Treatment of external thermal insulation composite systems (ETICS) with bio corrosion with respect to environment protection

Vestnik MGSU 9/2018 Volume 13
  • Antošová Naďa - Slovak University of Technology in Bratislava associate professor of the Department of Building Technology, Slovak University of Technology in Bratislava, 11 Radlinského, Bratislava, 813 68, Slovakia.
  • Minarovičová Katarína - Slovak University of Technology in Bratislava senior lecturer of the Department of Building Constructions, Faculty of Civil Engineering, Slovak University of Technology in Bratislava, 11 Radlinského, Bratislava, 813 68, Slovakia.
  • Belániová Barbora - Slovak University of Technology in Bratislava Postgraduate student of the Department of Building Technology, Faculty of Civil Engineering, Slovak University of Technology in Bratislava, 11 Radlinského, Bratislava, 813 68, Slovakia.

Pages 1106-1111

Subject: the treatment of External Thermal Insulation Composite Systems (ETICS) surfaces affected by bio-corrosion takes place as a part of planned or operational maintenance. As part of this process, ambient environments are loaded with running water and detergents that contain heavy metals. The article presents the results of research on reducing the impact of environmental contamination by cleaning and preventive coating of ETICS surfaces with biocides. The paper gives an overview of the problem and new approaches to the treatment of new and renovated buildings. Purposes: at the present time, the maintenance of existing ETICS lacks system solutions, instead using chemical methods for the treatment of contamination by microorganisms. While complete information on environmental impacts is lacking it is necessary to take this into consideration. The cost of renovation, which should include investment for future treatment of ETICS surfaces, is often underestimated. Film preservation biocides contain both algaecides and fungicides. Consequently, ETICS preservation agents in exterior paints and renders represent a potential risk for humans, animals and the wider biological environment and new concepts underlying more sustainable approaches are required. Materials and methods: the research was based on an evaluation of existing technologies for eliminating microorganisms from the ETICS surfaces and an analysis of their environmental effects. The aim was to find optimal operational and planned ETICS maintenance approaches that minimise negative environmental effects. Results: environmentally-friendly approaches were identified and a new leaching system for safe dewatering was designed. These approaches differ according to their suitability for periodic or operational maintenance. Conclusions: there is a wide range of materials used for ETICS finishes. It is important to consider the reliability and maintainability of the construction across the entire life cycle of a building. Operation and maintenance should be a significant element of the life-cycle cost of a building. The removal of bio corrosion coatings from ETICS structures by means of chemical and preservative substances (biocides) is currently the most-used and only effective technology. The uncontrolled release of applied chemicals is unacceptable. A system designed for collecting wastewater from the cleaned surface is considered an effective means of reducing the deleterious effects of biocidal substances on the environment. The safe dewatering of chemicals leached from the surface of the facade is presented by a drain system designed in accordance with the building type, use and age.

DOI: 10.22227/1997-0935.2018.9.1106-1111

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CAST-IN-PLACE BUILDING FRAME AND ITS FEATURES AT SEPARATE LIFE CYCLES

Vestnik MGSU 9/2015
  • Koyankin Aleksandr Aleksandrovich - Siberian Federal University (SibFU) Candidate of Technical Sciences, Associate Professor, Department of Building Structures and Control Systems, Siberian Federal University (SibFU), 79 Svobodny Avenue, Krasnoyarsk, 660041, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Mitasov Valeriy Mikhaylovich - Novosibirsk State University of Architecture and Civil Engineering (Sibstrin) (FGBOU VPO NGASU) Doctor of Technical Sciences, Professor, chair, Department of Reinforced Concrete Structures, Novosibirsk State University of Architecture and Civil Engineering (Sibstrin) (FGBOU VPO NGASU), 113 Leningradskaya str., Novosibirsk, 630008, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 28-35

Modern intensive development of precast-cast-in-place construction has led to creation of a wide range of various constructive systems of buildings during the last 100 years. They allow constructing buildings with best account of the requirements of functionality, architectural expressiveness, production possibilities of construction companies, etc. However in spite of this development both precast and cast-in-place housing construction has its peculiarities, positive and negative ones. The constructive systems of precast monolithic buildings existing at the moment are based on the required mutual deformation of prefabricated reinforced and cast iron reinforced concrete at the stage of a building construction and at the stage of its use as well. Having refused from this rule, the authors of this article have introduced a constructive system of a precast monolithic building able to bear loads, developing at the stage of erection (due to completion of a precast frame) and at the stage of use (due to completion of a precast monolithic frame). The offered construction of a precast monolithic building frame allows efficiently using the advantages of precast and cast-in-place construction minimizing their disadvantages and it also fully corresponds to the obligatory requirements to buildings. The corresponding patents are obtained.

