.
Reviews in Chemical Engineering, 2014
153.
Methods and models for the risk analysis and security management of chemical plants
Egorov A.F., Savitskaya T.V.
Theoretical Foundations of Chemical Engineering, 2010
154.
System analysis of safe chemical handling: Methods and approaches to predicting and classifying chemical hazards
Sarkisov P.D., Egorov A.F., Savitskaya T.V., Bachkala O.V., Kuz’mina Y.A.
Theoretical Foundations of Chemical Engineering, 2013
155.
10.1016/j.mencom.2021.09.003_b0775
Berman
Sci. Eng., 2020