INFORMATION SYSTEMS AND LOGISTICS IN CIVIL ENGINEERING

Analysis of cad software designated for analysis of water supply systemsfor the purpose of hydraulic modeling designated for renovation of pipelines

Vestnik MGSU 3/2013
  • Orlov Vladimir Aleksandrovich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Technical Sciences, Professor, Head of the Department of Water Supply and Waste Water Treatment, 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 .
  • Averkeev Il’ya Alekseevich - Moscow State University of Civil Engineering (MGSU) postgraduate student, Department of Water Supply; +7 (499) 183-36-29, 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 237-243

Operation of present-day water supply networks and management of hydraulic models of pipeline networks are labour intensive and ambiguous tasks requiring a sophisticated approach. Operation of water supply networks servicing major Russian cities is accompanied by processing of extensive amounts of information; moreover, some elements of the water supply infrastructure are hidden under the ground. Nowadays operators of water supply networks take advantage of the advanced software used to solve a wide range of tasks associated with data filing, overall evaluation, analysis and optimization of the most important parameters of urban water supply networks. The above software is an essential tool in the management of water networks in major cities. Their ability to collect and process all data on water supply networks and to conduct some research aimed at the improvement of various parameters of the system, including optimization of hydraulic characteristics of the pipeline is employed by researchers and water pipeline operators.The authors analyze and compare CAD software systems designated for water supply networks servicing big cities, capable of resolving multi-component problems and ensuring the reliability of water supply systems.

DOI: 10.22227/1997-0935.2013.3.237-243

References
  1. Abramov N.N. Vodosnabzhenie [Water Supply]. Moscow, Stroyizdat Publ., 1982, 382 p.
  2. Somov M.A., Zhurba M.G. Vodosnabzhenie. T. 1. Sistemy zabora, podachi i raspredeleniya vody [Water Supply. Vol. 1. Systems of Water Intake, Delivery and Distribution]. Moscow, ASV Publ., 2008, 262 p.
  3. Gal’perin E.M. Opredelenie nadezhnosti funktsionirovaniya kol’tsevoy vodoprovodnoy seti [Identification of Reliability of Operation of the Water Supply Ring]. Vodosnabzhenie i sanitarnaya tekhnika [Water Supply and Sanitary Engineering]. 1999, no. 6, pp. 13—16.
  4. Produkty dlya analiza i proektirovaniya infrastruktury vodosnabzheniya i kanalizatsii [Software Products for Analysis and Design of the Water Supply and Sewage Infrastructure]. Available at: www.bentley.com. Date of access: 05.12.12.
  5. MIKE URBAN — Programma gidravlicheskogo rascheta sistem vodosnabzheniya [MIKE URBAN – Hydraulic Design Software for Water Supply Networks]. NKF «Volga». Available at: www.volgaltd.ru. Date of access: 05.12.12.
  6. ZuluHydro — gidravlicheskie raschety vodoprovodnykh setey. Kompaniya «Poli-term» [ZuluHydro – Hydraulic Design of Water Supply Networks. Poli-term Company]. Available at: www.politerm.com. Date of access: 05.12.12.
  7. Govindan Sh., Val’ski T., Kuk D. Resheniya Bentley Systems: gidravlicheskie modeli. Pomogaya prinimat’ luchshie resheniya [Bentley Systems Solutions: Hydraulic Models. Helping Make the Best Decisions]. SAPR i grafika [CAD and Graphics]. 2009, no. 4, pp. 36—38.
  8. Borisov D.A. Bentley Systems — modelirovanie i ekspluatatsiya naruzhnykh setey vodosnabzheniya i kanalizatsii [Bentley Systems – Modeling and Operation of Exterior Water Supply and Sewage Networks]. SAPR i grafika [CAD and Graphics]. 2009, no. 5, pp. 64—68.
  9. Produkty serii MIKE kompanii DHI Water & Environment [MIKE Series Software Developed by DHI Water & Environment]. Available at: www.mikebydhi.com. Date of access: 05.12.12.
  10. Khramenkov S.V. Strategiya modernizatsii vodoprovodnoy seti [Water Supply Pipeline Upgrade Strategy]. Moscow, Stroyizdat Publ., 2005, 398 p.

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Original approach to service life prognostication developed for residential buildings

Vestnik MGSU 3/2013
  • Volkov Andrey Anatol’evich - Moscow State University of Civil Engineering (MGSU) Rector, Doctor of Technical Sciences, Professor, Chair, Department of Information Systems, Technology and Automation in Civil Engineering, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; +7 (499) 929-52-29; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Muminova Svetlana Rashidovna - Moscow State University of Civil Engineering (MGSU) Research Assistant, Scientific and Educational Centre for Information Systems and Intelligent Automatics in Civil Engineering, 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 244-248

A novel integrated mathematical model for devaluation of residential buildings is presented. The devaluation model proposed by the authors is a useful tool employed to predict the residual life span of a building. Availability of information concerning the building behaviour in the course of time makes it possible to influence its properties by means of renovation or restructuring-related actions to resist the aging process. Thisapproach can be regarded as a way to extend the service life span of residential buildings.

DOI: 10.22227/1997-0935.2013.3.244-248

References
  1. Muminova S.R., Pahl P.J. An Integrated Model of Planning Processes for Building Devaluation and Renovation. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2012, no. 10, pp. 297—304. Available at: http://vestnikmgsu.ru/index.php/en/archive. Date of access: 15.11.2012.
  2. Schr?der, Jules: Zustandsbewertung grosser Geb?udebest?nde. Schweizer Ingenieur und Architekt, no. 17, April 1989, pp. 449—459.
  3. Schweizer Bundesamt f?r Konjunkturfragen: Impulsprogramm Bau (IP BAU). Alter-ungsverhalten von Bauteilen und Unterhaltskosten: Grundlagendaten f?r den Unterhalt und die Erneuerung von Wohnbauten. Bern, December 1994, 110 p.
  4. Kirkham R.J., Alisa M., Pimenta da Silva A., Grindley T., Brondsted J. EUROLIFE-FORM: an Integrated Probabilistic Whole Life Cycle Cost and Performance Model for Buildings and Civil Infrastructure. Proceedings of International Construction Research Conference of the Royal Institution of Chartered Surveyors (COBRA 2004), September 2004.
  5. Cole I.S., Corrigan P.A (2009). Development of a Range of Methods for Estimating the Service Life of Buildings and Engineered Structures. In Anderssen R.S., Braddok R.D. and Newham L.T.H., editors. 18th World IMACS Congress and MODSIM09 International Congress on Modeling and Simulation. Modeling and Simulation Society of Australia and New Zealand and International Association for Mathematics and Computers in Simulation. July 2009, pp. 2377—2383.

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INTERACTIVE PLANNING OF RENOVATION WORKS FOR RESIDENTIAL BUILDINGS

Vestnik MGSU 4/2013
  • Volkov Andrey Anatol’evich - Moscow State University of Civil Engineering (MGSU) Rector, Doctor of Technical Sciences, Professor, Chair, Department of Information Systems, Technology and Automation in Civil Engineering, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; +7 (499) 929-52-29; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Muminova Svetlana Rashidovna - Moscow State University of Civil Engineering (MGSU) Research Assistant, Scientific and Educational Centre for Information Systems and Intelligent Automatics in Civil Engineering, 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 209-213

The paper deals with a new approach to renovation planning. The approach is based on the two models: one devaluation model and one renovation model.The proposed devaluation model is used to simulate the deterioration process taking place in a single component, a group of components or the whole building. The devaluation behavior is expressed through the employment of normalized values and the calendar time. Each component of the building has its own significance, so the normalized value of the whole building can be presented as a sum of normalized values of its components. The renovation model depends on the devaluation model as well as conditions and parameters applied by the user. For example, the user can attribute a certain value to a certain component and identify the level of renovation (the restored value).Thus, the two models consolidate into an integrated model. The input information is composed of the data about the physical state of the building, materials and mode of maintenance and operation. The output information represents renovation periodicity and renovation costs needed to maintain the building at the pre-set level.

DOI: 10.22227/1997-0935.2013.4.209-213

References
  1. Kolotilkin B.M. Dolgovechnost’ zhilykh zdaniy [Durability of Residential Buildings]. Moscow, Stroyizdat Publ., 1965, 254 p.
  2. Kyatov N.Kh. Modelirovanie protsessa fizicheskogo iznosa ob”ektov nedvizhimosti [Modeling of the Process of Physical Deterioration of Items of Real Estate]. Nedvizhimost’: ekonomika, upravlenie [Real Estate: Economics, Management]. 2004, no. 7-8, pp. 55—59.
  3. Masters L.W. Prediction of Service Life of Building Materials and Components. Materials and Structures/Materiauxet Constructions. 1986, vol. 19, no. 114, pp. 417—422.
  4. Volkov A.A., Muminova S.R. Original Approach to Service Life Prognostication Developed for Residential Buildings. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2013, no. 3, pp. 244—248.
  5. Muminova S.R., Pahl P.J. An Integrated Model of Planning Process for Building Devaluation and Renovation. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2012, no. 10, pp. 297—304.

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USING LOGISTICS-BASED APPROACH TO IMPROVE THE MARKET OF RECYCLED CONSTRUCTION PRODUCTS

Vestnik MGSU 5/2013
  • Aleksanin Aleksandr Vyacheslavovich - Moscow State University of Civil Engineering (MGSU) postgraduate student, Department of Technology, Organization and Management of Construction Processes, 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 .
  • Sborshchikov Sergey Borisovich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Economic Sciences, Professor, acting chair, Department of Technology, Organization and Management in the Construction, 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 193-199

The process of manufacturing of various construction products is accompanied by the generation of huge amounts of versatile wastes. Application of construction waste in further production processes is possible in the aftermath of its pre-processing or even without it. Construction waste recycling can generate high revenues. The pattern of waste generation and further logistic flows of waste generated in the process of construction and demolition are presented in article. The analysis of the market of secondary, or recycled, construction products has revealed weaknesses of its operation. The proper choice of effective technologies for the treatment of building waste may turn into the basis for successful economic development of the construction industry in the Russian regions. The backwardness of the market of secondary resources misbalances supply and demand for market products. In this article, the pattern for development of logistics-based models of intensive development of the market of secondary construction resources is proposed. Application of this logistics-based approach will generate economic benefits and prevent environmental pollution.

