Ergonomical study regarding working in standing and seating postures.

Voinescu, Mihai ; Davidescu, Arjana ; Argesanu, Veronica 等

1. INTRODUCTION

Most studies related to human ergonomics and energy consumption in various postures are generally based on experimental determination and less on mathematical models. The ever improving area of software related to human ergonomics has given the possibility of further understanding of the actual activity in the muscles and the causes of fatigue. Such mathematical models can be used to optimize the overall processes that involve certain human body postures for prolonged periods of time and thus give better productivity and less fatigue or perhaps distribute fatigue evenly and reduce the risk of certain "professional" back and shoulder disorders.

Such mathematical model research has been done mostly in the automotive industry for the purpose of obtaining optimal seating conditions for the average population of certain areas, but the importance of studying human body mechanics goes far beyond and can extend to any field in which involves human operators.

Regarding the working environment in the field of the dental physician, most data available on ergonomics is based on observation and on personal experience of the physicians themselves. Most of the work-related physical problems are, in general, only discovered after the harm has already been done and in most cases the need for resting the damaged muscles and tending to the affected part leads to the need of a certain period of less to no activity for the physician. (Hokwerda et al., 2007).

Because of these problems, a great deal of research has been made on the mechanics that cause fatigue and pain in different muscle groups. Doctor Oene Hokwerda's work in the field of ergonomics for dental medicine is impressive and offers a great deal of information regarding the correct theoretical postures and on the possible injuries that might occur over a prolonged period of time.

2. GENERATING HUMAN BODY MODEL POSTURES AND PRELEVATION OF DATA

The major problem in such an undertaking is building a suitable virtual environment and most of all an accurate model of the human body. Because of this, the models used have been selected from human physiques that Aalborg University has previously constructed, with precise muscle definition and insertion points for applications that involve human movement.

[FIGURE 1 OMITTED]

All these models are available in the standard demo package that can be used in conjunction with the ANYBODY human body simulation software. Starting from a standing human model, using pre-defined muscles and bone attachments, and building both seated position and standing position scenarios, eight simulated situations, five seated and three standing have been developed.

For the seated position, the chair was added virtually through a node that offers a stabile platform for the pelvis region. The angles for the legs were obtained from an ideal theoretical position for the purpose of minimising their involvement in the general muscle activity of the body system.

The work space of the arms was obtained from measurements of rotation and position during the physician's activity (Hokwerda et al., 2005). All simulated positions have been designed for similar hands and shoulders activity. The overall angle differences for the hands in the eight simulations is minimised so that the general difference in the total muscle activity is given by the other muscles. This allows for a clear view of the influence of the different postures on the system.

All activities include certain tensions in the hands given by an external load. Because of this factor, all models have forces attached to the nodes belonging to each of the hands. This ensures that the data output is similar to that which would be obtained from a real life model and further adds to the accuracy of the model.

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Generally, all postures considered have the same work routine and are designed in such a way that only the patient's position changes and the body model has to adapt to that change. As such, certain positions required a change in posture to ensure proper balance. A few of the models required a certain adjustment of the position of the knee; for this purpose, a rotation of the upper part of the legs was conducted. For this rotation, the outward rotation angles were considered positive and those inward negative.

All movement patterns were carefully studied for muscle collision and kinematical correctitude; after all data was considered viable, the next phase of the study--using inverse dynamics, was conducted. The data was then extracted from the output of the program for the various muscle groups that were of interest (shoulders and arms, legs, general muscle activity). The most relevant data was considered the overall muscle fatigue per cycle investigated; in this way, a clear analysis of the movement can be done referring to all muscles and not just individual parts of the body model. Muscle fatigue (Activity) is defined by the ANYBODY solver as muscle force divided by strength (anybodytech.com, 2007).

Some extreme situations were taken into consideration to allow the prelevation of data regarding object placement in the work space (Hokwerda, 2008); seated body rotations for various reaches left and right. The data was taken in a fixed time interval of 10 seconds per movement and the data can be multiplied by the assumed times a physician has to repeat the same move, giving us an overall muscle activity per work day.

One very important aspect of this study is the taking into account of the feet in the positioning of the body and thus, its equilibrium. Most previous work disregards leg muscles because of the seated position, but, as the results show, these muscles are not entirely inactive while seated and play a great role in equilibrium particularly in positions involving lateral bending of the trunk. The muscle models used are both simple and Hill-type muscles. Previous work (Dragulescu, 2005) has shown the advantages of Hill-type muscle models over the simpler models that only take into consideration the presumed strength of the muscle; for this reason, the leg muscles have been selected as Hill-type to better model their involvement in the movement.

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3. RESULTS AND CONCLUSIONS

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After a careful examination of the data and statistical analysis, a clear distinction between the energy consumption for seated compared to standing position became apparent. Even the extreme positions offered better energy consumption and less stress for the back and shoulders for most of the movement. Clearly the seated position is better in regard to the overall energy consumption, as was indicated by previous work.

The data resembles the results of previous studies done by observation of real situations and is both a validation for previous work and an improvement of the available data. Furthermore, by using the general data from each of the eight movement paths investigated, a maximum allowed bending and rotation of the thorax can be established. The drawback of the method is the lack of experimental investigation using real life subjects.

Additional studies can be conducted by replicating the motion trajectories using test subjects and heat sensors to detect muscle activity from the thermal variations in the body. The final result of further study can be the improvement of the layout of dental equipment in the dentist's workspace. The numerical model obtained can also be used to read data from various muscle groups, determine better work trajectories, and perhaps even ergonomically improve the way certain tools are gripped and handled.

Another aspect of the study is the possibility of pointing out the individual muscle strain for the various shoulder and arm muscles. The impact of such data can lead to improvement of movement ergonomics and development of specific work training that can relieve the tension generated during certain stages of physical activity.

4. REFERENCES

Dragulescu, D. (2005). Modelarea in Biomecanica, Editura Didactica si Pedagogica, ISBN 973-30-1725-6, Bucuresti

Hokwerda, O (2008). Ergonomic objections against a unit-cart on the right or left side of the patient chair, Available from: www.esde.org/docs/ergonomic_objectioins_against_a_unit _or_cart_next_to_patient_cha.pdf Accessed: 2009-01-25

Hokwerda, O.; Wouters J. & de Ruijter, R. (2007). Ergonomic requirements for dental equipment, Available from: www.optergo.com/images/Ergonomic_req_april2007.pdf Accessed: 2009-01-15

Hokwerda, O.; de Ruijter, R. & Zijlstra-Shaw, S. (2005). Adopting healthy sitting posture during patient treatment, Available from: www.optergo.com/uk/images/Adopting.pdf Accessed: 2009-01-14

*** (2007) www.anybodytech.com/index.php?id=691--ANYBODY technology tutorials, inverse dynamics analysis, Accesed on: 2009-03-20

Tab. 1. Major rotational angles

Pos. Thorax Thorax Knee
 rotation bending adjustment

1 70[degrees] 0[degrees] 3[degrees]
2 70[degrees] 30[degrees] 6[degrees]
3 0[degrees] 30[degrees] 3[degrees]
4 0[degrees] 45[degrees] 10[degrees]
5 45[degrees] 25[degrees] -10[degrees]
6 20[degrees] 40[degrees] 1[degrees]
7 30[degrees] 50[degrees] 2[degrees]
8 0[degrees] 40[degrees] 1[degrees]

Pos. Max. Seated
 Activity Yes/No

1 0,39 Yes
2 0,98 Yes
3 0,31 Yes
4 0,36 Yes
5 0,55 Yes
6 0,40 No
7 0,44 No
8 0,33 No