DOI: 10.22227/1997-0935.2015.9.28-35

References
  1. Mordich A.I., Belevich V.N., Simbirkin V.N., Navoy D.I., Mironov A.N., Raychev V.P., Chubrik A.I. Effektivnye konstruktivnye sistemy mnogoetazhnykh zhilykh domov i obshchestvennykh zdaniy (12…25 etazhey) dlya usloviy stroitel’stva v Moskve i gorodakh Moskovskoy oblasti, naibolee polno udovletvoryayushchie sovremennym marketingovym trebovaniyam [Effective Constructional Systems of Multistory Blocks of Flats and Civil Buildings (12…25 Storey) for the Construction Conditions in Moscow and the Cities of Moscow Region, More Fully Fulfilling Modern Marketing Demands]. Minsk, NIEPUP “Institut BelNIIS” Publ., 2002, 117 p. (In Russian)
  2. Unifitsirovannaya sistema sborno-monolitnogo bezrigel’nogo karkasa KUB 2.5. Vypusk 1-1 / TsNIIPI «Monolit» [Unified System of Precast-Cast-in-place Reinforced Concrete Composite Frame without Collar Beams KUB 2.5. Edition 1-1 / TSNIIPI “Monolit”]. Moscow, Stroyizdat Publ., 1990, 49 p. (In Russian)
  3. Shembakov V.A. Sborno-monolitnoe karkasnoe domostroenie: rukovodstvo k prinyatiyu resheniya [Cast-in place and Precast Frame House-Building. Guidance for Decision-Making]. 2-nd edition, revised. Cheboksary, OOO “Cheboksarskaya tipografiya № 1” Publ., 2005, 119 p. (In Russian)
  4. Mitasov V.M., Koyankin A.A. Rabota diska sborno-monolitnogo perekrytiya [Operation of a Precast Monolithic Slab]. Izvestiya vysshikh uchebnykh zavedeniy. Stroitel’stvo [News of Higher Educational Institutions. Construction]. 2014, no. 3, pp. 103—109. (In Russian)
  5. Nikitin N.V., Franov P.I., Timonin E.M. Rekomendatsii po proektirovaniyu konstruktsiy ploskogo sborno-monolitnogo perekrytiya «Sochi» [Recommendations for Engineering of the Constructions of Flat Precast Monolithic Slab “Sochi”]. 3-rd edition, revised. Moscow, Stroyizdat Publ., 1975, 34 p. (In Russian)
  6. Koyankin A.A., Mitasov V.M. Eksperimental’nye issledovaniya raboty stykovogo soedineniya rigelya s kolonnoy v sborno-monolitnom perekrytii [Experimental Study of the Operation of the Bolt Joint of a Bearer with a Column in Precast-Monolithic Ceiling]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2015, no. 5, pp. 27—34. (In Russian)
  7. Sakhnovskiy K.V. Zhelezobetonnye konstruktsii [Reinforced Concrete Constructions]. 8th edition. Moscow, Gosstroyizdat Publ., 1960, 840 p. (In Russian)
  8. Mordich A.I. Sborno-monolitnye i monolitnye karkasy mnogoetazhnykh zdaniy s ploskimi raspornymi perekrytiyami [Precast-Monolithic and Monolithic Frames of Multistoreyed Buildings with Flat Brace Floor]. Montazhnye i spetsial’nye raboty v stroitel’stve [Building and Special Works in Construction]. 2001, no. 8—9, pp. 10—14. (In Russian)
  9. Mordich A.I. Belevich V.N., Simbirkin V.N., Navoy D.I. Opyt prakticheskogo primeneniya i osnovnye rezul’taty naturnykh ispytaniy sborno-monolitnogo karkasa BelNIIS [Experience of Practical Application and the Main Results of Field Studies of the Precast-Monolithic Frame BelNIIS]. BST: Byulleten’ stroitel’noy tekhniki [BST: Bulletin of Construction Technologies]. 2004, no. 8, pp. 8—12. (In Russian)
  10. Mordich A.I., Sadokho V.E., Podlipskaya I.I., Taratynova N.A. Sborno-monolitnye prednapryazhennye perekrytiya s primeneniem mnogopustotnykh plit [Precast-Monolithic Prestressed Slabs Using Hollow Core Slabs]. Beton i zhelezobeton [Concrete and Reinforced Concrete]. 1993, no. 5, pp. 3—6. (In Russian)
  11. Weber H., Bredenbals B., Hullman H. Bauelemente mit Gittertragern. Institut fur Industrialisierung des Buens. Hannover, 1996, 24 p.
  12. Dimitrijevic R. A Prestressed «Open» System from Jugoslavia. Système «ouvert» précontraint yougoslave. Batiment Informational, Building Research and Practice. 1978, vol. 6, no. 4, pp. 244, 245—249. Nauchno-tekhnicheskiy referativnyy sbornik TsINIS [Science and Technical Abstract Collection of the Central Institute of Scientific Information on Construction]. 1979, vol. 14, no. 3, pp. 8—12.
  13. Bausysteme mit Gittertragern. Fachgruppe Betonbauteile mit Gittertragern im BDB. Bonn, 1998, 40 p.
  14. Schwerm D., Jaurini G. Deskensysteme aus Betonfertigteilen. Informationsstelle Beton-Bauteile, 1997, Bonn, 37 p.
  15. Pessiki S., Prior R., Sause R., Slaughter S. Review of Existing Precast Concrete Gravity Load Floor Framing System. PCI Journal. 1995, vol. 40, no. 2, pp. 52—67.
  16. Koprivitsa B. Primenenie karkasnoy sistemy IMS dlya stroitel’stva zhilykh i obshchestvennykh zdaniy [Application of Frame System IMS for Constructing Residentialand Public Buildings]. Zhilishchnoe stroitel’stvo [Housing Construction]. 1984, no. 1, pp. 30—32. (In Russian)
  17. Semchenkov A.S. Obosnovanie regional’no-adaptirovannye industrial’noy universal’noy stroitel’noy sistemy «RADIUSS» [Reasons of Regional-Adaptive Industrial Universal Construction System “RADIUSS”]. Beton i zhelezobeton [Concrete and Reinforced Concrete]. 2008, no. 4, pp. 1—7. (In Russian)
  18. Semchenkov A.S. Regional’no-adaptiruemye sborno-monolitnye stroitel’nye sistemy dlya mnogoetazhnykh zdaniy [Regional-Adaptive Precast-Cast-in-place Constructional Systems for Multi-Storied Buildings]. Beton i zhelezobeton [Concrete and Reinforced Concrete]. 2010, no. 3, pp. 2—6. (In Russian)
  19. Kimberg A.M. Effektivnaya konstruktivnaya sistema karkasno-panel’nykh zdaniy s natyazheniem armatury v postroechnykh usloviyakh (metodicheskie rekomendatsii) [Effective Constructive System of Frame-Panel Buildings with Tensioning of the Steel in Site Conditions (Methodological Recommendations)]. Tbilisi, TbilZNIIEP Publ., 1985, 33 p. (In Russian)
  20. Kazina G.A. Sovremennye zhelezobetonnye konstruktsii seysmostoykikh zdaniy [Modern Reinforced Concrete Structures of Earthquake-Resistant Buildings]. Moscow, VNIIS Publ., 1981, 25 p. (In Russian)