DOI: 10.22227/1997-0935.2013.5.193-199

References
  1. Kalinina E.V. Obosnovanie vozmozhnosti vypuska stroitel’nykh materialov na osnove otkhodov proizvodstva kal’tsinirovannoy sody [Substantiation of Production of Construction Materials from Soda Ash Waste Products]. Stroitel’nye materialy [Construction Products]. 2012, no. 9, pp. 64—67.
  2. Gubanov D.A. Stroitel’nye kompozity na osnove otkhodov proizvodstva metallopolimernykh vodoprovodnykh trub [Construction Composites Made of Waste Products Generated in the Process of Production of Metal-polymeric Water Pipes]. Regional’naya arkhitektura i stroitel’stvo [Regional Architecture and Construction]. 2012, no. 2, pp. 60—63.
  3. Gumba Kh.M., Papel’nyuk O.V. Otsenka effektivnosti primeneniya novogo stroitel’nogo materiala [Assessment of Efficiency of Application of a New Building Material]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2012, no. 3, pp. 176—181.
  4. Aleksanin A.V., Sborshchikov S.B. Logisticheskie printsipy upravleniya otkhodami stroitel’nogo proizvodstva [Principles of Logistics in Construction Waste Management]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2013, no. 2, pp. 197—203.
  5. Aleksanin A.V., Sborshchikov S.B. Povyshenie konkurentosposobnosti predpriyatiy stroitel’noy otrasli za schet integratsii 3 R-kontseptsii upravleniya otkhodami stroitel’nogo proizvodstva i logisticheskikh metodov [Improvement of the Competitive Strength of Construction Enterprises Using the 3R Concept of Management of Construction Waste and Methods of Logistics]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2011, no. 8, pp. 419—422.
  6. Asokan Pappua, Mohini Saxenaa, Shyam R. Asolekarb. Solid Wastes Generation in India and Their Recycling Potential in Building Materials. Building and Environment. 2007, vol. 42, no. 6, pp. 2311—2320.
  7. Dong Qing Zhang, Soon Keat Tan, Richard M. Gersberg. Municipal Solid Waste Management in China: Status, Problems and Challenges. Journal of Environmental Management. 2010, vol. 91, no. 8, pp. 1623—1633.
  8. Siti Nadzirah Othman, Zainura Zainon Noor, Ahmad Halilu Abba, Rafiu O. Yusuf, Mohd. Ariffin Abu Hassan. Review on Life Cycle Assessment of Integrated Solid Waste Management in Some Asian Countries. Journal of Cleaner Production. 2013, vol. 41, pp. 251—262.
  9. Efimenko A.Z. Stroitel’nye otkhody ot snosa zdaniy — syr’e dlya malootkhodnykh tekhnologiy [Building Demolition Waste as the Raw Material for Low-waste Technologies]. Stroitel’nye materialy [Construction Materials]. 2010, no. 12, pp. 73—75.
  10. Kostoglodov D.D. Marketing i logistika firmy [Corporate Marketing and Logistics]. Moscow, PRIOR Publ., 2000, 126 p.

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COMPARISON OF DEVELOPMENT METHODOLOGIES FOR SYSTEMS OF INTELLECTUAL INTERACTION

Vestnik MGSU 5/2013
  • Alfimtsev Aleksandr Nikolaevich - Moscow State Technical University named after N.E. Bauman (МSTU) Candidate of Technical Sciences, Associate Professor, Department of Information Systems and Telecommunications; +7 (499) 267-65-37, Moscow State Technical University named after N.E. Bauman (МSTU), 5 2nd Baumanskaya st., Moscow, 105005, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Loktev Daniil Alekseevich - Bauman Moscow State Technical University (BMSTU) postgraduate student, Department of Information Systems and Telecommunications, Bauman Moscow State Technical University (BMSTU), 5 2-ya Baumanskaya str., Moscow, 105005, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Loktev Aleksey Alekseevich - Moscow State University of Civil Engineering (МGSU) +7 (499) 183-24-01, Moscow State University of Civil Engineering (МGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 200-208

Development of systems for intellectual interaction in general and intelligent multimodal interfaces in particular involves employment of specific methodologies for development of an specific architecture composed of a converter of perceptions and situations, modifiers of models of user’s behaviour and the environment, recognizer of situations, as well as units responsible for storage of formal models of the user behaviour, environment and represented perceptions. In this case, various development methodologies may be employed, including Gaia, Mase, UML, IDEF8, based on samples, graph theory and components. In the course of the comparative analysis of the above methodologies, special requirements are applicable to the above methodologies are identified and basic strengths and weaknesses of existing methodologies are considered.

DOI: 10.22227/1997-0935.2013.5.200-208

References
  1. Harper R. et al. Being Human: Human-computer Interaction in the Year 2020. Cambridge, Microsoft Research Ltd, 2008, pp. 32—51.
  2. Devyatkov V.V., Alfimtsev A.N. Nechetkaya konechno-avtomatnaya model’ intellektual’nogo mul’timodal’nogo interfeysa [Fuzzy Finite Automaton Model of an Intelligent Multimodal Interface]. Problemy upravleniya [Management Problems]. 2011, no. 2, pp. 69—77.
  3. Wooldridge M.J., Jennings N.R., Kinny D. The Gaia Methodology for Agentoriented Analysis and Design. Autonomous Agents and Multi-Agent Systems. 2000, no. 3, pp. 285—312.
  4. Kendall E.A. Software Engineering with Role Modeling. Proc. of the Agent-oriented Software Engineering. Berlin, Springer-Verlag, 2000, vol. 1957, pp. 163—169.
  5. Chaib-draa B. Connection between Micro and Macro Aspects of Agent Modeling. Proc. of the First International Conference on Autonomous Agents. NY, 1996, pp. 262—267.
  6. DeLoach S.A. Multiagent Systems Engineering: A Methodology and Language for Designing Agent Systems. Proc. of Agent Oriented Information Systems. 1999, pp. 45—57.
  7. Wood M.W., DeLoach S.A. An Overview of the Multiagent Systems Engineering Methodology. Proc. of the First International Workshop on Agent-Oriented Software Engineering. 2000, pp. 207—221.
  8. Zambonelli F. et al. Coordination of Internet Agents: Models, Technologies and Applications. Berlin, Springer-Verlag, 2001, 524 p.
  9. Odell J., Parunak H.V., Bauer B. Representing agent interaction protocols in UML // Proc. of Agent-Oriented Software Engineering. Berlin, Springer-Verlag, 2000, vol. 1957, pp. 121—140.
  10. Bergenti F., Poggi A. Supporting Agent-oriented Modeling with UML. International Journal Software Engineering and Knowledge Engineering. 2002, no. 6, pp. 605—618.
  11. Steimann F., Vollmer H. Exploiting Practical Limitations of UML Diagrams for Model Validation and Execution. Journal on Software & Systems Modeling. 2006, no. 1, pp. 26—47.
  12. Peng P.W. et al. Graph-based Methods for the Analysis of Large-scale Multiagent Systems. Proc. of the 8th International Conference on Autonomous Agents and Multiagent Systems. Richland, 2009, pp. 545—552.
  13. Depke R., Heckel R. Formalizing the Development of Agent-Based Systems Using Graph Processes. Proc. of the ICALP’2000 Satellite Workshops on Graph Transformation and Visual Modeling Techniques. 2000, pp. 419—426.
  14. Aridor Y., Lange D.B. Agent Design Patterns: Elements of Agent Application Design. Proc. of the Second International Conference on Autonomous Agents. 1997, pp. 108—115.
  15. Rana O.F., Biancheri C. A Petri Net Model of the Meeting Design Pattern for Mobile-Stationary Agent Interaction. Proc. of the 32nd Hawaii International Conference on System Sciences. 1999, vol. 8, p. 8058.
  16. Sauvage S. Design Patterns for Multiagent System Design. Proc. of 3rd Mexican Int. Conf. on Artificial Intelligence. Mexico City, 2004, pp. 352—361.
  17. Brazier F., Jonker C., Treur J. Principles of Component-Based Design of Intelligent Agents. Data and Knowledge Engineering. 2002, no. 41, pp. 1—27.
  18. Lian J., Shatz S., He X. Component Based Multi-Agent System Modeling and Analysis: a Case Study. Proc. of the International Conference on Software Engineering Research and Practice. Las Vegas, 2007, pp. 183—189.
  19. Erol K., Lang J., Levy R. Designing Agents from Reusable Components. Proc. of the Fourth International Conference on Autonomous Agents. 2000, pp. 76—77.
  20. Charles M.S. Fifth Generation Management: Co-creating Through Virtual Enterprising, Dynamic Teaming, and Knowledge Networking. Boston, Butterworth-Heinemann, 1996, p. 184.
  21. Mayer R.J. et al. Information Integration for Concurrent Engineering Compendium of Methods Report. Ohio, Wright-Patterson Air Force Base, 1995, p. 108.

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METHODOLOGY OF EFFICIENCY EVALUATION APPLICABLE TO DISTRIBUTED INTELLIGENT POWER MANAGEMENT SYSTEMS WITHIN A NETWORKOF FACILITIES IN THE CONTEXT OF ARBITRARY LIMITATION OF RESOURCES

Vestnik MGSU 5/2013
  • Volkov Andrey Anatol’evich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Technical Sciences, Professor, Rector, Moscow State University of Civil Engineering (National Research University) (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation.
  • Chelyshkov Pavel Dmitrievich - Moscow State University of Civil Engineering (MGSU) Junior Researcher, Research and Educational Cen- tre for Information Systems and Intelligent Automation in Civil Engineering, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe Shosse, 129337, Moscow, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Sedov Artem Vladimirovich - Moscow State University of Civil Engineering (MGSU) Director of Research Laboratory, Scientific and Educational Center for Information Systems and Intelligent Automatics in Construction, 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 209-213

In this article, the authors present their original algorithm for the methodology of the efficiency assessment of distributed intelligent power management systems of construction facilities in the context of arbitrary limitation of resources.The method is designated for the analysis of implemented design solutions, and it applies to the systems engineering, classification and management of processes, let alone the evaluation of the efficiency of implemented designs.At first, the engineering systems are identified and described. Then, the processes are split into processes that accompany changes in the the parameters of a building and the management processes that accompany changes in the parameters of a building. For each process, the percentage of the total energy consumption is calculated.The coefficient of intelligence and building automation is based on the percentage of the total energy consumption. Further, the coefficient of efficiency of the implemented management system is identified. Therefore, the method helps to assess the effectiveness of a distributed intelligent power management system, and it may also be employed to minimize the impact of biased factors, such as peer reviews.

