Omnidirectional assessment of one-handed manual strength at three handle heights.

Maximal right-handed omnidirectional strengths of eleven males were measured at three handle heights of 1.5 m, 1.0 m and 0.5 m using the Tri-Axial Force measurement System. The postures of the subjects were constrained by preventing rotation of the footbase in order to ensure that the forward-backward and leftward-rightward axes of the subject remained constant relative to the measurement system. A two-way repeated measures analysis of variance revealed highly significant differences in maximal strengths between the three heights and the 614 directions of exertion measured. A highly significant interaction was found between height and direction. At all three hand heights a restricted area of great strength was found in the direction of upward and almost directly forward from the subject. A second, less powerful, but more widespread area of high strength was also found at each height. At the 1.5-m height the peak was in the backward and almost vertically downward area. At the 1.0-m height the peak was in the area of slightly downward and largely backward. At the 0.5-m height the peak was to the right of upward and backward. RELEVANCE: Very few real-life manual exertions involve forces which are purely in the sagittal, forward-backward plane, with lateral components of force usually being involved as well. The data presented extend the knowledge base about male one-handed strengths.

[1]  M. M. Ayoub,et al.  Problems and solutions in manual materials handling: the state of the art , 1992 .

[2]  William S. Marras,et al.  Three dimensional dynamic motor performance of the normal trunk , 1990 .

[3]  D. Grieve,et al.  Human strength capabilities during one-handed maximum voluntary exertions in the fore and aft plane. , 1991, Ergonomics.

[4]  H Rühmann,et al.  Human strength: measurements of maximum isometric forces in industry. , 1989, Ergonomics.

[5]  A Schultz,et al.  Maximum voluntary strengths of male adults in some lifting, pushing and pulling activities. , 1980, Ergonomics.

[6]  Don B. Chaffin,et al.  Volitional Postures during Maximal Push/Pull Exertions in the Sagittal Plane , 1983 .

[7]  A Garg,et al.  Revised NIOSH equation for the design and evaluation of manual lifting tasks. , 1993, Ergonomics.

[8]  S T Pheasant,et al.  The principal features of maximal exertion in the sagittal plane. , 1981, Ergonomics.

[9]  D W Grieve Environmental constraints on the static exertion of force: PSD analysis in task-design. , 1979, Ergonomics.

[10]  S H Snook,et al.  The design of manual handling tasks: revised tables of maximum acceptable weights and forces. , 1991, Ergonomics.

[11]  D W Grieve,et al.  System for the triaxial measurement of manual force exertions. , 1993, Clinical biomechanics.

[12]  Walter Rohmert Maximum Forces Exerted by Men in the Zone of Movement of the Arms and Legs , 1975 .

[13]  Anil Mital,et al.  Manual Materials Handling , 1989 .

[14]  D W Grieve,et al.  Protocol for the omnidirectional assessment of manual strength. , 1993, Clinical biomechanics.

[15]  D W Grieve The postural stability diagram (PSD): personal constraints on the static exertion of force. , 1979, Ergonomics.

[16]  D W Grieve,et al.  Relationships between one-handed force exertions in all directions and their associated postures. , 1995, Clinical biomechanics.

[17]  S T Pheasant,et al.  Vector representations of human strength in whole body exertion. , 1982, Applied ergonomics.

[18]  K. H. Eberhard Kroemer Horizontal push and pull forces: exertable when standing in working positions on various surfaces. , 1974 .

[19]  D W Grieve,et al.  The measurement and prediction of isometric lifting strength in symmetrical and asymmetrical postures. , 1992, Ergonomics.

[20]  D W Grieve Slipping due to manual exertion. , 1983, Ergonomics.