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METHODOLOGY OF ENVIRONMENTAL ASSESSMENT OF BUILDING MATERIALS

Vestnik MGSU 2/2013
  • Ustinova Yuliya Valer’evna - Moscow State University of Civil Engineering (MGSU) Candidate of Technical Sciences, Associate Professor, Department of General Chemistry, Moscow State University of Civil Engineering (MGSU), 6 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Nasonova Alla Evgenievna - Moscow State University of Civil Engineering (MGSU) +7 (499) 183-32-92, Moscow State University of Civil Engineering (MGSU), 6 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 123-129

The article covers the importance of environmental assessments of building materials. Magnesium binding materials were selected as the subject of the environmental analysis. The water resistance of these materials is regarded as one of environmental criteria. Thus, the purpose of this paper is an assessment of the life cycle of additives proposed to improve the water resistance of magnesium binding materials. Redispersible polymer powder based on the copolymer of vinyl acetate and vinilversatata, polyvinyl acetate dispersion, sodium carboxymethyl cellulose, oxalic acid, chrysotile asbestos, modified using concentrated sulfuric acid and micro-silica were selected for research purposes.The following findings have been generated in the course of the research:1. Correlation between the environmental assessment of the application of modifiers with the strength test results of caustic magnesite samples in dry and saturated states is identified.2. Organic additives classified as producing an unsatisfactory environmental impact do not significantly affect the water resistance of the caustic magnesite sample.3. Oxalic acid, chrysotile asbestos modified using sulfuric acid and micro-silica are acceptable for magnesium binding materials in terms of their environmental analysis.4. Micro-silica is the additive that demonstrates the best properties both in terms of its environmental analysis and in terms of improving the water resistance of magnesium binding materials.5. Environmental analysis of the life cycle of modifiers can be recommended as an important stage in the planning of experiments aimed at improvement of properties of building materials.

DOI: 10.22227/1997-0935.2013.2.123-129

References
  1. Kohler N. Grundlagen zur Bewertung kreislaufgerechter, nachhaltiger Baustoffe, Bauteile und Bauwerke 20. Aachener Baustofftag. March 3, 1998.
  2. Knyazeva V. P. Ekologicheskie aspekty vybora materialov v arkhitekturnom proektirovanii [Environmental Aspects of Selection of Materials in the Architectural Design]. Moscow, Arkhitektura-S Publ., 2006, 296 p.
  3. Rogovin Z.A. Khimicheskie prevrashcheniya i modifikatsiya tsellyulozy [Chemical Transformations and Modification of Cellulose]. Moscow, Khimiya Publ., 1987, 173 p.
  4. Patent RF 2375323. Sposob polucheniya silikokizeritovogo vyazhushchego [RF Patent 2375323. Method of Generation of the Silica-kizerit Binding Material]. Published on December 10, 2009.
  5. Pustovgar A.P. Effektivnost’ dobavok mikrokremnezema pri modifikatsii betonov [Effectiveness of Micro-silica Additives If Used to Modify Concretes]. StroyPROFIl’ Internetzhurnal [Construction Profile Internet Journal]. 2005, no. 8. Available at: http // storyprofile.com/archive/1980. Date of access: December 06, 2012.
  6. Legostaeva N.V. Magnezial’nye vyazhushchie i materialy na ikh osnove iz magnezitov Savinskogo mestorozhdeniya [Magnesia Binders and Materials on Their Basis Made of Magnesites of Savinskoye Deposit]. Tomsk, 2006.

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State order economic efficiency examination

Vestnik MGSU 10/2014
  • Piskarev Aleksandr Igorevich - Moscow State University of Civil Engineering (MGSU) postgraduate student, Department of Economics and Modern Management Principles in Construction and Real Estate, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 177-187

The monitoring procedure is an integral part for tracking the results of tendering. It’s also necessary for patterns’ identification to make subsequent legislative adjustments. This article includes the Western experience analysis of the state contracts’ tracking with underlining of its main features. The U.S. Federal contract system includes the Act called «The Office of the U.S. state order», which was adopted in 1974. The Act requires creating a system for collecting information about federal government contracts. It is OMB’s obligation. Federal data bank of the state order was created in 1978. The control system of public procurement procedures, serving in Germany, meets the requirements of the EU, but has certain specifics. All the organizations, which are equated to government customers in accordance with the definition of the European Union, are in the sphere of public procurement procedures’ control system. Thus, the state customer is also a number of private entities. The control system includes two instances: 1) the appellate court, which exists in the form of an independent institution; 2) the court, which exists in the form of a judicial authority. The governmental experts’ and scientists’ organization called “State orders forum” is very effective and popular in Germany. Its members exchange their opinions on new developments in public procurement within the country and abroad. The article includes the analysis of the existing public orders monitoring procedures. Also the laws of procurement implementation, which exists at the stage of bidding and contractual obligations, are highlighted in the article. The consequences of ignoring the existing problems of public order in Russia are systematized. The main drawbacks of the state order control system are identified. In this article the existing public systems of the state order monitoring in Russia are inventoried. The requirement of cardinal processing the format and scope of the information is provided. Also the rules, which should serve as a new base for the state order controlling system, are formulated. What is more, the article includes the Moscow Construction Department as an example of the system tracking the procurement procedures. We offer a hypothetical model of the state order economic examination, based on the resulting data rates: price reduction in tendering; the number of participants in the tendering; execution of the contract term; life cycle costs; the quality of products; the presence of documented violations. Each indicator is assigned an importance factor in achieving the overall efficiency, which is defined by experts with the participation of government customers’. Determination of the complex efficiency index occurs by summing the obtained parameters. The results are obtained. The conclusions are formulated. Thus, the vector of the state order analysis direction from monitoring data to the hypothetical model of efficiency examination is defined.