DOI: 10.22227/1997-0935.2013.5.209-213

References
  1. Il’ichev V.A. Printsipy preobrazovaniya goroda v biosferosovmestimyy i razvivayushchiy cheloveka [Principles of Transformation of a City into the One Compatible with the Biosphere and Capable of Developing the Man]. Promyshlennoe i grazhdanskoe stroitel’stvo [Industrial and Civil Construction]. 2010, no. 6, pp. 3—13.
  2. Il’ichev V.A. Biosfernaya sovmestimost’: Tekhnologii vnedreniya innovatsiy. Goroda, razvivayushchie cheloveka. [Compatibility with the Biosphere, Technology for Introduction of Innovations. Cities That Are Capable of Developing the Man]. Moscow, Librokom Publ., 2011, 240 p.
  3. Volkov A.A. Intellekt zdaniy: formula [Intelligence of Buildings: the Formula]. Promyshlennoe i grazhdanskoe stroitel’stvo [Industrial and Civil Construction]. 2012, no. 3, pp. 54—57.
  4. Ashby W.R. An Introduction to Cybernetics. London, Chapman & Hall Ltd., 1957, 295 p.
  5. Ashby W.R. Design for a Brain. New York, John Wiley & Sons Inc., London, Chapman & Hall Ltd., 1960, 286 p.
  6. Gusakov A.A., editor. Sistemotekhnika [Systems Engineering]. Moscow, Fond «Novoe tysyacheletie» publ., 2002, 768 p.
  7. Wiener N. Cybernetics or Control and Communication in the Animal and the Machine. The MIT Press, Cambridge, Massachusetts, 1965, 212 p.

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MATHEMATICAL AND INFORMATION SUPPORT OF HYDRAULIC EXPERIMENTS AT PIPELINES

Vestnik MGSU 5/2013
  • Orlov Vladimir Aleksandrovich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Technical Sciences, Professor, Head of the Department of Water Supply and Waste Water Treatment, 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 .
  • Zotkin Sergey Petrovich - Moscow State University of Civil Engineering (MGSU) Candidate of Technical Sciences, Professor, Department of Informatics and Applied Mathematics; +7 (495) 953-36-35, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation.
  • Koblova Elena Viktorovna - Moscow State University of Civil Engineering (MGSU) postgraduate student; Department of Water Supply; 7 (495) 516-96-88., Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation.

Pages 214-219

The article contains summarized results of the research into developed software programme capable of processing findings of hydraulic experiments held at pressure pipelines (protective coatings). The authors describe the algorithm of the analysis procedure, sequential analysis, mathematical and hydro-mechanical modeling of the process of transformation of hydraulic values. The authors provide their concept of the dialog box and description of input and output information, as well as functions of the software programme at intermediate stages of the hydraulic analysis. Basic input information supplied into the hydraulic analysis software programme includes the pipeline, its inner diameter, length, and acceptable roughness error.Whenever a user presses the “display result” button, interim information is displayed on the screen and, if necessary, a set of output information is provided in the form of tables and graphs. The choice for the optimal solution is made on the basis of the minimum margin of error between experimental and analytical values of the pipe roughness.The findings may be useful to researchers involved in the study of hydraulic characteristics of pipelines made of various materials and to designers and builders engaged in renovation of sections of pipelines.

DOI: 10.22227/1997-0935.2013.5.214-219

References
  1. Khramenkov S.V. Strategiya modernizatsii vodoprovodnoy seti [Strategy for Modernization of a Water Supply Network]. Moscow, Stroyizdat Publ., 2005, 398 p.
  2. Orlov V.A., Orlov E.V., Pimenov A.V. Podkhody k vyboru ob”ekta renovatsii na truboprovodnoy seti, vosstanavlivaemoy polimernym rukavom [Approaches to the Choice of the Renovated Section of a Pipeline Restored by a Polymeric Sleeve]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2010, no. 3, pp. 129—131.
  3. Zotkin S.P., Orlov V.A., Orlov E.V., Maleeva A.V. Algoritm i avtomatizirovannaya programma optimizatsii vybora metoda bestransheynogo vosstanovleniya napornykh i beznapornykh truboprovodov [Algorithm and Software Programme for Optimization of Choice for the Method of Trenchless Renovation of Pressure and Free-flow Pipelines]. Nauchnoe obozrenie [Scientific Review]. 2011, no. 4, pp. 61—65.
  4. Khurgin R.E., Orlov V.A., Zotkin S.P., Maleeva A.V. Metodika i avtomatizirovannaya programma opredeleniya koeffitsienta Shezi «S» i otnositel’noy sherokhovatosti «n» dlya beznapornykh truboprovodov [Methodology and Software Programme for Identification of Chezy Factor and Relative Roughness for Free-flow Pipelines]. Nauchnoe obozrenie [Scientific Review]. 2011, no. 4, pp. 54—60.
  5. Orlov V.A., Maleeva A.V. Vodootvodyashchie truboprovodnye seti. Vybor ob”ekta renovatsii na baze ranzhirovaniya destabiliziruyushchikh faktorov [Water Discharge Pipeline Networks. Choice of an Item to Be Renovated on the Basis of the Ranking of Destabilizing Factors]. Tekhnologii Mira [World Technologies]. 2011, no. 1, pp. 31—34.
  6. Kiselev P.G. Spravochnik po gidravlicheskim raschetam [Reference Book of Hydraulic Analysis]. Moscow, Energiya Publ., 1972, 312 p.
  7. Al’tshul’ A.D., Zhivotovskiy L.S., Ivanov L.P. Gidravlika i aerodinamika [Hydraulics and Aerodynamics]. Moscow, Stroyizdat Publ., 1987, 414 p.
  8. Shevelev F.A., Shevelev A.F. Tablitsy dlya gidravlicheskogo rascheta vodoprovodnykh trub. [Tables for Hydraulic Analysis of Water Supply Pipelines]. Moscow, Stroyizdat Publ., 1984, 117 p.
  9. Al’tshul’ A.D. Gidravlicheskie soprotivleniya [Hydraulic Resistances]. Moscow, Nedra Publ., 1970, 216 p.
  10. Prozorov I.V., Nikoladze G.I., Minaev A.V. Gidravlika, vodosnabzhenie i kanalizatsiya gorodov. [Hydraulics, Water Supply and Urban Sewage]. Moscow, Vyssh. shk. publ., 1975, 422 p.

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METHODOLOGY FOR CONSTRUCTION OF DISTRIBUTED INTELLIGENT POWER MANAGEMENT SYSTEMS APPLICABLE TO A NETWORK OF BUILDING FACILITIES IN THE CONTEXT OF ARBITRARY LIMITATION OF RESOURCES

Vestnik MGSU 5/2013
  • Volkov Andrey Anatol’evich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Technical Sciences, Professor, Rector, Moscow State University of Civil Engineering (National Research University) (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation.
  • Chelyshkov Pavel Dmitrievich - Moscow State University of Civil Engineering (MGSU) Director of Research Laboratory, Scientific and Educational Center for Information Systems and Intelligent Automatics in Construction, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation.
  • Sedov Artem Vladimirovich - Moscow State University of Civil Engineering (MGSU) Director of Research Laboratory, Scientific and Educational Center for Information Systems and Intelligent Automatics in Construction, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation.

Pages 220-225

In this article, the algorithm underlying the methodology for construction of distributed intelligent power management systems applicable to construction facilities in the context of arbitrary limitation of resources is considered by the authors. The methodology consist of a sequence of operations, including the analysis of design solutions in terms of the systems engineering, identification of their energy consumption rate, assessment of the feasibility of actions aimed at the automation or organization of an intelligent management system.The authors consider the algorithm of the calculation of specific energy consumption rate of each engineering system, as well as the calculation of acceptable process losses (based on the regional standards).After that, the most power-intensive engineering systems are identified. First, conversion of true values of measurement of energy consumption in tons of oil equivalent must be performed to assure the unbiased evaluation of the power consumption rate of engineering systems, irrespectively of the energy nature. Thereafter, the power consumption rate of management systems is calculated, and their degree of automation is assessed from the viewpoint of its technical and financial efficiency. The final step consists in the preparation of design specifications and estimates.

DOI: 10.22227/1997-0935.2013.5.220-225

References
  1. Il’ichev V.A. Printsipy preobrazovaniya goroda v biosferosovmestimyy i razvivayushchiy cheloveka [Principles of Transformation of a City into the One Compatible with the Biosphere and Capable of Developing the Man]. Promyshlennoe i grazhdanskoe stroitel’stvo [Industrial and Civil Construction]. 2010, no. 6, pp. 3—13.
  2. Il’ichev V.A. Biosfernaya sovmestimost’: Tekhnologii vnedreniya innovatsiy. Goroda, razvivayushchie cheloveka. [Compatibility with the Biosphere, Technology for Introduction of Innovations. Cities That Are Capable of Developing the Man]. Moscow, Librokom Publ., 2011, 240 p.
  3. Volkov A.A. Intellekt zdaniy: formula [Intelligence of Buildings: the Formula]. Promyshlennoe i grazhdanskoe stroitel’stvo [Industrial and Civil Construction]. 2012, no. 3, pp. 54—57.
  4. Ashby W.R. An Introduction to Cybernetics. London, Chapman & Hall Ltd., 1957, 295 p.
  5. Ashby W.R. Design for a Brain. New York, John Wiley & Sons Inc., London, Chapman & Hall Ltd., 1960, 286 p.
  6. Wiener N. Cybernetics or Control and Communication in the Animal and the Machine. The MIT Press, Cambridge, Massachusetts, 1965, 212 p.
  7. Gusakov A.A., editor. Sistemotekhnika [Systems Engineering]. Moscow, Fond «Novoe tysyacheletie» publ., 2002, 768 p.

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DEVELOPMENT OF A REGION-WIDE MECHANISM FOR CENTRALIZED MANAGEMENTOF CONSTRUCTION WASTE

Vestnik MGSU 6/2013
  • Aleksanin Aleksandr Vyacheslavovich - Moscow State University of Civil Engineering (MGSU) postgraduate student, Department of Technology, Organization and Management of Construction Processes, 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 .
  • Sborshchikov Sergey Borisovich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Economic Sciences, Professor, acting chair, Department of Technology, Organization and Management in the Construction, 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 229-235

Today no effective centralized control system is available for building waste. However, it may be generated through the establishment of special-purpose logistics centers. Logistics centers will be designated for the regulation of processes of building waste handling. Depending on the status of development of building waste control systems in specific regions, logistics centers of one of the following two types are to be installed: multi-component logistics centers or information logistics centers. The objective is to develop a mechanism for generation and transfer of information streams in order to compile an effective model of waste management for construction and demolition works. The mechanism is to involve each participant of waste-related processes. If this mechanism is in place, waste transportation and amount/composition analysis will be streamlined to assure timely information delivery to/from construction organizations, transport companies, waste processing enterprises, and consumers of secondary products. In the article, the mechanism of effective region-wide management of construction waste is proposed depending on the status of development of waste processing facilities in different areas (regions, etc.). Patterns of interaction between the parties involved in this process are also analyzed.

