nach oben

Metallurgist

Erschienen in:

05.07.2021

Process Control System for Producing a Silica-Based Modifying Additive

verfasst von: V. A. Ershov, A. I. Karlina, Yu. I. Karlina

Erschienen in: Metallurgist | Ausgabe 3-4/2021

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

In this study, the authors describe the development of an automated system for controlling the technological process of obtaining a modifying concrete additive comprising spherical silicon dioxide nanostructures. The paper describes the automation object, outlines system development aims, as well as presenting the main process-specific parameters to be measured, adjusted, signaled, and / or blocked. A list of automation equipment of the field, lower, and upper levels of the automated process control system (APCS) is provided. As well as input signal processing, the automatic polling of sensors and instruments is achieved by employing a distributed system based on Siemens equipment for the collection of data, which interact via Ethernet. The paper considers software requirements for the APCS operation and analyzes its reliability. The maximum safety level of the APCS is SIL 3; the average service life is stated to be 12 years. The developed automated control system for the technological process of obtaining the silica-based modifying additive permits the development of its structure, specifically an increase in the number of measurement points using a 10% input-output margin. In addition, software and data support of the APCS allows the system configuration to be modified, as well as enabling its expansion through an upgrade and the input of new tasks (sets of tasks and algorithms).

Vorheriger Artikel Development of Coatings for Protection of Blast Furnace Air Tuyeres

Nächster Artikel Determination of Critical Points of Variable Composition Beta-Solidifying TiAl-Alloy

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

K. S. Elkin, A. V. Sivtsov, D. K. Elkin, and A. I. Karlina, “Silicon metallurgy and environmental issues,” in: Proc. Int. Congr. and Conf. for Young Scientists: Fundamental Research and Applied Developing of Recycling and Utilization Processes of Technogenic Formations TECHNOGEN-2019 [in Russian], (2019), pp. 160–163.

M. P. Kuz’min, S. S. Shestakov, M. Yu. Kuz’mina, and A. S. Zhuravleva, “Innovative development of the metallurgical complex in the Irkutsk Region,” Vestn. IrGTU, No. 5 (100), 236–240 (2015).

V. V. Kondrat’ev, V. A. Ershov, I. A. Sysoev, V. G. Grigor’ev, A. B. Chernigova, and B. I. Zel’berg, “Flue gas treatment in silicon production,” in: Prospects for the Development of Silicon Production, Collected Papers (2011), pp. 67–70.

V. V. Kondrat’ev, N. A. Ivanov, É. P. Rzhechitskii, and I. A. Sysoev, “Promising applications of nanotechnologies and nanomaterials in the mining and metallurgical industries,” Vestn. IrGTU, No. 1 (41), 168–174 (2010).

V. V. Kondrat’ev, K. S. Elkin, O. I. Doshlov, B. I. Zel’berg, S. P. Yakovlev, and S. V. Balakirev, “Improving the process of metallurgical silicon production,” in: 10th Conference on the Silicon Physics, Material Science, Technology and Diagnostics, Silicon-Based Nanometer Structures and Devices [in Russian] (2014), pp. 122–123.

V. V. Kondrat’ev, N. V. Nemchinova, N. A. Ivanov, V. A. Ershov, and I. A. Sysoev, “New production solutions for processing silicon and aluminum production waste,” Metallurgist, 57, No. 5-6, 455–459 (2013).

D. Munkkhtuvshin, V. B. Balabanov, and K. N. Putsenko, “Application of micro- and nanosilica additives generated from silicon production waste in concrete technologies,” Izv. Vuzov. Invest. Stroit. Nedvizh., 7, No 3 (22), 107–115 (2017).

A. D. Kolosov, A. A. Nemarov, and S. A. Nebogin, “Technology for obtaining nanosilica and its application in the production of new materials for mechanical engineering,” Sovr. Tekhnol. Sist. Anal. Model., No. 3 (55), 59–66 (2017).

V. S. Yurovskii, L. G. Glukhatkina, G. M. Pankratova, I. E. Sorokina, and T. V. Maksimova, “Development of heat and cold resistant rubbers for flexible hoses on the basis of siloxane rubbers and domestic silica fillers,” Prom. Proizv. Ispol’z. Elastom., No. 1, 28–31 (2016).

10.

V. V. Kondrat’ev, N. A. Ivanov, A. E. Balanovskiy, N. N. Ivanchik, and A. I. Karlina, “Improving the properties of gray cast iron using silica- and carbon-based nanostructures,” Zh. Sibirsk. Federal. Univ. Ser. Tekhn. Tekhnol., 9, No. 5, 671–685 (2016).

11.

N. N. Ivanchik, A. E. Balanovskiy, V. V. Kondrat’ev, A. A. Tyutrin, and M. P. Kuz’min, “Application of silicon waste processing products as ultradispersed activating fluxes for arc welding,” Vestn. IrGTU, 20, No 12 (119), 165–172 (2016).

12.