DOI: 10.22227/1997-0935.2014.10.177-187

References
  1. Piskarev A.I. Raschet nachal’noy (maksimal’noy) tseny gosudarstvennogo kontrakta na vypolnenie podryadnyh rabot [Initial (maximum) Contract Price Calculation for the State Order]. Goszakaz [State Order]. 2014, no. 35, pp. 67—73. (in Russian)
  2. Karpinskaya E.S., Bereza A.O., Bogdanov T. Transfertnoe tsenoobrazovanie v stroiyel’nykh organizatsiyakh [Transfer Pricing of Construction Organizations]. Bukhuchet v stroitel’nykh organizatsiyakh [Accounting in Construction Companies]. 2014, no. 4, pp. 60—71. (in Russian)
  3. Yas’kova N.Y., Silka D.N., Bakrunov Yu.O. Razvitie investitsionno-stroitel’nykh protsessov v usloviyakh globalizatsii [Development of Investment and Construction Processes in the Globalization Conditions]. Moscow, MAIES Publ., 2009, 520 p. (in Russian)
  4. Chemerisov M.V. Kontraktnye otnosheniya: mezhdunarodnyy, regional’nyy i korporativnyy opyt [Contractual Relationship: International, Regional and Corporate Experience]. Available at: http://economy.gov.ru/minec/about/structure/depfks/doc20100806_06. Дата обращения: 08.02.2014. (in Russian)
  5. Federal Acquisition Regulation (FAR). 2005, vol. 1, 1889 p. Available at: https://acquisition.gov/far/current/pdf/FAR.pdf. Date of access: 01.03.2014.
  6. Albano G.L., Sparro M. Flexible Strategies for Centralized Public Procurement. Review of Economics and Institutions. 2010, vol. 1, no. 2, art. 4. Available at: http://www.rei.unipg.it/rei/article/view/17. Date of access: 14.02.2014. DOI: http://dx.doi.org/10.5202/rei.v1i2.17/.
  7. Brammer S., Walker H. Sustainable Procurement Practices in the Public Sector: An International Comparative Study. University of Bath: School of Management. Working Paper Series. 2007, no. 16. Available at: http://www.bath.ac.uk/management/research/pdf/2007-16.pdf. Date of access: 08.02.2014.
  8. Andreeva A. Mirovoy opyt goszakupok [World Experience of State Procurements]. Byudzhet [Budget]. 2006, no. 9. Available st: http://bujet.ru/article/2895.php. Date of access: 08.02.2014. (in Russian)
  9. Shumaev V.A. Sovershenstvovanie upravleniya gosudarstvennym sektorom ekonomiki s uchetom opyta zarubezhnykh stran [Improving of the State Economy Sector Management Basing on Foreign Experience]. Mekhanizatsiya stroitel’stva. [Automation of Construction]. 2013, no. 10, pp. 49—51. (in Russian)
  10. Balashov V.V., Fisunov K.V. Sistema monitoringa v ramkakh ekspertizy realizatsii gosudarstvennogo zakaza [Monitoring System in Frames of Public Order Implementation Examination]. Upravlenie ekonomicheskimi sistemami [Management of Economic Systems]. 2012, no. 48. Available at: http://www.uecs.ru/marketing/item/1876-2012-12-25-08-50-27. Date of access: 08.02.2014. (in Russian)
  11. Reyting Spetsializirovannykh organizatsiy po provedeniyu torgov v sootvetstvii s zakonom o razmeshchenii zakazov za 2013 god [Rating of Specialized Organizations on Tendering According to Law on Placing of Contracts]. Available at: http://www.mosgorzakaz.ru/2013.html. Date of access: 28.04.2014. (in Russian)
  12. Burak P.I. Investitsionno-stroitel’nyy kompleks Moskvy v usloviyakh territorial’noy ekspansii goroda [Construction and Investment Complex of Moscow in Terms of Territorial Expansion of the City]. Ekonomika stroitel’stva [Construction Economics]. 2014, no. 1, pp. 12—25. (in Russian)
  13. Gur'ev V.V., Dmitriev A.N., Sichareva A.Y., Sazhneva Z.S. Ekonomiko-tekhnologicheskaya effektivnost’ stroitel’noy otrasli Moskvy [Economic and technological efficiency of the Moscow’s’ construction industry]. Promyshlennoe i grazdanskoe stroitel’stvo [Industrial and Civil Engineering]. 2014, no. 1, pp. 37—42. (in Russian)
  14. Goryachev I.E. O rabote assotsiatsii ekspertizy stroitel’nykh proektov v 2013 godu [On the Work of the Association of Construction Projects’ Examination in 2013]. Promyshlennoe i grazdanskoe stroitel’stvo [Industrial and Civil Engineering]. 2014, no. 4, pp. 29—33. (in Russian)
  15. Makushchenko M.P. Razvitie regional’nogo mekhanizma povysheniya effektivnosti ispol’zovaniya rynochnogo potentsiala stroitel’nykh predpriyatiy [Development of a Regional Mechanism for Improving the Efficiency of Construction Enterprises’ Market Potential]. Ekonomika stroitel’stva i gorodskogo hozyaystva [Economy of Construction and Municipal Services]. 2013, vol. 9, no. 4, pp. 313—320. (in Russian)
  16. Grabovyy P.G., Bredikhin V.V., Kapyrin D.A. Problemy upravleniya proizvodstvenno-tekhnicheskim potentsialom territorial’no-investitsionnogo stroitel’nogo kompleksa (TISK) v usloviyakh konkurentnoy sredy [Management Problems of Production and Technical Potential of Spatial and Investment Construction Complex in Competitive Environment]. Nedvizhimost’: ekonomika, upravlenie [Real Estate: Economics, Management]. 2012, no. 1, pp. 47—51. (in Russian)
  17. Gushchin A.Yu. Opredelenie effektivnosti i sposoby ee otsenki v sisteme gosudarstvennogo zakaza [Definition of Efficiency and Methods of its Evaluation in the State Order System]. Fundamental’nye issledovaniya [Basic Research]. 2012, no. 9, part 1, pp. 204—208. (in Russian)
  18. Saydayev Kh.L.-A. Metodika vybora stroitel’noy kompanii v ramkakh organizatsii tendera na osnove rascheta kompleksnogo pokazatelya rezul’tativnosti [Methodology of Choosing a Construction Company for Tender on the Basis of Estimating Complex Efficiency Index]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2013, no. 10, pp. 266—271. (in Russian)

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INTERACTION BETWEEN MODELS OF THE LIFE CYCLE OF INDUSTRIAL ENTERPRISE AND CYCLE OF ITS REORGANIZATION