DOI: 10.22227/1997-0935.2013.6.229-235

References
  1. Yudin A.G. Smena paradigmy — ot upravleniya otkhodami k upravleniyu resursami [Paradigm Replacement: from Waste Management to Resources Management]. Ekologiya i promyshlennost’ Rossii [Ecology and Industry of Russia]. 2010, no. 3, pp. 30—32.
  2. Kostarev S.N. Razrabotka parametricheskoy modeli upravleniya poligonom tverdykh bytovykh otkhodov [Development of a Parametric Model for Solid Household Waste Landfill Management]. Sovremennye problemy nauki i obrazovaniya [Contemporary Problems of Science and Education]. 2013, no.1, pp. 188—196.
  3. Ulanova Z.A. Sistema obrashcheniya s tverdymi bytovymi otkhodami na rossiyskom severe [System of Solid Household Waste Treatment in the North of Russia]. Natsional’nye interesy: prioritety i bezopasnost’. [National Concerns: Priorities and Safety]. 2012, no. 47, pp. 62—65.
  4. Il’inykh G.V., Slyusar’ N.N., Korotaev V.N., Vaysman Ya.I., Samutin N.M. Issledovaniya sostava tverdykh bytovykh otkhodov i otsenka ikh sanitarno-epidemiologicheskoy opasnosti [Studies of the Composition of Solid Household Waste and Assessment of Its Sanitary and Epidemiological Harmfulness]. Gigiena i sanitariya [Hygiene and Sanitation]. 2013, no. 1, pp. 53—55.
  5. Aleksanin A.V., Sborshchikov S.B. Upravlenie stroitel’nymi otkhodami na osnove sozdaniya spetsializirovannykh logisticheskikh tsentrov [Construction Waste Management through Development of Specialized Logistics Centers]. Promyshlennoe i grazhdanskoe stroitel’stvo [Industrial and Civil Construction]. 2013, no. 2, pp. 66—68.
  6. Aleksanin A.V., Sborshchikov S.B. Povyshenie effektivnosti upravleniya otkhodami stroitel’nogo proizvodstva na osnove razvitiya informatizatsii i normativnoy bazy [Improvement of Efficiency of Management of Construction Waste through Development of Information Systems and the Regulatory Framework]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2013, no. 1, pp. 148—155.
  7. Rukovodstvo k Svodu znaniy po upravleniyu proektami [Guidebook for Collection of Project Management Information]. PMI Publ., 2008, 241 p.
  8. Dablanca L., Ross C. Atlanta: a Mega Logistics Center in the Piedmont Atlantic Megaregion (PAM). Journal of Transport Geography. 2012, vol. 24, pp. 432—442.
  9. Kayikci Y. A Conceptual Model for Intermodal Freight Logistics Centre Location Decisions. Procedia - Social and Behavioral Sciences. 2010, vol. 2, no. 3, pp. 6297—6311.
  10. Eckhardta J., Rantala J. The Role of Intelligent Logistics Centres in a Multimodal and Cost-effective Transport System. Procedia - Social and Behavioral Sciences. 2012, vol. 48, pp. 612—621.

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Comprehensive analysis of the aerated concrete technology

Vestnik MGSU 7/2013
  • Zhukov Aleksey Dmitrievich - Moscow State University of Civil Engineering (National Research University) (MGSU) Candidate of Technical Sciences, Associate Professor, Department of Composite Materials Technology and Applied Chemistry, 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 .
  • Chugunkov Aleksandr Viktorovich - Moscow State University of Civil Engineering (MGSU) Director, Department of Examination of Buildings, postgraduate student, Department of Technology of Finishing and Insulation Materials, 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 .
  • Khimich Anastasiya Olegovna - Moscow State University of Civil Engineering (MGSU) student, Institute of Construction and Architecture, 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 .
  • Eremenko Nikita Andreevich - Moscow State University of Civil Engineering (MGSU) student, Institute of Economics, Management and Information Systems 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 .
  • Kopylov Nikita Andreevic - Moscow State University of Civil Engineering (MGSU) student, Institute of Economics, Management and Information Systems 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 167-175

The software package developed by Department of Technology of Finishing and Insulation Materials of Moscow State University of Civil Engineering is designated to improve the performance efficiency of experiments that consist in planning, implementation, and processing of findings of research projects, including solutions for their optimization. The software package assists researchers in planning and analyzing experimental findings that are influenced by versatile factors, especially if their number is different. The number of factors of impact may be set at 15, 30, 45, and 60. This software was tested in the context of the aerated concrete technology. The first stage of the research consists in the preparation for an experiment with account for all factors characterizing the manufacturing process. The software assesses the relevance of the above factors and ranks them on the basis of their significance. As a result, three groups of factors are identified: factors of major significance (Group A), factors of secondary significance (Group B) and other factors.The software package was applied in the context of the aerated concrete technology to determine the most important parameters of its production. As a result of the experiment, the group of most significant factors (group A) included foaming agent efficiency, foaming agent consumption rate, and mould filling degree, while less important factors (Group B) included modifier consumption rate, mixture temperature, exposure time and water consumption rate.

DOI: 10.22227/1997-0935.2013.7.167-175

References
  1. Dolotova R.G., Vereshchagin V.I., Smirenska V.N. Opredelenie sostavov yacheistykh betonov razlichnoy plotnosti pri ispol’zovanii polevoshpatovo-kvartsevykh peskov metodom matematicheskogo planirovaniya [Using Method of Mathematical Planning to Identify Compositions of Cellular Concretes Having Different Density Values and Containing Feldspar Sands]. Stroitel’nye materialy [Construction Materials]. 2012, no. 12, pp. 16—19.
  2. Zhukov A.D., Chugunkov A.V. Lokal’naya analiticheskaya optimizatsiya tekhnologicheskikh protsessov [Local Analytical Optimization of Manufacturing Processes]. Vestnik MGSU Proceedings of Moscow State University of Civil Engineering]. 2011, no. 1, pp. 273—279.
  3. Zhukov A.D., Chugunkov A.V., Gudkov P.K. Sistema fasadnoy izolyatsii na osnove betonov yacheistoy struktury [Fa?ade Insulation System Based on Cellular Structure Concretes]. Utility Model Patent no. 121834 of 06.07.2012, 6 p.
  4. Zhukov A.D., Chugunkov A.V., Rudnitskaya V.A. Zakonomernosti formirovaniya struktury materiala v usloviyakh variotropii davleniy [Regularities of Material Structure Formation under Variotropic Pressure Conditions]. Internet-Vestnik VolgGASU. 2012, no. 3. Available at: http://vestnik.vgasu.ru. Date of access: 05.02.2013.
  5. Loskutov A.B., Gossen Ya.Ya., Gorbacheva O.Yu. Sovershenstvovanie tekhnologii proizvodstva silikatnykh blokov na ZAO «Kombinat stroitel’nykh materialov» [Improvement of Production Technology of Silicate Blocks by “Kombinat stroitel›nykh materialov” closed Joint Stock Company]. Stroitel’nye materialy [Construction Materials]. 2013, no. 5, pp. 52—54.
  6. Sakharov G.P., Strebitskiy V.P., Voronin V.A. Novaya effektivnaya tekhnologiya neavtoklavnogo porobetona [New Effective Technology for Non-autoclaved Cellular Concrete]. Stroitel’nye materialy, obrudovanie i tekhnologii XXI veka [Construction Materials, Equipment and Technologies of the 21st Century]. 2002, no. 6, pp. 28—29.
  7. Perekhozhentsev A.G. Modelirovanie temperaturno-vlazhnostnykh protsessov v poristykh stroitel’nykh materialakh [Modeling of Temperature and Moisture Processes in Porous Construction Materials]. Part 6. Energeticheskiy potentsial vlazhnosti kapillyarno-poristykh materialov [Energy Potential of the Moisture Content of Capillary-porous Materials]. Stroitel’nye materialy [Construction Materials]. 2013, no. 5, pp. 90—91.
  8. Shmelev S.E. Puti vybora optimal’nogo nabora energosberegayushchikh meropriyatiy [Choice of the Optimal Set of Power-saving Actions]. Stroitel’nye materialy [Construction Materials]. 2013, no. 3, pp. 7—9.
  9. Verarbeitungsanleitung. Xella-Daemmsysteme GmbH, 2007, 47 p.
  10. Ytong Multipor Mineraldaemmplatte. Xella-Daemmsysteme GmbH, 2012, 24 p.
  11. Waermedamm-Verbundsystem. Xella GmbH, 2009, 53 p.

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Using WUFI®plus software to simulate energy arameters of buildings

Vestnik MGSU 7/2013
  • Usmonov Shukhrat Zaurovich - Khujand Politechnic Institute of Tajik Technical University by academic M. Osimi (PITTU); Moscow State University of Civil Engineering (MGSU) Senior Lecturer, Khujand Politechnic Institute of Tajik Technical University by academic M. Osimi (PITTU); Moscow State University of Civil Engineering (MGSU), 226 Lenina st., Khujand, 735700, Tajikistan; applicant, Department of Architecture of Civil and Industrial Buildings; 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 176-180

The author explores the main principles of modeling the energy performance of residential buildings using WUFI®plus software. The author also assesses and analyzes images generated using WUFI+ software within the framework of the simulation of energy parameters of residential buildings. The article also has an experimental analysis of expensive and time-consuming factors that can be avoided thanks to the WUFI®plus software which allows for (1) easy and quick changes in the structure and its design, (2) input of different boundary conditions as well as (3) various values of parameters like material characteristics.

DOI: 10.22227/1997-0935.2013.7.176-180

References
  1. Fundamentals of WUFI®plus. Simultaneous Calculation of Transient Hygrothermal Conditions of Indoor Spaces and Building Envelopes. Holzkirchen, Fraunhofer-lnstitut f?r Bauphysik, 2008, 68 p.
  2. WUFI®plus: general information (October 10, 2010). Retrieved: February 19, 2011, from WUFI-Wiki.
  3. Building Energy Software Tools Directory. Available at: http://apps1.eere.energy.gov. Date of access: 15.06.13.

