Abstract
Vibration serviceability of timber floors is becoming increasingly relevant due to their increased long-span applications in pure timber and hybrid structures. As a serviceability limit state, the check of acceptable floor vibrations is part of some current timber design standards. However, a universal agreement on acceptance levels and design procedures has not been achieved. This paper gives an overview of traditional and recent design approaches for floor vibrations, with those approaches intended to allow engineers to implement design strategies that produce floors that perform acceptably under service conditions. The subsequent discussion does not catalogue all relevant technical literature, information in design manuals and aids, nor list all relevant design code rules related to vibration serviceability of timber floors. Instead what is written is intended to convey and critique the state of background knowledge, design recommendation and code rules using illustrative examples from the literature. The objective is to contribute to resolution of debate about control of floor response characteristics by engineering design methods.
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References
APA (2004) Minimizing floor vibrations by design or retrofit, Technical Note 70, APA-The Engineered Wood Association, Tacoma, USA
BSI (1984) Evaluation of human exposure to vibration in buildings (1 Hz to 80 Hz), British Standard BS6472, British Standards Institute, London, UK
CEN (2004) Comité Européen de Normalisation (CEN) Eurocode 5—design of timber structures, part 1-1: general—common rules and rules for buildings. EN 1995-1-1:2004 (E), English version, British Standards Institution, London, UK
Chui YH (1986) Evaluation of vibrational performance of light-weight wooden floors: method of assessment of floor vibration due to human footsteps, Research Report No. 3/86, Timber Research and Development Association (TRADA), High Wycombe, UK
Chui YH (1987) Vibrational performance of wooden floors in domestic dwellings. Ph.D. Thesis, Brighton Polytechnic, Brighton, UK
Chui YH, Smith I (1990) A dynamic approach for timber floor design. N Z J Timber Constr 6(1):9–10
CWC (1997) Development of design procedures for vibration controlled spans using wood members, Concluding Report, Canadian Construction Materials Centre and Consortium of Manufacturers of Engineered Wood Products Used In Repetitive Member Situations, Canadian Wood Council, Ottawa, Canada
Dolan JD, Murray TM, Johnson JR, Runte D, Shue BC (1999) Preventing annoying wood floor vibration. J Struct Eng 125(1):19–24
Fitz M (2008) Untersuchung des Schwingungsverhaltens von Deckensystemen aus Brettsperrholz (BSP), Master thesis, Graz: Technical University of Graz
Hamm P, Richter A, Winter S (2010) Floor vibrations—new results. In: Proceedings of 10th world timber engineering conference 2010, Lago di Garda, Italy
Homb A (2006) Low frequency sound and vibrations from impacts on timber floor constructions, Ph.D. Thesis, Norwegian University of Science and Technology, Trondheim, Norway
Hu LJ (1992) Prediction of vibration responses of ribbed plates by modal synthesis, Ph.D. Thesis, University of New Brunswick, Fredericton, Canada
Hu LJ (2000) Serviceability design criteria for commercial and multi-family floors, Canadian Forest Service Report No. 4, Forintek Canada Corp, Sainte-Foy, Canada
Hu LJ, Chui YH (2004) Development of a design method to control vibrations induced by normal walking action in wood-based floors. In: Proceedings of 8th world conference on timber engineering, Lahti, Finland
Hu LJ, Gagnon S (2011) Vibration performance of cross-laminated timber floors. In: Gagnon S, Pirvu C (eds) CLT handbook: cross-laminated timber. FPInnovations, Québec
Hu LJ, Tardif Y (1999) Effects of partition walls on vibration performance of engineered wood floors. In: Proceedings of international RILEM symposium on timber engineering, Stockholm, Sweden
IRC (2010) National Building Code of Canada, National Research Council of Canada, Institute for Research in Construction, Ottawa, Canada
ISO (1989) Evaluation of human exposure to whole-body vibration, Standard ISO 2631-2 International Standards Organization, Geneva, Switzerland
Jarnero K (2014) Vibrations in timber floors: dynamic properties and human perception, Dissertations No 195/2014, Linnaeus University, Växjoe, Sweden