Vestnik MGSU 3/2012
  • Chulkov Vitaliy Olegovich - Moscow State Academy of Communal Services and Construction (MSUCSC) , Moscow State Academy of Communal Services and Construction (MSUCSC), 30 Srednyaya Kalitnikovskaya St., Moscow, 109029, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Kulakov Kirill Yurevich - Moscow State University of Civil Engineering (MSUCE) , Moscow State University of Civil Engineering (MSUCE), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Grabovyy Kirill Petrovich - Moscow State University of Civil Engineering (MSUCE) , Moscow State University of Civil Engineering (MSUCE), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Gazaryan Robert Kamoevich - Moscow State University of Civil Engineering (MSUCE) , Moscow State University of Civil Engineering (MSUCE), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 223 - 227

The objective of this scientific research is to develop a theoretical model of organizational and technology-related processes of reorganization of industrial enterprises, as well as their interaction. Multipoint logic notions of growth and interaction phases are used as research methods. The author describes the basic stages of reorganization, the life cycle of industrial enterprises and the cycle of their transformation. The processes are presented as an infographical image that represents a concentric model of interaction. This concentric model represents interaction between two or more phases. The process is entitled infografical modeling on the polyfunctional level. The concentric model moves both clockwise and anti-clockwise. Basic organizational and technological processes of reorganization of industrial enterprises that include decision making in terms of expediency of reorganization, design, construction, and performance of industrial enterprises at full capacity, and further operation of the industrial enterprise are described in the paper. Attainment of this objective, namely, reorganization of an industrial enterprise, involves a huge amount of resources, including labour resources that need interaction with all parties of reorganization; therefore, the concentric model of interaction describing the basic cycle of reorganization, the life cycle of an industrial enterprise and the cycle of its conversion is a trustworthy representation of this process. The proposed concentric model of interaction should be used in the design of organizational and technology-related processes for integrated consideration of reorganization of enterprises required to understand and improve the efficiency of reorganizations and to control the reorganization of industrial facilities.

DOI: 10.22227/1997-0935.2012.3.223 - 227

References
  1. INFOGRAFIYA. Tom 2: Infograficheskoe modelirovanie nelinyeinykh virtual’nykh funktsional’nykh sistem soorganizatsii dyeyatel’nosti [INFOGRAFICS. Part 2: Infografical Simulation of Nonlinear Functional Systems of Co-organized Operations]. Edited by Chulkov V.O. Moscow, 2007, 264 p.

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Problem solving on the basis of information models of buildings

Vestnik MGSU 9/2012
  • Ignatova Elena Valentinovna - Moscow State University of Civil Engineering (MGSU) Candidate of Technical Sciences, Associate Professor, Department of Information Systems, Technology and Automation in Civil Engineering 8 (499) 182-66-38, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 241 - 246

The author considers the potential of information models of buildings exemplified by the application
of Allplan technologies. Consecutive stages of research and problems under consideration
are described. The efficiency of different tools and approaches are discussed.
At the first stage, standard Allplan tools are analyzed. At the second stage, the problem of
integration and interoperability of different software programmes is analyzed. At the third stage,
the attempt to further the functional capabilities of the software programme by developing supplementary
plug-ins is made. At the fourth stage, compilation of electronic passports of buildings is
considered. The article deals with the prospects for the development of the information technology
of building models.

DOI: 10.22227/1997-0935.2012.9.241 - 246

References
  1. Ignatova E.V. BIM-aktual’naya tendentsiya v avtomatizatsii proektirovaniya [BIM as a Relevant Trend in Computer Aided Design]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2009, Special Issue, pp. 225 — 226.
  2. Ignatov V.P., Ignatova E.V. Analiz napravleniy issledovaniy, osnovannykh na kontseptsii informatsionnogo modelirovaniya stroitel’nykh ob”ektov [Analysis of Lines of Research Based on the Concept of Information Modeling of Buildings]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2011, no. 1, vol.1, pp. 325 — 330.
  3. Ignatov V.P., Ignatova E.V. Effektivnoe ispol’zovanie informatsionnoy modeli stroitel’nogo ob”ekta [Building Information Model: Effective Use]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2011, no. 1, vol.1, pp. 321 — 324.

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DESCRIPTION OF THE ORGANIZATIONAL AND TECHNOLOGICAL PROCESSES ON THE GROUND OF THE BASIC MODEL OF THE CYCLE OF REORGANIZATION

Vestnik MGSU 12/2012
  • Gazaryan Robert Kamoevich - Moscow State University of Civil Engineering (MSUCE) , Moscow State University of Civil Engineering (MSUCE), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Chulkov Vitaliy Olegovich - Moscow State Academy of Communal Services and Construction (MSUCSC) , Moscow State Academy of Communal Services and Construction (MSUCSC), 30 Srednyaya Kalitnikovskaya St., Moscow, 109029, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Fakhratov Viktor Mukhammetovich - Moscow State University of Civil Engineering (MGSU) postgraduate student, Department of Information Technologies and Automation in the Construction Industry, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Guseva Ol'ga Borisovna - Moscow State University of Civil Engineering (MGSU) Associate Professor, Department of Construction of Thermal Power Plants and Nuclear Plants, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 248 - 252

The objective of this scientific research is application of the basic model of interaction between phases of a cycle of reorganization of organizational and technological processes underway at industrial enterprises.
The authors describe interactions between all six phases of the process of reorganization within the framework of the basic model of a cycle that contemplates organizational and technological processes.
Engineering studies are necessary to check for the feasibility of reorganization of industrial enterprises and application of results extracted from the design documentation with a view to reorganization of production activities and construction operations. Upon completion of the decision-making process concerning the need for reorganization in accordance with the basic model of interaction between phases, there occurs restructuring that incorporates processes of design and construction. The authors have demonstrated that reorganization of the basic model cycle should be used in the design of organizational and technological processes with a view to the integrated consideration of reorganization of enterprises in order to comprehend and improve the efficiency of reorganization at each stage, as well as the control over the reorganization of a construction facility.

