Vibrations transmitted from human hands to upper arm, shoulder, back, neck, and head

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Xu, Xueyan S.¹; Dong, Ren G.¹; Welcome, Daniel E.¹; Warren, Christopher¹; McDowell, Thomas W.¹; Wu, John Z.¹

Vibrations transmitted from human hands to upper arm, shoulder, back, neck, and head

Int J Ind Ergon. November 2017;62:1-12

© Published by Elsevier B.V.

Affiliations

¹Engineering & Control Technology Branch, National Institute for Occupational Safety and Health, 1095 Willowdale Road, Morgantown, WV 26505, USA
Abstract and keywords

Some powered hand tools can generate significant vibration at frequencies below 25 Hz. It is not clear whether such vibration can be effectively transmitted to the upper arm, shoulder, neck, and head and cause adverse effects in these substructures. The objective of this study is to investigate the vibration transmission from the human hands to these substructures. Eight human subjects participated in the experiment, which was conducted on a 1-D vibration test system. Unlike many vibration transmission studies, both the right and left hand-arm systems were simultaneously exposed to the vibration to simulate a working posture in the experiment. A laser vibrometer and three accelerometers were used to measure the vibration transmitted to the substructures. The apparent mass at the palm of each hand was also measured to help in understanding the transmitted vibration and biodynamic response. This study found that the upper arm resonance frequency was 7–12 Hz, the shoulder resonance was 7–9 Hz, and the back and neck resonances were 6–7 Hz. The responses were affected by the hand-arm posture, applied hand force, and vibration magnitude. The transmissibility measured on the upper arm had a trend similar to that of the apparent mass measured at the palm in their major resonant frequency ranges. The implications of the results are discussed.

Relevance to industry: Musculoskeletal disorders (MSDs) of the shoulder and neck are important issues among many workers. Many of these workers use heavy-duty powered hand tools. The combined mechanical loads and vibration exposures are among the major factors contributing to the development of MSDs. The vibration characteristics of the body segments examined in this study can be used to help understand MSDs and to help develop more effective intervention methods.

Keywords: Hand-arm vibration; Hand-transmitted vibration; Shoulder; Neck; Head
Links

DOI: 10.1016/j.ergon.2016.07.001

WoS: 000414879600001
History

Received: 2016-02-05

Revised: 2016-05-25

Accepted: 2016-07-01

Online: 2016-07-22

Cited Works (23)