M. P. Kuz’min, V. V. Kondrat’ev, L. M. Larionov, M. Yu. Kuz’mina, and N. N. Ivanchik, “Possibility of preparing alloys of the Al-Si system using amorphous microsilica,” Metallurgist, 61, No. 1-2, 86–91 (2017).

13.

A. I. Karlina, V. V. Kondrat’ev, A. D. Kolosov, A. E. Balanovskiy, and N. A. Ivanov, “Production of new nanostructures for modification of steels and cast irons,” in: IOP Conf. Series: Mater. Sci. and Eng. (2019), p. 012183.

14.

V. A. Vasin, N. G. Fat’yanova, B. A. Troshin, B. N. Vasichev, and S. V. Stepanchikov, “Problems associated with the creation of nanoproducts using nanotechnologies,” Elektrotekh. Inf. Kompl. Sist., 8, No. 4, 37–43 (2012).

15.

N. Gerasimenko, A. Volokhovskii, and O. Zaporozhan, “Specifics of controlling the technology for silicon nanostructures,” Nanoindustriya, No. 5 (76), 36–51 (2017).

16.

V. I. Kodolov, A. Yu. Bondar’, and A. P. Kuznetsov, “Technology for producing carbon metal-containing nanostructures in the nanoreactors of polymer matrices (on the example of PVA),” Nanotekhnika, No. 1 (9), 38–41 (2007).

17.

A. R. Khokhlun, “Equipment and technologies for producing MEMS, micro and nanostructures,” Elektron. Elektrooborud. Transp., No. 6, 36–38 (2008).

18.

M. P. Kuz’min, N. A. Ivanov, V. V. Kondrat’ev, M.Yu. Kuz’mina, A. I. Begunov, A. S. Kuz’mina, N. N. Ivanchik, and V. G. Grigor’ev, “Preparation of aluminum-carbon nanotubes composite material by hot pressing,” Metallurgist, 61, No. 9-10, 815–821 (2018).

19.

V. A. Ershov, V. V. Kondrat’ev, I. A. Sysoev, and A. O. Mekhnin, “Extraction of carbon nanoparticles from fluorinated alumina during aluminum production,” Metallurgist, 56, No. 11-12, 952–956 (2013).

20.

V. N. Petrovskaya and V. V. Kondrat’ev, “Gas-hydrodynamic nature of the anode effect,” Metallurgist, 56, No. 3-4, 215–221 (2012).

21.

V. V. Kondrat’ev, V. N. Petrovskaya, É. P. Rzhechitskii, A. A. Nemarov, and N. N. Ivanchik, “Carbon foam of aluminum electrolyzers and carbon nanotubes (CNTs) present in it,” Vestn. IrGTU, No. 12 (107), 215–223 (2015).

22.

V. N. Petrovskaya, V. V. Kondrat’ev, A. A. Nemarov, and A. A. Petrovskii, “Carbon nanotubes in the production of crystalline silicon,” Ekol. Promyshl. Rossii, 21, No. 1, 17–23 (2017).

23.

N. N. Ivanchik, V. N. Petrovskaya, V. V. Kondrat’ev, and A. A. Nemarov, “Study and development of processes for obtaining target products from the finely dispersed waste of silicon production,” Sist. Met. Tekhnol., No. 2 (26), 133–137 (2015).

Titel: Process Control System for Producing a Silica-Based Modifying Additive
verfasst von: V. A. Ershov
A. I. Karlina
Yu. I. Karlina
Publikationsdatum: 05.07.2021
Verlag: Springer US
Erschienen in: Metallurgist / Ausgabe 3-4/2021
Print ISSN: 0026-0894
Elektronische ISSN: 1573-8892
DOI: https://doi.org/10.1007/s11015-021-01175-0

Production of Aluminum Matrix Composite Material Hardened with Hollow Ceramic Microspheres

Analysis of the Specific Features of Wear of the Working Rolls of the Finishing Group of Stands Under Conditions of the 1950 Mill at the Casting-Rolling Complex of the “VMZ” JSC

Automatic Temperature Control System for Electric Resistance Annealing of Steel Welding Wire

Correction to: Investigation of the Process of Synthesizing Nanosized Nickel Powders by Hydrogen Reduction under Nonisothermal Conditions

Author Correction

Improvement of the Devices for Filling the Crystallizers of Continuous Casting Machines with Liquid Metal

Establishment of the Temperature Field Model of 72LX Blooms in the Reheating Furnace

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Bildnachweise

MKVS GbR/© MKVS GbR, Nordson/© Nordson, ViscoTec/© ViscoTec, BCD Chemie GmbH, Merz+Benteli/© Merz+Benteli, Robatech/© Robatech, Hermann Otto GmbH/© Hermann Otto GmbH, Ruderer Klebetechnik GmbH, Fere/© Fere, Xometry Europe GmbH/© Xometry Europe GmbH, Scheugenpflug/© Scheugenpflug, Sika/© Sika, Medmix/© Medmix, Kisling AG/© Kisling AG, Dosmatix GmbH/© Dosmatix GmbH, Innotech GmbH/© Innotech GmbH, Hilger u. Kern GmbH, VDI Logo/© VDI Wissensforum GmbH