DOI: 10.22227/1997-0935.2012.12.248 - 252

References
  1. Chulkov V.O., editor. Infografi ya. Tom 2: Infografi cheskoe modelirovanie nelineynykh virtual’nykh funktsional’nykh sistem soorganizatsii deyatel’nosti [Infographics. Vol. 2. Inforgraphic Modeling of Nonlinear Virtual Functional Systems of Co-organization of Activities]. Seriya «Infografi cheskie osnovy funktsional’nykh sistem» (IOFS) [Infographic Fundamentals of Functional Systems Series (IOFS)]. Moscow, SvR-ARGUS Publ., 2007, 264 p.
  2. Volkov A.A., Pikhterev D.V. K voprosu ob organizatsii informatsionnogo obespecheniya stroitel’nogo ob”ekta [On the Issue of Information Support of Construction Facilities]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2011, no. 6, pp. 460—462.
  3. GOST R 53778—2010: «Zdaniya i sooruzheniya. Pravila obsledovaniya i monitoringa tekhnicheskogo sostoyaniya». [State Standard of Russia 53778-2010. Buildings and Structures. Rules of Examination and Monitoring of Their Technical Condition]. Approved and put into effect by Order issued by the Federal Agency for Technical Regulations of March 25, 2010.
  4. Gradostroitel’nyy kodeks Rossiyskoy Federatsii [Urban Planning Code of the Russian Federation] of December 29, 2004. Federal law ¹190-FZ, passed in Moscow by the State Duma of the Federal Meeting of the Russian Federation on December 22, 2004.
  5. GOST 27751—88: «Nadezhnost‘ stroitel‘nykh konstruktsiy i osnovaniy». [State Standard 27751—88. Reliability of Structures and Beddings]. Approved and put into effect by Resolution of March 25, 1998 of the State Committee for Construction, Utilities and Housing.
  6. SP 13-102—2003: «Pravila obsledovaniya nesushchikh stroitel’nykh konstruktsiy zdaniy i sooruzheniy» [Construction Rules 13-102—2003. Rules of Examination of Bearing Structural Units of Buildings and Structures]. Approved and put into effect by Resolution of State Committee for Construction, Utilities and Housing of August 21, 2003.

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Methodological approaches to assessing the innovativeness level of investment and construction projects

Vestnik MGSU 2/2015
  • Dolzhenko Yuliya Aleksandrovna - Plekhanov Russian University of Economics (PRUE); LLC “K4” postgraduate student, Department of Projects and Programs Management; chief specialist, Systems Analysis Group, Plekhanov Russian University of Economics (PRUE); LLC “K4”, 36 Stremyannyy pereulok, Moscow, 117997, Russian Federation; 2/4-17 Luzhnetskaya naberezhnaya, Moscow, 119270, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 178-186

The article presents the results of the analysis of the existing approaches to innovations evaluation in international and Russian practice. The authors examine the nature of the concept of “innovation”, especially innovation projects, methodological tools to measure various objects’ innovativeness level as well as innovative project economic efficiency assessing methods. It should be noted that at the legislative level up to date in the process of formation and implementation of capital construction projects there are no eligible requirements and assistance from public authorities to the developer for creating innovative products, providing the appropriate level of services. And if the financial indicators of the project are more or less clear, the level of innovativeness of them is much more complicated, although the requirements on the innovativeness of the projects are included in the Strategy of innovative development of Russia. The analysis shows that in Russian and international practice there are many approaches to assessing innovations, but they cannot be considered universal and they are applied differentially depending on the goals and tasks of applying the results of scientific achievements in the form of intellectual property to improve the efficiency and competitiveness of industries, products, services. In this case individual, specific evaluation method is selected and implemented basing on taking into account all the legal, economic, technical and other aspects. As a result, the author concluded that the innovativeness level rating requires development, which is in its analytical capabilities to provide flexible management tool, which can be applied at all the stages of the investment and construction project life cycle.