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MATHEMATICAL SIMULATION OF MASS TRANSFER IN THE VERTICAL SETTLER

Vestnik MGSU 8/2013
  • Belyaev Nikolay Nikolaevich - Prydneprovsk State Academy of Civil Engineering and Architecture (PSACEA) Doctor of Technical Sciences, Associate Professor, Department of Hydraulics, Prydneprovsk State Academy of Civil Engineering and Architecture (PSACEA), 24a Chernyshevskiy St., Dnepropetrovsk, 49600, Ukraine; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Nagornaya Elena Konstantinovna - Prydneprovsk State Academy of Civil Engineering and Architecture (PSACEA) assistant lecturer, Department of Hydraulics, Prydneprovsk State Academy of Civil Engineering and Architecture (PSACEA), 24a Chernyshevskiy St., Dnepropetrovsk, 49600, Ukraine; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 150-157

Mathematical models of secondary settlers have been intensively developed in the past several years. The challenge is to develop CFD models capable of taking account of the geometrical shape of the settler, the most important physical processes, and to perform calculations in the timely manner. The task of the authors was to develop a 2D numerical model designated for the research into the transfer of waste waters inside vertical settlers, for the model to take account of the geometrical shape and structural features of the settler. The authors employed finite difference schemes as the basic methods of research. As a result, a new 2D CFD model was developed. The novel model may be used to perform CFD studies of vertical settlers. This model takes account of the geometrical shape of the settler, the central pipe inside it, and other peculiarities. The CFD model and code developed by the authors constitute a solution to multi-parametric problems of the vertical settler design. Computer time taken by this model is equal to the one of a 1D model.

DOI: 10.22227/1997-0935.2013.8.150-157

References
  1. Davydov E.I., Lyamaev B.F. Issledovanie i raschet vertikal'nogo otstoynika so spiral'no-navitoy nasadkoy [Research into and Analysis of a Vertical Settler Having a Spiral-wound Nozzle]. Inzhenerno-stroitel’nyy zhurnal [Journal of Civil Engineering]. Ìoscow, 2011, no. 5, pp. 10—15.
  2. Tavartkiladze I.M., Kravchuk A.M., Nechipor O.M. Matematicheskaya model' rascheta vertikal'nykh otstoynikov s peregorodkoy [Mathematical Model for the Analysis of Vertical Tanks Having Dividers]. Vodosnabzhenie i sanitarnaya tekhnika [Water Supply and Sanitary Engineering]. 2006, no. 1, Part 2, pp. 39—42.
  3. B?rger R., Diehl S., Nopens I. A Consistent Modeling Methodology for Secondary Settling Tanks in Wastewater Treatment. Water Research. 2011, no. 45(6), pp. 2247—2260.
  4. Oleynik Ya.A., Kalugin Yu.I., Stepovaya N.G., Zyablikov S.M. Teoreticheskiy analiz protsessov osazhdeniya v sistemakh biologicheskoy ochistki stochnykh vod [Theoretical Analysis of Sedimentation Processes in Biological Wastewater Treatment]. Prikladna g³dromekhan³ka [Applied Hydromechanics]. 2004, vol. 6 (78), no. 4, pp. 62—67.
  5. Holenda B. Development of Modeling, Control and Optimization Tools for the Activated Sludge Process. Doctorate School of Chemical Engineering, University of Pannonia, 2007, 155 ð.
  6. David R., VandeWouwer A., Saucez P., Vasel J.-L. Classical Models of Secondary Settlers. 16th European Symposium on Computer Aided Process Engineering (ESCAPE 2006) and 9th International Symposium on Process Systems Engineering. Belgium, 2006, pp. 677—682.
  7. Plosz B.G., Nopens I., Rieger L., Griborio A., De Clercq J., Vanrolleghem P.A., Daigger G.T., Takacs I., Wicks J., Ekama G.A. A Critical Review of Clarifier Modeling: State-of-the-art and Engineering Practices. Proceedings 3rd IWA/WEF Wastewater Treatment Modeling Seminar (WWTmod2012). Mont-Sainte-Anne, Quebec, Canada, February 26-28, 2012, pp. 27—30.
  8. Plosz B. G., De Clercq J., Nopens I., Benedetti L., Vanrolleghem P.A. Shall We Upgrade One-dimensional Secondary Settler Models Used in WWTP simulators? An Assessment of Model Structure Uncertainty and Its Propagation. Water Science and Technology. Belgium, 2011, no. 63(8), pp. 1726—1738.
  9. Ramin E., Sin G., Mikkelsen P.S., Plosz B.G. Significance of Uncertainties Derived from Settling Tank Model Structure and Parameters on Predicting WWTP Performance. A Global Sensitivity Analysis Study. 8th IWA Symposium on Systems Analysis and Integrated Assessment Watermatex 2011. Spain, San Sebastian, 2011, pp. 476—483.
  10. Shaw A., McGuffie S., Wallis-Lage C., Barnard J. Optimizing Energy Dissipating Inlet (Edi) Design In Clarifiers Using an Innovative CFD Tool. Water Environment Federation (WEFTEC). 2005, pp. 8719—8736.
  11. Griborio A. Secondary Clarifier Modeling: a Multi-process Approach. University of New Orleans, USA, 2004, 440 p.
  12. Shahrokhi M., Rostami F., Said Md Azlin Md, Syafalni. The Computational Modeling of Baffle Configuration in the Primary Sedimentation Tanks. 2nd International Conference on Environmental Science and Technology Singapore, 2011, vol. 6, pp. V2-392—V2-396.
  13. Stamou A.I., Latsa M., Assimacopoulos D. Design of Two-storey Final Settling Tanks Using Mathematical Models. Journal of Hydroinformatics. 2000, no. 2(4), pp. 235—245.
  14. Marchuk G.I. Matematicheskoe modelirovanie v probleme okruzhayushchey sredy [Mathematical Modeling in the Environmental Problem]. Moscow, Nauka Publ., 1982, 320 p.
  15. Loytsyanskiy L.G. Mekhanika zhidkosti i gaza [Fluid and Gas Mechanics]. Moscow, Nauka Publ., 1978, 735 p.
  16. Zgurovskiy M.Z., Skopetskiy V.V., Khrushch V.K., Belyaev N.N. Chislennoe modelirovanie rasprostraneniya zagryazneniya v okruzhayushchey srede [Numerical modeling of Pollution Propagation in the Environment]. Kiev, Naukova dumka publ., 1997, 368 p.
  17. Samarskiy A.A. Teoriya raznostnykh skhem [Theory of Difference Schemes]. Moscow, Nauka Publ., 1983, 616 p.

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OPTIMIZATION OF HIGH DIMENSIONALITY SYSTEMS USING ILOG SOFTWARE COMPONENTS

Vestnik MGSU 8/2013
  • Khayrullin Rustam Zinnatullovich - Moscow State University of Civil Engineering (MGSU) Doctor of Physical and Mathematical Sciences, senior scientific worker, Professor, Department of Higher Mathematics, 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 157-164

Effective logistics management in vertically integrated oil companies (VIOC) is an important factor of business success. Losses caused by irrational logistics management may reach hundreds of millions of rubles a year. Therefore, mathematical simulation of VIOC logistics and methods of optimization of high dimensionality systems represent a relevant problem.The author presents a logistics model for VIOCs and their oil products. The model is based on methods applicable to linear programming problems, algorithms of reduction and restoration of high dimensionality matrixes, and the software developed by ILOG Ltd., a leading developer of applied software components.The software package, developed by the author, solve the problem through the optimization of purchases, production, storage, flow and sales of VIOC oil products, in respect of dozens and even hundreds of small companies of the group. The software package takes account of a big variety of types of contracts between companies, delivery service providers, and storage facilities.This solution may be used to generate a wide range of reports both for VIOC as a whole, and for each VIOC constituent company.The software package has been successfully used for 5 years in respect of logistics, operational and strategic planning of purchases, production, storage, flow and sales of oil products, as well as generation and development of an optimal distribution network.The software was integrated into the corporate resource consumption planning system (ERP System). The assessment of the mathematical simulation is also provided and analyzed in the article.

DOI: 10.22227/1997-0935.2013.8.157-164

References
  1. Fusco M.E., Webster M. Increase Profitability across the Enterprise with AspenONE Petroleum Supply Chain. Aspen Technology Inc. Available at: http://aspentech.com/products/aspenONE-Petroleum-Supply-Chain. Date of Access: 09.08.13.
  2. Fusco M.E., Webster M. Maximize Profitability, Reduce Distribution Costs. Aspen Technology Inc. Available at: http://aspentech.com/products/aspen-distribution-planning-optimization.aspx. Date of Access: 09.08.13.
  3. Cardenuto R. Fine Tune Supply Chain Management with SAP Software. SAP Ltd. Available at http://www54.sap.com/solution/lob/scm.html. Date of Access: 09.08.13.
  4. Cardenuto R. Supercharge Oil and Gas Operations. Accelerate Innovation and Energize Performance — with Our Oil and Gas Industry Software. SAP Ltd. Available at: http://www54.sap.com/solution/industry/oil-gas.html. Date of Access: 09.08.13.
  5. Mikkilineni K., Sorkin L.R. Oil & Gas, Refining, Petrochemicals and Biofuels. Honeywell Ltd. Available at: http://honeywell.com/Products-Services/Pages/oil-gas-refining-petrochemicals.aspx. Date of Access: 09.08.13.
  6. ILOG CPLEX 10.1 User’s Manual. Copyright by ILOG, 2006, 140 p.
  7. Simpson I. IBM ILOG. Why IBM Operational Decision Management. IBM Inc. Available at: http://www-01.ibm.com/software/websphere/ilog. Date of Access: 09.08.13.
  8. Simpson I. Network Design and Planning for Supply Chain Optimization. IBM Inc. Available at: http://www-03.ibm.com/software/products/us/en/ibmiloglogiplusxe. Date of Access: 09.08.13.
  9. Simpson I. Multi-objective Technology for Better Network Optimization. IBM Inc. Available at: http://www-03.ibm.com/software/products/us/en/supply-chain-optimization. Date of access: 09.08.13.
  10. Khayrullin R.Z. Tekhnologiya issledovaniya upravlyaemykh sistem [Technology of Research into Controllable Systems]. Gornyy informatsionno-analiticheskiy byulleten' [Informational and Analytical Mining Bulletin]. 1999, no. 4, pp. 111—113.

