Your search keyword '"Core-tube"' showing total 2 results

1. Heat transfer performance of a two-phase closed thermosyphon with different inclination angles based on the core-tube monitoring

Author

Yingmei Wang, Xi Wang, Juncheng Wang, Yongheng Liu, and Ji Chen

Subjects

Two-phase closed thermosyphon, Core-tube, Inclination angle, Isothermal characteristic, Heat transfer rate, Thermal resistance, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Two-phase closed thermosyphons (TPCTs) have been widely used in permafrost regions because of their good cooling effect. The variation in the inclination angle of TPCTs significantly affects the heat transfer process and temperature distribution inside TPCTs, which is still not fully understood. This study experimentally investigated the heat transfer performance of TPCTs with inclination angles varied from 0° to 90° with 10° intervals. In addition to the outer wall temperature and heat flux, the thermal regime of the working medium inside TPCT was simultaneously monitored based on the core-tube. Experimental results show that the temperature distributions inside TPCT along the axial direction vary regularly with inclination angle. The heat transfer rates of the evaporator and condenser sections change nonmonotonically and nonlinearly with the inclination angle. The influence of the inclination angle on the thermal resistance is greater in the evaporator and the adiabatic sections than in the condenser section. Consequently, a TPCT at 10° produces the best heat transfer performance, corresponding to the best isothermal characteristics, the maximum heat transfer rates of the evaporator and condenser sections, and the minimum total thermal resistance. This study provides a reference of monitoring method for further research on TPCT.

Published

2023

2. Dynamic Response Of Fixed-Base Core-Tube And Base-Isolated Frame Structure Subjected To Strong Earthquake Motions

Author

Z.D. Yang and E.S.S. Lam

Subjects

Base Isolator, Core-tube, Isolated frame, Seismic Mitigation, Story Isolator, Physics::Geophysics