DOI: 10.22227/1997-0935.2015.2.178-186

References
  1. Arbatskaya E.A. Podkhody k otsenke konkurentosposobnosti predpriyatiya [Approaches to Assess the Competitiveness of an Enterprises]. Izvestiya Irkutskoy gosudarstvennoy ekonomicheskoy akademii [News of Irkutsk State Economic Academy]. 2012, no. 1 (81), pp. 118—128. (In Russian)
  2. Bachurina S.S., Dolzhenko Yu.A. Innovatsionnaya sostavlyayushchaya dostizheniya strategicheskogo konkurentnogo preimushchestva kompanii [An Innovative Component of Achieving Strategic Competitive Advantage of a Company]. Sovremennye problemy upravleniya proektami v investitsionno-stroitel'noy sfere i prirodopol'zovanii: materialy III Mezhdunarodnoy nauchno-prakticheskoy konferentsii (12 aprelya 2013 g.) [Modern Problems of Management of Investment Projects in Construction and Environmental Management: Proceedings of the 3rd International Scientific and Practical Conference (April 12, 2013)]. Edited by V.I. Resin. Moscow, REU im. G.V. Plekhanova Publ., 2013, pp. 7—12. (In Russian)
  3. Sukhachev K.A., Sultanova I.P., Dolzhenko Yu.A. Novye tekhnologii upravleniya kak sredstvo resheniya problem stroitel’stva energeticheskikh ob”ektov [New Management Technologies as Means of Solving the Problems of Energy Facilities Construction]. Neftegazopromyslovyy inzhiniring [Oil and Gas Engineering]. 2013, Special issue no. 7, pp. 62—66. (In Russian)
  4. Batukova L.R. Otsenka urovnya innovatsionnosti investitsionnykh proektov [Innovativeness Level Assessment of Investment Projects]. Regionologiya [Regional Studies]. 2010, no. 3, pp. 59—68. (In Russian)
  5. Chekcheeva N.V., Uvarov A.F., Osipov Yu.M. Metodika ekspertizy innovatsionnykh proektov [Methods of Examination Of Innovative Projects]. Innovatsii [Innovations]. 2006, no. 9, pp. 114—116. (In Russian)
  6. Rot E. Innovatsii — put’ k povysheniyu effektivnosti [Innovations — the Path to Greater Efficiency]. Vestnik McKinsey [Bulletin Of McKinsey]. 2010, no. 21, pp. 37—51. (In Russian)
  7. Vaccaro I.G., Jansen J.P., Van Den Bosch F.A.J., Volberda H.W. Management Innovation and Leadership: The Moderating Role of Organizational Size. Journal of Management Studies. 2012, no. 49 (1), pp. 28—51. DOI: http://dx.doi.org/10.1111/j.1467-6486.2010.00976.x.
  8. Kock A., Gemünden H.G., Salomo S., Schultz S. The Mixed Blessings of Technological Innovativeness for the Commercial Success of New Products. Journal of Product Innovation Management. 2011, no. 28, issue s1, pp. 28—43. DOI: http://dx.doi.org/10.1111/j.1540-5885.2011.00859.x.
  9. Tsai K.H., Fang W., Hsu T.T. Relinking Cross-Functional Collaboration, Knowledge Integration Mechanisms and Product Innovation Performance: A Moderated Mediation Model. Canadian Journal of Administrative Sci. 2012, no. 29, issue 1, pp. 25—39. DOI: http://dx.doi.org/10.1002/cjas.192.
  10. Dereli T., Altun K. A Novel Approach for Assessment of Candidate Technologies with Respect to Their Innovation Potentials: Quick Innovation Intelligence Process. Expert Systems with Applications. 2013, 40 (3), pp. 881—891. DOI: http://dx.doi.org/10.1016/j.eswa.2012.05.044.
  11. Lasagni A. How Can External Relationships Enhance Innovation in SMEs? New Evidence for Europe. Journal of Small Business Management. 2012, no. 50 (2), pp. 310—339. DOI: http://dx.doi.org/10.1111/j.1540-627X.2012.00355.x.
  12. Batukova L.R. Innovatsionnost’, kak vazhneyshaya sotsial’no-ekonomicheskaya kategoriya [Innovation as the Most Important Socio-Economic Category]. Problemy: perspektivy razvitiya innovatsionno-kreativnoy ekonomiki : Sbornik materialov Vtoroy mezhdunarodnoy nauchno-prakticheskoy konferentsii [Collection of Materials of the Second International Scientific-Practical Conference “Innovative and Creative Economy Development Problems and Prospects”]. 2010. Available at: http://econference.ru/blog/conf06/216.html. Date of access: 25.12.2014. (In Russian)
  13. Baklanova Yu.O. Tipologizatsiya, klassifikatsiya i sistematizatsiya innovatsionnykh proektov i initsiativ v kompanii [Classification, Grouping and Systematization of Innovational Projects and Initiatives in a Company]. Sovremennye tekhnologii upravleniya [Modern Management Technologies]. 2012, no. 4 (16). Available at: http://sovman.ru/all-numbers/archive-2012/april2012/item/82-typology-classification-and-systematization-of-innovative-projects-and-initiatives-in-the-company.html. (In Russian)
  14. Baklanova Yu.O. Evolyutsiya podkhoda k proektnomu upravleniyu innovatsiyami: initsiativa, proekt, programma, portfel’ [Evolution of the Approach to Project Management, Innovation, Initiative, Project, Program, Portfolio]. Sovremennye tekhnologii upravleniya [Modern Management Technologies]. 2012, no. 3 (15). Available at: http://sovman.ru/all-numbers/archive-2012/march2012/item/72-03-03-12.html. Date of access: 25.12.2014. (In Russian)
  15. Komkov N.I., Eroshkin S.Yu., Mamontova N.G. «Dorozhnaya karta» — kak instrument tekhnologicheskogo prognozirovaniya i analiza innovatsionnykh proektov [“Road Map” as a Tool of Technological Forecasting and Analysis of Innovative Projects]. Nauchnye trudy: Institut narodnokhozyaystvennogo prognozirovaniya RAN [Scientific Works: the Institute of Economic Forecasting of the Russian Academy of Sciences]. 2008, no. 6, pp. 242—265. (In Russian)
  16. Panchenko V.Ya. RFFI — klyuchevoy element obespecheniya zapuska innovatsionnogo tsikla [RFBR — a Key Element of the Launch of the Innovation Cycle]. Novaya ekonomika. Innovatsionnyy portret Rossii [The New Economy. Innovative Portrait of Russia]. 2013, pp. 62—66. (In Russian)
  17. Sadkov V.G., Mashegov P.N., Zbinyakova E.A. Otsenka urovnya innovatsionnosti ekonomiki i klyuchevye napravleniya formirovaniya tselostnoy mnogourovnevoy natsional’noy innovatsionnoy sistemy [Economy Innovativeness Level Assessment and the Key Areas of Developing a Comprehensive Multi-Level National Innovation System]. Innovatsionnyy Vestnik Region [Innovative Herald Region]. 2006, no 1., pp. 49—53. (In Russian)
  18. Sarkin A.V. Razrabotka sistemy upravleniya innovatsionnoy deyatel’nost’yu na naukoemkikh mashinostroitel’nykh predpriyatiyakh [Development of Innovation Management Systems in Knowledge-Intensive Machine-Building Enterprises]. Ekonomika i finansy [Economics and Finance]. 2010, no. 8, pp. 32—39. (In Russian)
  19. Sarkin A.V. Primenenie sistemy sbalansirovannykh pokazateley v sisteme planirovaniya na naukoemkikh mashinostroitel’nykh predpriyatiyakh [Application of Balanced Scorecard in the Planning System at the High-Tech Machine-Building Enterprises]. Ekonomika i finansy [Economics and Finance]. 2010, no. 7, pp. 14—29. (In Russian)
  20. Chetverik N.P., Khanukhov Kh.M., Pirotskaya L.M., Grunin I.Yu., Shlyapni- kov A.A., Derevyanko A.A. Metodicheskie rekomendatsii po otsenke effektivnosti innovatsiy v stroitel’stve [Guidelines for the Innovation Effectiveness Evaluation in Construction]. Moscow, Komitet innovatsionnykh tekhnologiy v stroitel’stve NOSTROY Publ., 2011, 66 p. (In Russian)

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DESIGN OF STRUCTURAL ELEMENTS IN THE EVENT OF THE PRE-SET RELIABILITY, REGULAR LOAD AND BEARING CAPACITY DISTRIBUTION

