REGULATION OF PARAMETERS OF NATURAL OSCILLATIONS OF THE SPATIAL FRAME OF THE BUILDING

Aim. In article the problem of influence of geometrical characteristics of elements of a steel concrete frame of the building on parameters of forms of natural oscillations of system is considered.

Methods. The finite and element model of an object in a program complex of ING + according to the spatial slabby and rod diagram is developed by the finite-element method. A slabby grillage, plates of overlapping and a covering, a wall and a diaphragm of rigidness were modelled by triangular cover elements with 18 levels of freedom and quadrangular cover elements with the 24th freedom levels. Columns were modelled by spatial rods with 12 levels of freedom. Spatial rigidness of a frame is provided with collaboration of columns, diaphragms of rigidness and plates of overlappings. The estimated diagram is developed taking into account rigid seal of columns, diaphragms of rigidness and walls in a monolithic slabby grillage.

Results. Seven versions of different project solutions of a frame of the multi-storey building are probed. In project decisions parameters of a transverse section of walls of the elevator shaft, diaphragms of cruelty and plates of overlappings varied. As a result of dynamic calculation in a program complex of ING + MKE are received the maximum relocation of the upper point of a plate of overlapping, frequency and the periods of natural oscillations.

Conclusion. The analysis of results of researches on regulation of forms and frequencies of natural oscillations of a frame of the building taking into account change of rigidities of elements of a frame is made. Results of dynamic calculation are reduced in plate, graphic and illustrative forms. Recommendations about a choice of version of project solutions of a frame of the building with optimum parameters of natural oscillations are made.

1. Abakarov A.D., Zaynulabidova H.R. Probabilistic models of seismic effects. Vestnik Dagestanskogo gosudarstvennogo tehnicheskogo universiteta. Tehnicheskie nauki. [Herald of Daghestan State Technical University. Technical science], 2009. vol.15, no.4, pp.92-97. (In Russian)

2. Abdurazakov G.M., Abakarov A.D. Construction of settlement survivability assessment models frame systems under seismic impacts. Voprosy sovremennykh tekhnicheskikh nauk: Svezhii vzglyad i novye resheniya. Sbornik nauchnykh trudov konferentsii [Questions of modern engineering science: A fresh look and new solutions. Collection of scientific papers Conference]. 2015, рр. 58-61. (In Russian)

3. Abovsky N.P., Endzhiievsky L.V., Sachenkov V.I. et al. Selected problems in structural mechanics and theory of elasticity (regulation, synthesis, optimization). Uchebnoe posobie dlya VUZov [Textbook for High Schools]. Moskow: Stroyizdat, 1978, рр.25-26. (In Russian)

4. Agakhanov G.E. Agakhanov G.E. The solution of problems of mechanics of the deformable solid body with use of fictitious settlement schemes. Vestnik Dagestanskogo gosudarstvennogo tehnicheskogo universiteta. Tehnicheskie nauki. [Herald of Dagestan State Technical University. Technical Science], 2015, vol.38, no.3, pp.8-15. (In Russian) DOI:10.21822/2073-6185-2015-38-3-8-15.

5. Agakhanov E.K., Kravchenko G.M., Panasyuk L.N., Trufanova E.V. Implementation of the method of kinematic decomposition for calculations in nonlinear formulation. Vestnik Dagestanskogo gosudarstvennogo tehnicheskogo universiteta. Tehnicheskie nauki. [Herald of Dagestan State Technical University. Technical Sciences], 2014, vol.35, no.4, pp.14-19. (In Russian). DOI:10.21822/2073-6185-2014-35-4-14-19.

6. Agakhanov E.K. About development of complex decision methods of the problems of deformable solid body mechanics. Vestnik Dagestanskogo gosudarstvennogo tehnicheskogo universiteta. Tehnicheskie nauki. [Herald of Dagestan State Technical University. Technical Sciences], 2013, vol.29, no.2, pp.39-45. (In Russian). DOI:10.21822/2073-6185-2013-29-2-39-45.

7. Agakhanov E.K. Development of complex methods in solid mechanics. Materialy Mezhdunarodnoy nauchno-prakticheskoy konferentsii. Groznyy. [International scientific-practical conference], Grozny, 2015, pp.99-105. (In Russian)

8. Kravchenko G.M., Kazantsev A.A., Shamitko D.A. Determination of the optimal parameters of plate and rod systems. [Theoretical Foundation of Civil Engineering], Warsaw, 2006, pp.78-82. (In Russian)

9. Kravchenko G.M., Korobkin A.P., Trufanova E.V., Lukyanov V.I. Criteria for evaluation of dynamic models of reinforced concrete frame building. Science Time, 2014, pp.255-260. (In Russian)

10. Murtazaliyev G.M., Akaev A.I., Payzulaev M.M. Main ratios of the initial stage of poslekritichechky of deformation of designs. Vestnik Dagestanskogo gosudarstvennogo tehnicheskogo universiteta. Tehnicheskie nauki. [Herald of Dagestan State Technical University. Technical Sciences], 2013, vol.28, no.1. pp.90-94. (In Russian) DOI:10.21822/2073-6185-2013-28-1-90-94.

11. Murtazaliev G.M., Dibirgadzhiev A.M. Variational principles of mechanics of structures. Abstracts of the XXXVI final scientific conference of teachers, staff and students Dagestan State Technical University. Dagestanskiy gosudarstvennyy tekhnicheskiy universitet [Daghestan State Technical University], 2015, pp.118-119. (In Russian)

12. Trufanova E.V., Panasyuk E.L. Influence of simplifying hypotheses in modeling of construction projects on the accuracy of design results. [Science and business: ways of development], Nauka i biznes: puti razvitiya, 2013, vol.26, no.8, pp.11-18. (In Russian)

13. Batht K.-J. Finite Element Procedures. New Jersey: Prentice Hall, 1996, pp.95-97.

14. Engel H. Structure Systems. Stuttgart: Deutsche Verlags-Anstalt, 1967, pp.23-24.

15. Lutz L.A. Analysis of Stress in Concrete Hear a Reinforcing Bar Due To Bond and Transverse. ACI Joarnal, 1979, no.10, pp.12-15.

16. Nilsen A.H. Nonlinear Analysis of Reinforced Concrete by the Finite Element Method. ACI Joarnal, 1968, vol. 65, no.9, pp.6-70.

17. Raymond W. Clough, Joseph Penzien. Dynamics of Structures. New York: McGraw-Hill, 1993, pp.29-31.

18. Semenov V.A. Hybrid finite elements for analysis of shell structures. Proceedings of international congress ICSS-98, June 22-26, 1998, Moscow, Russia, 1998, vol.1, pp.47-49.

19. Simbirkin V. Analysis of Reinforced Concrete Loadbearing Systems of Multistorey Buildings. Modern Building Materials, Structures and Techniques. CD-ROM Proceedings of the 8th International Conference, Vilnius, May 19-21, 2004, pp.98-99.

20. Yakushev Vladimir Analysis of numerical methods for building structures in STARK ES. ABSE-IASS-2011 Symposium, London, 20 - 23 September, 2011, pp.54-56.