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Using LabVIEW software to collect and process measurement data as partof development of systems of monitoring of bearing structures

Vestnik MGSU 9/2013
  • Korgin Andrey Valentinovich - Moscow State University of Civil Engineering (MGSU) Doctor of Technical Sciences, Professor, Supervisor, Scientific and Educational Center of Constructions Investigations and Examinations, Department of Test of Structures, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; +7 (499) 183-54-29; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Emel'yanov Valentin Alekseevich - Moscow State University of Civil Engineering (MGSU) Candidate of Technical Sciences, Junior Researcher, Scientific and Educational Center for Engineering Research and Monitoring of Structural Units, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoye shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Ermakov Mikhail Valer'evich - Moscow State University of Civil Engineering (MGSU) Junior Researcher, Scientific and Educational Center for Engineering Research and Monitoring of Structural Units, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoye shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Zeid Kilani Leys Zeydovich - Moscow State University of Civil Engineering (MGSU) Junior Researcher, Scientific and Educational Center for Engineering Research and Monitoring of Structural Units, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoye shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Krasochkin Aleksandr Gennad'evich - Moscow State University of Civil Engineering (MGSU) technician, Scientific and Educational Center for Engineering Research and Monitoring of Structural Units, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoye shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Romanets Vladimir Anatol'evich - Moscow State University of Civil Engineering (MGSU) technician, Scientific and Educational Center for Engineering Research and Monitoring of Structural Units, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoye shosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 134-142

Present-day urban construction trends make buildings taller and the urban environment denser. These developments result in the growth of negative effects produced on existing structures. That’s why the monitoring of the technical condition of structures is of vital importance. Now the most efficient way of forecasting and preventing emergency situations consists in the installation of automated monitoring systems operating in continuous and periodic modes.Monitoring systems may comprise various sensors, devices and measurement elements. Any signal must be coordinated to make sure that the data are accurate and reliable. Moreover, the proposed system (or network) composed of various items of equipment (often produced by various manufacturers) demands appropriate integrated software. The database of LabVIEW drivers can be employed for this purpose.LabVIEW environment is applied for the measurement, testing and management of applications that constitute embedded programming tools needed to develop complex applications designated for computer-aided measurements and data processing. The library of drivers is employed to assure the availability of the most common types of interfaces, sensors and devices. If a user lacks a particular driver, it can be either integrated or developed. The authors have successfully collected and processed the data in the LabVIEW environment of a measurement system based on tensometric sensors attached to experimental items of equipment.

DOI: 10.22227/1997-0935.2013.9.134-142

References
  1. Korgin A.V., Korgina M.A. Integrirovannaya informatsionnaya tekhnologiya monitoringa tekhnicheskogo sostoyaniya zdaniy i sooruzheniy [Integrated Information Technology for the Monitoring of the Technical Condition of Buildings and Structures]. Nauchnye trudy 12 Mezhdunarodnoy mezhvuzovskoy nauchno-prakticheskoy konferentsii molodykh uchenykh, doktorantov, aspirantov «Stroitel'stvo – formirovanie sredy zhiznedeyatel'nosti» [Research works of the 12th International Inter-university Science and Practical Conference of Young Researchers, Doctoral Students and Postgraduates “Construction – Formation of the Environment”. Moscow, 2009, pp. 75—78.
  2. Korgin A.V., Emel'yanov M.V. Intellektual'naya sistema avtomaticheskogo monitoringa tekhnicheskogo sostoyaniya stroitel'nykh konstruktsiy [Intelligent System for Computer-aided Monitoring of the Technical Condition of Structural Units]. Mekhanizatsiya stroitel'stva i ZhKKh [Mechanization of Construction Operations and Housing Utilities]. 2010, no. 9, pp. 18—20.
  3. Shakhraman'yan A.V. Tekhnologicheskie i metodicheskie osnovy postroeniya sistem monitoringa nesushchikh konstruktsiy vysotnykh i unikal'nykh ob"ektov [Technological and Methodological Fundamentals of Development of Systems of Monitoring of Bearing Structures of High-rise and Unique Buildings]. Predotvrashchenie avariy zdaniy i sooruzheniy: elektronnyy zhurnal [Prevention of Emergencies of Buildings and Structures: electronic journal]. Available at: http://www.pamag.ru/pressa/tech-construct. Date of access: 21.07.13.
  4. Data Acquisition and Signal Conditioning Course Manual. National Instruments Course Software. Ver. 2011. February 2012, pp. 74—76.
  5. Suranov A.Ya. LabVIEW 8.20 Spravochnik po funktsiyam [LabVIEW 8.20. Reference Book of Functions]. DMK Press Publ., 2007, pp. 57—133.
  6. Trevis Dzh., Kring Dzh. LabVIEW dlya vsekh [LabVIEW for Everybody]. DMK Press Publ., 2008, pp. 27—95.
  7. Preimushchestva kontseptsii graficheskogo programmirovaniya NI LabVIEW [Advantages of the Concept of Graphic Programming in LabVIEW]. Available at: http://www.LabVIEW.ru/LabVIEW/what_is_LabVIEW/rapid_development.php Date of access: 23.04.2013.
  8. Peych L.I., Tochilin D.A., Pollak B.N. LabVIEW dlya novichkov i spetsialistov [LabVIEW for Beginners and Specialists]. Moscow, Goryachaya Liniya — Telekom Publ., 2004, pp. 33—46.
  9. Zagidullin R.Sh. LabVIEW v issledovaniyakh i razrabotkakh [LabVIEW in Researches and Developments]. Moscow, Goryachaya Liniya – Telekom Publ., 2005, pp. 216—251.
  10. Batovrin V.K., Bessonov A.S., Moshkin V.V., Papulovskiy V.F. LabVIEW praktikum po osnovam izmeritel'nykh tekhnologiy [LabVIEW Practice Book on Fundamentals of Measurement Technologies]. DMK Press Publ., 2010, pp. 36—49.

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On a problem of active system management

Vestnik MGSU 9/2013
  • Khayrullin Rustam Zinnatullovich - Moscow State University of Civil Engineering (MGSU) Doctor of Physical and Mathematical Sciences, senior scientific worker, Professor, Department of Higher Mathematics, 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 .
  • Adigamov Arkadiy Engelevich - Moscow State University of Civil Engineering (MGSU) Candidate of Technical Sciences, Associate Professor, Associate Professor, Department of Higher Mathematics; +7(495)236-95-21, 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 .
  • Bitieva Zarina Ruslanovna - Moscow State University of Civil Engineering (MGSU) assistant, Laboratory of Communicative and Information Technologies; +7(495)939-46-98., 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 143-148

A mathematical model of an active system is considered in the article. An active system represents an organizational model. The authors research into the problem of inconsistency between the concerns of the management authority and those of the managed subject. The managed subject acts for its benefit and supplies realistic information to the management authority. The main method of research into the above systems is based on the mathematical simulation of administrative decision making procedures. The theoretical grounds represent the systems analysis, the game theory, the decisionmaking theory, operations research, discrete mathematics and the management theory. The active system theory is based on a coordinated mechanism of choice. If the coordinated mechanism of choice is unavailable, the mechanism closest to the coordinated one must be developed. In this case, the authors believe it appropriate to consider additional criteria characterizing the "proximity" of a decision to coordinated and cumulative criteria, which are equal to the sum of additional criteria adjusted by particular coefficients of importance. A set of plans that cannot be coordinated at the same time is composed on the basis of the analysis of additional criteria and the cumulative criterion. Model testing and mathematical simulation are presented in the article.

DOI: 10.22227/1997-0935.2013.9.143-148

References
  1. Burkov V.N., Novikov D.A. Teoriya aktivnykh sistem: sostoyanie i perspektivy [Theory of Active Systems: Status and Prospects]. Moscow, SINTEG Publ., 2001.
  2. Burkov V.N., Zalozhnev A.Yu., Novikov D.A. Teoriya grafov v upravlenii organizatsionnymi sistemami [Theory of Graphs in Management of Organizational Systems]. Moscow, SINTEG Publ., 2001.
  3. Novikov D.A. Teoriya upravleniya organizatsionnymi sistemami [Theory of Management of Organizational Systems]. Moscow, Fizmatlit Publ., 2007.
  4. Myerson R.B. Games Theory: Analysis of Conflict. London, Harvard University Press, 1991.
  5. Fudenberg D., Tirole J. Game Theory. Cambridge, MIT Press, 1995.
  6. Nisan N., Roughgarden T., Tardos E., Vazirani V. Algorithmic Game Theory. New-York, Cambridge University Press, 2009.
  7. Drucker P. The Effective Executive: The Definitive Guide to Getting the Right Things Done. New-York, Collins Business, 2006.
  8. Adigamov A.E., Yudenkov A.V., Ivanov V.V. Matematicheskaya model' konfliktnoy situatsii na mikrourovne v nechetkoy postanovke [Mathematical Model of a Conflict Situation on the Misrolevel in the Fuzzy Setting]. Gornyy informatsionno-analiticheskiy byulleten' [Mining Bulletin of Information and Analysis]. 2010, no. 1, pp. 80—83.
  9. Khayrullin R.Z. Tekhnologiya issledovaniya upravlyaemykh sistem [Technology of Research into Managed Systems]. Gornyy informatsionno-analiticheskiy byulleten' [Mining Bulletin of Information and Analysis]. 1999, no. 4, pp. 111—113.
  10. Vybory v Rossiyskoy Federatsii 2007. Elektoral'naya statistika. Tsentral'naya izbiratel'naya komissiya Rossiyskoy Federatsii [Elections in the Russian Federation 2007. Electoral Statistics. Central Election Committee of the Russian Federation.] Moscow, SitiPressServis Publ., 2008.

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Reasons and stages of transition from ERP to enterprise information systems

Vestnik MGSU 10/2013
  • Anikin Dmitrii Vasilevich - Moscow State University of Civil Engineering (MGSU) Engineer, Department of Enterprise Information Systems, 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 278-286

In addition to ERP systems, there is a specific list of other systems: asset management, product lifecycle management at all stages, operations management, customer relationship management, the management of the overall performance of the company, supply chain management, project management, service management, portals outside interference.A construction company must be prepared to work with a great number of customers, to understand what they need and when, not to disappoint their expectations, be prepared for the fact that customers can be not in the same region as the construction company. Senior management should be able to work with subcontractors, time contracts, freelancer workers, be aware of the financial affairs of the company.When choosing software package, a company should be guided by its aims, clearly understand the expected effect. Choosing software system is an integral part of the process of information systems implementation. It should not be focused entirely on the selected software, after all, the main purpose of this introduction is to optimize the infrastructure management. In this case, not programmers, but business consultants must deal with the implementation.A system that will include the ERP-system is needed, which will be easy to operate, flexible and interoperable not only internally, but also with external applications. This system should be object-oriented for easy programming, reasonably standardized, functional, have a high level of self-organization and to have one of the representations in the form of business processes.The stages of the project of implementing interoperable enterprise information systems are the following: definition of the project aims; enterprise inspection and preparation for the project of implementation, the choice of software package supplier, management of the project of information system construction and development.