Year	Entry
1995	Kihlberg S. Biodynamic response of the hand-arm system to vibration from an impact hammer and a grinder. Int J Ind Ergon. July 1995;16(1):1-8.
2015	Marchetti E, Sisto R, Lunghi A, Sacco F, Sanjust F, Di Giovanni R, Botti T, Tirabasso A. Hand-arm vibration transmissibility measurement for assessing hearing impairment. In: Proceedings of the 13th International Conference on Hand-Arm Vibration. October 13-15, 2015; Beijing, China.60-61.
1976	Pyykkö I, Färkkilä M, Toivanen J, Korhonen O, Hyvärinen J. Transmission of vibration in the hand-arm system with special reference to changes in compression force and acceleration. Scand J Work Environ Health. June 1976;2(2):87-95.
2013	Dong RG, Welcome DE, McDowell TW, Wu JZ. Theoretical relationship between vibration transmissibility and driving-point response functions of the human body. J Sound Vibrat. November 25, 2013;332(24):6193-6202.
2013	Dong RG, Welcome DE, McDowell TW, Wu JZ. Modeling of the biodynamic responses distributed at the fingers and palm of the hand in three orthogonal directions. J Sound Vibrat. February 2013;332(4):1125-1140.
2010	Adewusi SA, Rakheja S, Marcotte P, Boutin J. Vibration transmissibility characteristics of the human hand–arm system under different postures, hand forces and excitation levels. J Sound Vibrat. July 5, 2010;329(14):2953-2971.
2015	Xu XS, Dong RG, Welcome DE, Warren C, McDowell TW. An examination of an adapter method for measuring the vibration transmitted to the human arms. Measurement. September 2015;73:318-334.
2005	Marcotte P, Aldien Y, Boileau P-É, Rakheja S, Boutin J. Effect of handle size and hand–handle contact force on the biodynamic response of the hand–arm system under z_h-axis vibration. J Sound Vibrat. May 20, 2005;283(3-5):1071-1091.
1994	Pyykkö I, Färkkilä M, Inaba R, Starck J, Pekkarinen J. Effect of hand-arm vibration on inner ear and cardiac functions in man. Nagoya J Med Sci. May 1994;57(suppl):113-119.
2001	Mechanical Vibration: Measurement and Evaluation of Human Exposure to Hand-Transmitted Vibration, I: General Requirements. ISO Standard ISO 5349-1. [ISO Standard thesis]. Geneva, Switzerland: International Organization for Standardization; 2001.
2012	Welcome DE, Dong RG, Xu XS, Warren C, McDowell TW. An evaluation of the proposed revision of the anti-vibration glove test method defined in ISO 10819 (1996). Int J Ind Ergon. January 2012;42(1):143-155.
2013	Mechanical Vibration and Shock: Hand-Arm Vibration: Method for the Measurement and Evaluation of the Vibration Transmissibility of Gloves At the Palm of the Hand. ISO Standard ISO 10819. [ISO Standard thesis]. Geneva, Switzerland: International Organization for Standardization; 2013.
1967	Miwa T. Evaluation methods for vibration effect, III: measurements of threshold and equal sensation contours on hand for vertical and horizontal sinusoidal vibrations. Ind Health. 1967;5(3-4):213-220.
1977	Reynolds DD, Angevine EN. Hand-arm vibration, II: vibration transmission characteristics of the hand and arm. J Sound Vibrat. March 22, 1977;51(2):255-265.
2006	Dong RG, Welcome D., McDowell TW, Wu JZ. Measurement of biodynamic response of human hand–arm system. J Sound Vibrat. July 2006;294(3):807-827.
1968	Miwa T. Evaluation methods for vibration effect, VI: measurements of unpleasant and tolerance limit levels for sinusoidal vibrations. Ind Health. 1968;6(1-2):18-27.
1998	Bovenzi M. Exposure-response relationship in the hand-arm vibration syndrome: an overview of current epidemiology research. Int Arch Occup Environ Health. November 1998;71(8):509-519.
1995	Gurram R, Rakheja S, Brammer AJ. Driving-point mechanical impedance of the human hand-arm system: synthesis and model development. J Sound Vibrat. February 23, 1995;180(3):439-458.
1986	Sakakibara H, Kondo T, Miyao M, Yamada S, Nakagawa T, Kobayashi F, Ono Y. Transmission of hand-arm vibration to the head. Scand J Work Environ Health. August 1986;12(4):359-361.
2015	Tirabasso A, Botti T, Lunghi A, Di Giovanni R, Sacco F, Marchetti E, Cerini L, Sanjust F, Moleti A, Sisto R. Combined effect of noise and hand-arm vibration exposures on the cochlear function. In: Proceedings of the 13th International Conference on Hand-Arm Vibration. October 13-15, 2015; Beijing, China.84-85.
2015	Welcome DE, Dong RG, Xu XS, Warren C, McDowell TW, Wu JZ. An examination of the vibration transmissibility of the hand-arm system in three orthogonal directions. Int J Ind Ergon. February 2015;45:21-34.
2009	Dong RG, McDowell TW, Welcome DE, Warren C, Wu JZ, Rakheja S. Analysis of anti-vibration gloves mechanism and evaluation methods. J Sound Vibrat. March 20, 2009;321(1-2):435-453.
2008	Dong JH, Dong RG, Rakheja S, Welcome DE, McDowell TW, Wu JZ. A method for analyzing absorbed power distribution in the hand and arm substructures when operating vibrating tools. J Sound Vibrat. April 8, 2008;311(3-5):1286-1304.

Cited By (2)

Year	Entry
2019	Khalil HH, Rongong JA, Carré MJ. The effect of grip force on an upper arm under both continuous and shock vibration using the MDOF model. In: 54th UK Conference on Human Response to Vibration. September 24-26, 2019; Edinburgh, UK.
2021	Dong RG, Wu JZ, Xu XS, Welcome DE, Krajnak K. A review of hand–arm vibration studies conducted by US NIOSH since 2000. Vibration. 2021;4(2):482-528.