Abstract

Considering the merits and limitations of energy dissipation system, seismic isolation system and suspension system, a new earthquake resistant system is proposed and is demonstrated numerically through a frame-core structure. Base isolators and story isolators are installed in the proposed system. The former “isolates" the frame from the foundation and the latter “separates" the frame from the center core. Equations of motion are formulated to study the response of the proposed structural system to strong earthquake motion. As compared with the fixed-base building system, the proposed structural system shows substantial reduction on structural response., {"references":["M. D. Symans, F. A. Charney, A. S. Whittaker, M. C. Constantinou, C.\nA. Kircher, M. W. Johnson and R. J. McNamara, Energy Dissipation\nSystems for Seismic Applications: Current Practice and Recent\nDevelopments, J. Struct. Eng. 2008; 134(1) 3-21.","M.C. Constantinou, P.Tsopelas, W. Hammel and A.N. Sigaher, Togglebrace-\ndamper seismic energy dissipation system, J. Struct. Eng. 2001;\n127(2) 105-112.","T.S.K. Chung, E.S.S. Lam, B.Wu and Y.L. Xu, Retrofitting Reinforced\nConcrete Beam-column Joints by Hydraulic Displacement\nAmplification Damping System. Proceedings of 2007 ASCE Structures\nCongress. Long Beach, California; 2007.","A. Whittaker and M. Constantinou, Seismic Energy Dissipation\nSystems for Buildings, in: Y. Bozorgnia, V.V. Bertero (Eds.),\nEarthquake Engineering From Engineering Seismology to Performance-\nBased Engineering, Taylor & Francis, London, 2006, pp. 716-744.","J.M. Kelly, Aseismic base isolation: review and bibliography, Soil Dyn.\nEarthq. Eng.1986; 5(4) 202-216.","R.L. Mayes and F. Naeim, Design of Structures with Seismic Isolation,\nin: F. Naeim (Eds.), The Seismic Design Handbook, second ed., Kluwer\nacademic publishers, Boston, Dordrecht, London, 2001, pp.723-756.","H.N. Li and X.X. Wu, limitations of height to width ratio for baseisolated\nbuildings under earthquake, Struct. Design Tall Spec. Build.\n2006; 15 277-287.","T. Komuro, Y. Nishikawa, Y. Kimura and Y. Isshiki, Development and\nrealization of base isolation system for high-rise buildings, J. Adv.\nConcr. Technol. 2005; 3(2) 233-239.","L. Bo, S.S. Xiong and J.X. Tang, Wind effects on habitability of baseisolated\nbuildings, J. Wind Eng. Ind. Aerodyn.2002; 90 1951-1958.\n[10] M. Mezzi and A. Parducci, Conceptual seismic design and state-of-the\nart protection systems. 8th U.S. National Conference on Earthquake\nEngineering. San Francisco, California, USA; April 2006.\n[11] Y. Nakamura, M. Saruta, A. Wada, T. Takeuchi, S. Hikone and T.\nTakahashi, Development of the core-suspended isolation system,\nEarthq. Eng. Struct. D. 2011; 40:429-447.\n[12] D. Mar, L. Panian, R.A. Dameron, B.E. Hansen, S. Vahdani, D,\nMitchell and J. Paterson, Performance-based seismic upgrade of a 14-\nstory suspended slab building using state-of-the-art analysis and\nconstruction techniques, Proceedings of SEAOC 69th Annual\nConvention, Sacramento, California; 2000, pp.127-142.\n[13] D. Mar, and S. Tipping, Smart frame story isolation: a new highperformance\nseismic technology, 9th U.S.-Japan Workshop on the\nImprovement of Structural Design and Construction Practices, Victoria,\nBritish Columbia, Canada, 2000.\n[14] J.E. LUCO AND F.C.P. DE Barros, Control of the seismic response of a\ncomposite tall building modelled by two interconnected shear beams,\nEarthq. Eng. Struct. 27(1998) 205-223.\n[15] P. S. Timoshenko and M.J. Gere, Theory of Elastic Stability, McGraw-\nHill, New York, 1961.\n[16] K.K. Kapur, Vibrations of a Timoshenko Beam, Using Finite-Element\nApproach, J. Acoust. Soc. Am. 40 (1966) 1058-1063.\n[17] K.J. Bathe, Finite Element Procedure, Prentice-hall, Upper Saddle\nRiver, New Jersey, 1996.\n[18] I. A. Karnovsky and O. I. Lebed, non-classical vibration of arches and\nbeams: Eigenaluves and Egenfunctions, McGraw-hill, New York, 2004.\n[19] Hutchinson, J.R. (2001), Shear Coefficients for Timoshenko Beam\nTheory, J. Appl. Mech., 68(1), 87-92.\n[20] A.K. Chopra, Dynamics of structures: theory and applications to\nearthquake engineering, Upper Saddle River, New Jersey, 1995.\n[21] T.K. Datta, Seismic analysis of structures,John Wiley & Sons (Asia) Pte\nLtd., Singaore, 2010.\n[22] H. Fujitani and T. Saito, Devices for aeismic isolation and response\ncontrol, in: M. Higashino, and S. Okamoto (Eds.), Response Control\nand Seismic Isolation of Buildings, Taylor & Francis, London and New\nYork, 2006, pp.3-37.\n[23] C.P. Providakis, Effect of LRB isolators and supplemental viscous\ndampers on seismic isolated buildings under near-fault excitations, Eng.\nStruct. 30(2008) 1187-1198.\n[24] P. Komodromos, Seismic isolation for earthquake-resistant structures,\nWIT press, Ashurst Lodge, Ashurst, Southampton, SO40 7AA, UK,\n2000.\n[25] W.X Cheng, D.H. Yan, G.Y. Kang and J.J. Jiang, Concrete structure\nPart II: concrete structure design, China architecture & building press,\nBeijing, 2003.\n[26] GB50011-2010, Code for seismic design of buildings, Chinese\nArchitecture & Building Press, Beijing, 2010."]}

Published

2012