DOI: 10.22227/1997-0935.2013.10.278-286

References
  1. Naneishvili G.D. Opredelenie k terminam ERP i trebovaniya k ERP-sistemam [Definitions to the Terms of ERP and Requirements to ERP-systems]. 2013. Available at: http://club.cnews.ru/blogs/entry/opredelenie_termina_erp_i_trebovaniya_k_erpsistemam Date of access: 05.2013.
  2. Volkov A.A. Sistemy aktivnoy bezopasnosti stroitel'nykh ob"ektov [Active Safety Systems of Construction Sites]. Zhilishchnoe stroitel'stvo [House Construction]. 2000, no. 7, p. 13.
  3. Volkov A. A. Ierarkhii predstavleniya energeticheskikh sistem [Hierarchies of Description of Energy Systems]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2013, no. 1, pp. 190—193.
  4. Sedov A., Volkov A., Chelyshkov P. Usage of Building Information Modeling for Evaluation of Energy Efficiency. Applied Mechanics and Materials (Trans Tech Publications, Switzerland). 2013, vol. 409—410, pp. 630—633.
  5. Andreev V. Za granitsami ERP [Beyond the Limits of ERP]. 2006. Available at: http://www.interface.ru/fset.asp?Url=/chapters/news.htm Date of access: 11.04.2013.
  6. Volkov A., Sukneva L. Programming Applications of Computer Aided Design and Layout of the Complex Solar Panels. Applied Mechanics and Materials (Trans Tech Publications, Switzerland). 2013, vol. 411—414, pp. 1840—1843.
  7. Volkov A.A., Yarulin R.N. Avtomatizatsiya proektirovaniya proizvodstva remontnykh rabot zdaniy i inzhenernoy infrastruktury [Computer-Aided Design of Repairs of Buildings and the Engineering Infrastructure]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2012, no. 9, pp. 234—240.
  8. Volkov A.A., Ignatov V.P. Myagkie vychisleniya v modelyakh gomeostata stroi-tel'nykh ob"ektov [Soft Computing of the Homeostat Models of Buildings]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2010, no. 2. pp. 279—282.
  9. Gnatush A. ERP-sistemy: «za», «protiv» ili vozderzhat'sya [ERP-systems: in favor, against, abstentions]. 2006. Available at: http://www.interface.ru/fset.asp?Url=/chapters/news.htm Date of access: 12.04.2013.
  10. Volkov A., Vodnev N.N. Sistemotekhnika chislennykh predstavleniy kachestvennykh parametrov sredy zhiznedeyatel'nosti: rekursivnoe pogruzhenie na urovni detalizatsii ob"ekta [Numerical Representation System Engineering of the Quality Parameters of Living and Working Environment: Recursive Exposure into Detailization Levels of an Object]. Promyshlennoe i grazhdanskoe stroitel'stvo [Industrial and Civil Engineering]. 2013, no. 7, pp. 29—32.
  11. Volkov A.A. Gomeostaticheskoe upravlenie zdaniyami [Homeostatic Management of Buildings]. Zhilishchnoe stroitel'stvo [House Construction]. 2003, no. 4, pp. 9–10.
  12. Rubtsov S. Sistemy upravleniya biznes-protsessami i korporativnaya kul'tura [Systems of Business Processes Management and Corporate Culture]. 2001. Available at: http://www.pcweek.ru/idea/article/detail.php?ID=60155 Date of access: 17.04 2013.
  13. Vernikov G. Korporativnye informatsionnye sistemy: ne povtoryayte proydennykh oshibok [Enterprise Information Systems: Do not Repeat Past Mistakes]. 2002. Available at: http://www.cfin.ru/vernikov/kias/errors.shtml. Date of access: 17.04.2013.
  14. Volkov A.A. Bezopasnost' stroitel'nykh ob"ektov v chrezvychaynoy situatsii [Safety of Construction Projects in Emergency Situations]. Sel'skoe stroitel'stvo [Rural Construction]. 2000, no. 3, pp. 42—43.
  15. Volkov A.A., Pikhterev D.V. K voprosu ob organizatsii informatsionnogo obespecheniya stroitel'nogo ob"ekta [On the Issue of Arrangement of Information Support of a Construction Facility]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2011, no. 6, pp. 460—462.

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System technique of virtual organizational structures design for construction companies

Vestnik MGSU 10/2013
  • Bol'shakov Sergey Nikolaevich - Moscow State University of Civil Engineering (MGSU) postgraduate student, Assistant, Department of Information Systems, Technologies and Automation in Construction, Moscow State University of Civil Engineering (MGSU), 26, Yaroslavskoyeshosse, Moscow, 129337, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 287-294

The article describes virtual organizational structure for the construction industry, which was formed as a result of a number of problematic issues. The development of the construction industry is one of the prior tasks for the state economy. Virtual enterprises, tailored to the industry, showed themselves as the most progressive means of production optimization and automation.Virtual organizational structures are becoming more widespread. They demonstrate positive effect after being introduced and used in various sectors of the economy. Today, foreign experience and technologies of implementing virtual organizational structures of enterprises is actively adapted in the realities of the Russian economy with harsh investment climate and the increased interest of the state sector. The introduction of virtual organizational structures for construction companies is a significant step in the process of the industry informalization. By setting a precedent and reinforcing it by appropriate methodological framework, we obtain a basis for the formation of information platforms, which contain the full list of theoretical and practical knowledge.Getting positive effect after creating virtual organizational structures of enterprises in the construction industry is only half the way. Any result from the introduction will result in a new area for research and development.

DOI: 10.22227/1997-0935.2013.10.287-294

References
  1. Volkov A.A. Informatsionnoe obespechenie v ramkakh kontseptsii intellektual'nogo zhilishcha [Information Support under the Concept of Smart Homes]. Zhilishchnoe stroitel'stvo [House Construction]. 2001, no. 8, pp. 4—5.
  2. Volkov A.A. Gomeostat stroitel'nykh ob"ektov. Chast' 3. Gomeostaticheskoe upravlenie [Homeostat of Construction Projects. Part 3. Homeostatic Management]. Stroitel'nye materialy, oborudovanie, tekhnologii XXI veka [Building Materials, Equipment, Technologies of the 21st century]. 2003, no. 2, pp. 34—35.
  3. Volkov A.A., Yarulin R.N. Avtomatizatsiya proektirovaniya proizvodstva remontnykh rabot zdaniy i inzhenernoy infrastruktury [Computer-Aided Design of Repairs of Buildings and the Engineering Infrastructure]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2012, no. 9, pp. 234—240.
  4. Chelyshkov P., Volkov A., Sedov A. Application of Computer Simulation to Ensure Comprehensive Security of Buildings. Applied Mechanics and Materials (Trans Tech Publications, Switzerland). 2013, vol. 409—410, pp. 1620—1623.
  5. Volkov A.À. Building Intelligence Quotient: Mathematical Description. Applied Mechanics and Materials (Trans Tech Publications, Switzerland). 2013, vol. 409—410, pp. 392—395.
  6. Volkov A.A. Udalennyy dostup k proektnoy dokumentatsii na osnove sovremennykh telekommunikatsionnykh tekhnologiy [Remote Access to Project Documents on the Basis of Advanced Telecommunications Technologies]. Stroitel'nye materialy, oborudovanie, tekhnologii XXI veka [Building Materials, Equipment, Technologies of the 21st century]. 2000, no 4, p. 23.
  7. Volkov A.A, Lebedev V.M. Proektirovanie sistemokvantov rabochikh operatsiy i trudovykh stroitel'nykh protsessov v srede informatsionnykh tekhnologiy [Designing of the System Quanta of Working Operations and Labor Building Processes in the IT environment]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2010, no. 2, pp. 293—296.
  8. Volkov A.A. Virtual'nyy informatsionnyy ofis stroitel'noy organizatsii [Virtual Information Office of a Building Company]. Stroitel'nye materialy, oborudovanie, tekhnologii XXI veka [Building Materials, Equipment, Technologies of the 21st century]. 2002, no. 2, pp. 28—29.
  9. Volkov A.A., Vaynshteyn M.S., Vagapov R.F. Raschety konstruktsiy zdaniy na progressiruyushchee obrushenie v usloviyakh chrezvychaynykh situatsiy. Obshchie osnovaniya i optimizatsiya proekta [Design Calculations for the Progressive Collapse of Buildings in Emergency Situations. Common Grounds and Project Optimization]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2008, no. 1, pp. 388—392.
  10. Losev K.Yu., Losev Yu.G., Volkov A.A. Razvitie modeley predmetnoy oblasti stroitel'noy sistemy v protsesse razrabotki informatsionnoy podderzhki proektirovaniya [Building System Subject Area Development During the Process of Design-cals-system Work out]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2011, no. 1, vol. 1, pp. 352—357.

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The organization of efficient functioning and improvement of industrialand environmental systems

Vestnik MGSU 10/2013
  • Volkov Andrey Anatol’evich - Moscow State University of Civil Engineering (National Research University) (MGSU) Doctor of Technical Sciences, corresponding member of Russian Academy of Architectural and Construction Sciences, Professor, Department of Information Systems, Technologies and automation in Construction, Rector, 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 .
  • Shlykova Anna Anatol'evna - Moscow State University of Civil Engineering (MGSU) postgraduate student, assistant, Department of Information Systems, Technology and Automation in Civil Engineering, 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 295-300

The paper deals with optimization of the process of purification and desulfonation of the flue gas in industrial and environmental systems.The objects of the research are industrial and environmental systems producing gypsum. The research presents the modes, methods and control circuits of the systems operation in order to monitor the quality of byproduct and end product. Also the subject of the research is the analysis and synthesis of organizational and technical solutions and the development of the methods for determining and assessing the feasibility of the process operational optimization on the basis of the received results. In the given theoretical research and practical studies the methods of structural organization and mathematical modeling of production processes were used, together with the methods of their engineering, operational optimization, and linear synthesis of organizational control systems.Analytical and idealized mathematical models of gypsum production on flue gas desulphurisation units were compared.The practical significance of the research is in theoretical base and recommendations for scientifically-based selection of organizational structures, modes, methods and control circuits. These organizational structures, modes, methods and control circuits are used for establishing new industrial and environmental systems, as well as updating and improving existing ones. Preliminary calculations show, that the obtained results will improve the quality of end products and improve the technical and economic performance. Also they will help to reduce the time and cost of research while creating industrial and environmental systems.