Vestnik MGSU 10/2012
  • Tamrazyan Ashot Georgievich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Technical Sciences, Professor, full member, Russian Engineering Academy, head of the directorate, Moscow State University of Civil Engineering (National Research University) (MGSU), 26 Yaroslavskoe Shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 109 - 115

Accurate and adequate description of external influences and of the bearing capacity of the structural material requires the employment of the probability theory methods. In this regard, the characteristic that describes the probability of failure-free operation is required. The characteristic of reliability means that the maximum stress caused by the action of the load will not exceed the bearing capacity.
In this paper, the author presents a solution to the problem of calculation of structures, namely, the identification of reliability of pre-set design parameters, in particular, cross-sectional dimensions. If the load distribution pattern is available, employment of the regularities of distributed functions make it possible to find the pattern of distribution of maximum stresses over the structure.
Similarly, we can proceed to the design of structures of pre-set rigidity, reliability and stability in the case of regular load distribution. We consider the element of design (a monolithic concrete slab), maximum stress which depends linearly on load . Within a pre-set period of time, the probability will not exceed the values according to the Poisson law.
The analysis demonstrates that the variability of the bearing capacity produces a stronger effect on relative sizes of cross sections of a slab than the variability of loads. It is therefore particularly important to reduce the coefficient of variation of the load capacity. One of the methods contemplates the truncation of the bearing capacity distribution by pre-culling the construction material.

DOI: 10.22227/1997-0935.2012.10.109 - 115

References
  1. Lychev A.S. Sposoby vychisleniya veroyatnosti otkaza v kompozitsii raspredeleniy prochnosti i nagruzki [Methods of Calculation of the Probability of Failure within the Framework of the Distribution of Strength and Load]. Trudy mezhdunarodnoy nauchno-tekhnicheskoy konferentsii [Collected works of the international scientific and technical conference]. Samara, 1997, pp. 33—37.
  2. Tichy M. In the Reliability Measure. Struct. Safety. 1988, vol. 5, pp. 227—232.
  3. Araslanov A.S. Raschet elementov konstruktsiy zadannoy nadezhnosti pri sluchaynykh vzaimodeystviyakh [Calculation of Structural Elements with the Pre-set Reliability If Exposed to Random Interactions]. Moscow, 1986, 268 p.
  4. Tamrazyan A.G. Otsenka riska i nadezhnosti nesushchikh konstruktsiy i klyuchevykh elementov — neobkhodimoe uslovie bezopasnosti zdaniy i sooruzheniy [Assessment of Risk and Reliability of Bearing Structures and Key Elements as the Necessary Condition of Safety of Buildings and Structures]. Vestnik TsNIISK [Bulletin of Central Research and Development Institute of Building Structures]. 2009, no. 1, pp. 160—171.
  5. JSO/TK 98 ST 2394. General Principles on Reliability for Structures. 1994, pp. 50.
  6. Rayzer V.D. Teoriya nadezhnosti v stroitel’nom proektirovanii [Theory of Reliability in Structural Design]. Moscow, ASV Publ., 1998, 304 p.

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GREEN TECHNOLOGIES OF LIVING ENVIRONMENT: CONCEPTS, TERMS, STANDARDS

Vestnik MGSU 4/2017 Volume 12
  • Telichenko Valeriy Ivanovich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Technical Sciences, Professor, Honored Worker of Science of the Russian Federation, President, Moscow State University of Civil Engineering (National Research University) (MGSU), 26 Yaroslavskoe shosse, Moscow, Russian Federation, 129337.

Pages 364-372

The article deals with the main principles, concepts, terms that characterize the scientific approach to the formation of a safe and comfortable living environment on the basis of the development and wide application of the sustainable development principles in urban development practice. Definitions of the basic concepts related to the tasks of developing green technologies of the living environment are proposed. The purpose of the study is to select methodological tools for creating a national system of green standardization and certification of urban development objects. This requires technical regulation and standardization; analysis and management of object life cycles; integrated safety, building materials science; energy efficiency and energy saving; development and application of green standards; BIM-technology; rating systems of green certification; construction systems. It is established that the main characteristics that define the “green technologies” concept are energy efficiency, safety, non-wasting, comfort. The factors preventing the achievement of the stated purposes are shown. Positive shifts in this direction and examples of practical implementation of voluntary certification systems for urban development projects have been noted.

DOI: 10.22227/1997-0935.2017.4.364-372

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A model of organization life cycle of a medical building

Vestnik MGSU 12/2018 Volume 13
  • Dorogan Igor A. - Almaz-SP Director for construction, Almaz-SP, 7 Obraztsova st., Moscow, 127025, Russian Federation.

Pages 1474-1481

Introduction. An approach to the development of the organizational-technological model of the life cycle of a medical facility building is presented. Buildings of medical organizations have a number of features in the design, construction and operation. The buildings of nuclear medicine are subject to particularly high requirements of radiation and fire safety. Materials and methods. To organize the design, construction and maintenance of medical buildings, it is advisable to create and develop an organizational and technological model of the medical building life cycle. Such model was created by the author in the form of a business processes sequence. Confirmation of the effectiveness of the model is carried out with the help of multi-criteria expert evaluation. Results. To solve this problem, it is proposed a number of changes in the order of the investment project carrying. A new element is the Preliminary justification of the requirements for the health facility. It should become a mandatory document when obtaining a town-planning plan of the ground area, which is in Russia a de facto permission to design. It is also proposed to prepare technical requirements of three levels. The first level requirements are used for pre-design stage procedures. The requirements of the second level are included in the medical and technical design assignment. The requirements of the third level are applied to the detailed design, as well as to the construction and maintenance of the facility. Requirements are included in the requirement system and must be checked at key stages of the project. At the preliminary project phase, it is also advisable to make a technical and economic calculation with the justification of the main technical solutions and technical and economic indicators. This document should also include a project management plan. New elements are included in organizational and technological models of different stages of the object life cycle. Conclusions. On the basis of the developed model, it is proposed to make adjustments to the normative guideline used in the construction management. For example, it is necessary to make mandatory documents of the pre-design stage. These works have to be paid by investor therefore the standard of design cost has to be increased.

DOI: 10.22227/1997-0935.2018.12.1474-1481

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