Jarnero K, Brandt A, Olsson A (2015) Vibration properties of a timber floor assessed in laboratory and during construction. Eng Struct 82:44–54
Khokhar A (2004) Influence of bracing stiffness on performance of wooden floors, M.Sc. Thesis, University of New Brunswick, Fredericton, Canada
Khokhar A, Chui YH, Smith I (2012) Influence of stiffness of between-joists bracing on vibrational serviceability of wood floors. In: Proceedings of world conference on timber engineering, Auckland, New Zealand
Leissa A (1969) Vibration of plates, Report SP-160, National Aeronautics and Space Administration, Washington DC, USA
Ohlsson SV (1982) Floor vibrations and human discomfort. Division of Steel and Timber Structures, Chalmers University of Technology, Sweden
Ohlsson SV (1988a) Floor vibration serviceability and the CIB model code, Conseil International du Bâtiment (CIB). In: Proceedings of CIB meeting Working Commission 18, Paper 21-8-2, Rotterdam, The Netherlands
Ohlsson SV (1988b) Springiness and human induced floor vibration: a design guide, Document No. D 12-1988, Sweden Council for Building Research, Stockholm, Sweden
Ohmart RD (1968) An approximate method for the response of stiffened plates to a periodic excitation, Ph.D. Thesis, University of Kansas, Lawrence, USA
Onysko DM (1985) Serviceability criteria for residential floors based on a field study of consumer response, Project Report 03-50-10-008, Forintek Canada Corp, Ottawa, Canada
Polensek A (1985) Structural damping and its effect on human response to floor vibrations. Forest Research Laboratory, Oregon State University, Corvallis
Schickhofer G, Bogensperger T, Moosbrugger T (2009) Holz-Massivbauweise in Brettsperrholz: Nachweise auf Basis des neuen europäischen Normenkonzepts, (Solid timber construction with CLT: proof on the basis of the new European concept of standards) (In German) Technische Universität Graz, Austria
Smith I, Chui YH (1988) Design of lightweight wooden floors to avoid human discomfort. Can J Civ Eng 15:254–261
Smith I, Chui YH (1991) On the possibility of applying neutral vibrational serviceability criteria to joisted wood floors. In: Proceedings of CIB meeting Working Commission 18, Paper 24-8-1, Rotterdam, The Netherlands
Smith I, Hu LJ (1993) Prediction of vibration serviceability of ribbed plates by modal synthesis. In: International Association for Bridge and Structural Engineering, Reports, 69, pp 243–250
Smith I, Hu LJ, Schriver AB (1993) Free flexural vibration analysis of one-way stiffened plates by the free interface modal synthesis method. Can J Civ Eng 20(6):885–894
Smith I, Thelandersson S, Larsen HJ (2003) Vibration of timber floors—serviceability aspects. In: Thelandersson S, Larsen HJ (eds) Timber engineering. Wiley, Chichester, pp 241–266
Toratti T, Talja A (2006) Classification of human induced floor vibrations. J Build Acoust 13(3):211–221
Ussher E, Smith I (2015) Predicting vibration behaviour of cross laminated timber floors. In: Proceedings of IABSE conference on elegance in structures, Nara, Japan
Weckendorf J (2009) Dynamic response of structural timber flooring systems, Ph.D. Thesis, Edinburgh Napier University, Edinburgh, UK
Weckendorf J, Smith I (2012a) Dynamic characteristics of shallow floors with cross-laminated-timber spines. In: Proceedings of world conference on timber engineering, Auckland, New Zealand
Weckendorf J, Smith I (2012b) Multi-functional interface concept for high-rise hybrid building systems with structural timber. In: Proceedings of the world conference on timber engineering, Auckland, New Zealand
Weckendorf J, Hafeez G, Doudak G, Smith I (2014) Investigations of nature of floor vibration serviceability problems in wood light-frame buildings. J Perform Constr Facil 28(6):A4014003
Zhang B, Rasmussen B, Jorissen A, Harte A (2013) Comparison of vibrational comfort assessment criteria for design of timber floors among the European countries. Eng Struct 52:592–607
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The support of this project by COST Action FP 1004 is gratefully acknowledged.
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Weckendorf, J., Toratti, T., Smith, I. et al. Vibration serviceability performance of timber floors. Eur. J. Wood Prod. 74, 353–367 (2016). https://doi.org/10.1007/s00107-015-0976-z
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DOI: https://doi.org/10.1007/s00107-015-0976-z