DOI: 10.22227/1997-0935.2013.10.295-300

References
  1. Ayrapetov A.K., Zaytsev V.A., Rul'nov A.A. Razrabotka i postroenie matemati-cheskoy modeli protsessa polucheniya gipsa pri seroochistke dymovykh gazov [The Development and Construction of a Mathematical Model of Gypsum Production in the Process of Flue Gas Desulphurisation]. Avtomatizatsiya i upravlenie tekhnologicheskimi protsessami i proizvodstvami v stroitel'stve: Sbornik [The Automation and Management of Technological Processes and Production in Construction Area: Collection of Works]. Moscow, MGSU Publ., 2004, pp. 38—42.
  2. Mironov N.P. Matematicheskoe opisanie protsessa ochistki otkhodyashchikh gazov ot sernistogo angidrida [The Mathematical Description of Flume Cleaning of Sulfur Dioxide]. Oborudovanie i sredstva avtomatizatsii [The Equipment and Automation Aids]. 1998, no. 4, pp.1—5.
  3. Komar A.G., Rul'nov A.A. Matematicheskoe opisanie protsessa polucheniya gipsa pri seroochistke otkhodyashchikh gazov [The Mathematical Description of Gypsum Production in the Process of Flue Gas Desulphurisation]. Izvestiya vuzov. Stroitel'stvo i arkhitektura [News of Higher Educational Institutions. Construction and Architecture]. 1982, no. 12, pp. 66—71.
  4. Shkatov E.F. Avtomatizatsiya promyshlennoy i sanitarnoy ochistki gazov [The Automation of Industrial and Sanitary Gas Cleaning]. Moscow, Khimiya Publ., 1999, 200 p.
  5. Volkov A.A. Informatsionnoe obespechenie v ramkakh kontseptsii intellektual'nogo zhilishcha [Information Support under the Concept of Smart Homes]. Zhilishchnoe stroitel'stvo [House Construction]. 2001, no. 8, pp. 4—5.
  6. Volkov A.A. Virtual'nyy informatsionnyy ofis stroitel'noy organizatsii [Virtual Information Office of a Building Company]. Stroitel'nye materialy, oborudovanie, tekhnologii XXI veka [Building Materials, Equipment, Technologies of the 21st century]. 2002, no. 2, pp. 28—29.
  7. Volkov A.A. Udalennyy dostup k proektnoy dokumentatsii na osnove sovremennykh telekommunikatsionnykh tekhnologiy [Remote Access to Project Documents on the Basis of Advanced Telecommunications Technologies]. Stroitel'nye materialy, oborudovanie, tekhnologii XXI veka [Building Materials, Equipment, Technologies of the 21st century]. 2000, no 4, p. 23.
  8. Volkov A.A. Gomeostat v stroitel'stve: sistemnyy podkhod k metodologii upravleniya Homeostat in construction: a systems approach to management methodology // Promyshlennoe i grazhdanskoe stroitel'stvo Industrial and civil construction. 2003, no. 6, p. 68.
  9. Volkov A.A, Ignatov V.P. Myagkie vychisleniya v modelyakh gomeostata stroi-tel'nykh ob"ektov [Soft Computing of the Homeostat Models of Buildings] Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2010, no. 2. pp. 279—282.

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The model of multiagent system for automatization of version design of frame structures

Vestnik MGSU 10/2013
  • Kozyreva Viktoriya Viktorovna - Moscow State University of Civil Engineering (MGSU) postgraduate student, 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 .
  • Volkov Andrey Anatol’evich - Moscow State University of Civil Engineering (MGSU) Rector, Doctor of Technical Sciences, Professor, Chair, Department of Information Systems, Technology and Automation in Civil Engineering, Moscow State University of Civil Engineering (MGSU), 26 Yaroslavskoe shosse, Moscow, 129337, Russian Federation; +7 (499) 929-52-29; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 301-308

In the process of version design of structures an engineer is compelled to solve problems of parametrical synthesis (parametrical optimization). Existing design software systems contain modules of optimization. But they require the user to select a specific optimization method, used throughout the computing process, which does not always provide effective solutions. The recalculation of structure by the method of finite elements on each stage of optimization demands much time and computing. The solution to this problem is possible by using parallel computing and introducing a block of approximations, which would allow accepting a preliminary approximate solution to a problem without using FE-analysis. It can be realized using a group of intellectual agents organized as a multiagent system. A multiagent system is effective modern software, which uses the intelligent agents as the basic units. Agents can be arranged in groups and work closely together during the decision-making process. In the article the authors offer a multiagent system consisting of three types of agents in order to solve the problem of version design of structures. The agents are assigned for special functional roles: agentperformer, agent-calculator and agent-manager. The agent-performer is responsible for optimization of every element of the structure. The agent-calculator carries out design calculation by means of FE method. The agent-manager makes control over the process of task solution, interaction of agents in the system, resolves conflicts and defines current purposes of the computing system.

DOI: 10.22227/1997-0935.2013.10.301-308

References
  1. Alekseytsev A.V., Serpik I.N. Optimizatsiya ploskikh ferm na osnove geneticheskogo poiska i iterativnoy protsedury triangulyatsii [Optimization of Flat Farms on the Basis of Genetic Search and Iterative Procedure of Triangulation]. Stroitel'stvo i rekonstrutsiya [Construction and reconstruction]. Moscow, 2011, no. 2, p. 3—8.
  2. Vasil'kov G.V. Evolyutsionnaya teoriya zhiznennogo tsikla mekhanicheskikh sistem: Teoriya sooruzheniy [Evolutionary Theory of Life Cycle of Mechanical Systems: Theory of Constructions]. Moscow, LKI Publ., 2013, 320 p.
  3. Sofieva Yu.N., Tsirlin A.M. Uslovnaya optimizatsiya. Metody i zadachi [Conditional Optimization. Methods and Tasks]. Moscow, Librikom Publ., 2012, 144 p.
  4. Shoham Y., Leyton-Brown K. Multiagent Systems. Algorithmic, Game-Theoretic, and Logical Foundations. Cambridge University Press, 2009.
  5. Official site of The Foundation for Intelligent Physical Agent. Available at: www.fipa.org/subgroups/ROFS-SG-docs/History-of-FIPA.htm#10-1996 Date of access: 5.09.2013.
  6. Gorodetskiy V.I., Grushinskiy M.S., Khabalov A.V. Mnogoagentnye sistemy (obzor) [Multiagent systems (review)]. Novosti iskusstvennogo intellekta [News of Artificial Intelligence]. 1998, no. 2. Available at: http://www.raai.org/library/library.shtml?publ?ainews.
  7. Hyacinth S. Nwana. Software Agents: An Overview. Knowledge Engineering Review. 1996, vol. 11, no 3, pp. 1—40.
  8. Wooldridge M., Michael J. An Introduction to Multiagent Systems. 2nd ed. John Wiley & Sons, 2009.
  9. Tarasov V.B. Ot mnogoagentnykh sistem k intellektual'nym organizatsiyam: filosofiya, psikhologiya, informatika [From Multiagent Systems to Intellectual Organizations: Philosophy, Psychology, Informatics]. Moscow Editorial URSS Publ., 2002, 352 p.
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  11. Volkov A.A. Formalizatsiya zadach organizatsii funktsional'nogo upravleniya ob"ektami (protsessami) v stroitel'stve. Ustoychivost' [Formalization of tasks of the organization of functional management by objects (processes) in construction. Stability]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2008, no. 1, pp. 347—351.
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Mathematical model of the filtration process in suspended floc layer of the contact mass with account for its horizontal size limit

Vestnik MGSU 10/2013
  • Skolubovich Yuriy Leonidovich - The Novosibirsk State University of Architecture and Civil Engineering (NGASU) Doctor of Technical Sciences, Professor, Rector, The Novosibirsk State University of Architecture and Civil Engineering (NGASU), 113 Leningradskaya street, Novosibirsk, 630008, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Boyko Ol'ga Aleksandrovna - The Novosibirsk State University of Architecture and Civil Engineering (NGASU) Senior Lecturer, Department of Information tehnology, The Novosibirsk State University of Architecture and Civil Engineering (NGASU), 113 Leningradskaya street, Novosibirsk, 630008, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Zerkal' Sergey Mikhaylovich - The Novosibirsk State University of Architecture and Civil Engineering (NGASU) Doctor of Technical Sciences, Professor, Department of Applied Mathematics, The Novosibirsk State University of Architecture and Civil Engineering (NGASU), 113 Leningradskaya street, Novosibirsk, 630008, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Rogazinskiy Sergey Valentinovich - The Novosibirsk State University of Architecture and Civil Engineering (NGASU) Doctor of Technical Sciences, Professor, Department of Applied Mathematics, The Novosibirsk State University of Architecture and Civil Engineering (NGASU), 113 Leningradskaya street, Novosibirsk, 630008, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .
  • Sineeva Natal'ya Valer'evna - The Novosibirsk State University of Architecture and Civil Engineering (NGASU) Candidate of Technical Sciences, Dean, Faculty of Engineering and Ecology, The Novosibirsk State University of Architecture and Civil Engineering (NGASU), 113 Leningradskaya street, Novosibirsk, 630008, Russian Federation; This e-mail address is being protected from spambots. You need JavaScript enabled to view it .

Pages 309-316

The problem of filtration in the conditions of suspended contact mass appears not only in the process of water purification, but also in other spheres of human activity.New theory on foreign particle motion inside suspended floc layer is observed (only their upward motion). The influence of horizontal limit of the suspended floc layer on foreign particle motion is considered. The co-authors present equations for calculating new space coordinates of a foreign particle.Therefore, the authors form mathematical model of the water purifying filter reactor functioning, which can be used in the process of studying the peculiarities of filtration and in prospect can be taken as the basis for experiment planning. Further specification of this model may be made in case of developing the method of calculating the free path length in space case.

DOI: 10.22227/1997-0935.2013.10.309-316

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