For all the interventions, an ergonomics committee (called an ergo group) was set up at the start of the project. Its core of approximately five people consisted of workers and technical specialists who, depending on the company, were mechanics or engineers. Resource persons could be added to this core for some steps in the process. The ergo groups’ work was mainly carried out during meetings, but it also included fieldwork such as interviews with workers, video recordings, and field tests to perfect solutions. An intervention lasted 18 to 24 months, during which time the ergo groups analyzed three or four work situations. The groups met from eight to twelve times to analyze a job in the case of repetitive tasks, and from twelve to fifteen times to analyze a varied task.

Training consisted of an initial relatively formal step in which the ergo group received theoretical training and then did an initial job analysis. The aim of the theoretical training, which varied from 14 to 24 hours depending on the intervention, was to teach the basics and objectives of ergonomics and WSMD-related anatomical and physiological concepts, and to explain the main risk factors, as well as to pass on information about the mandate and role of the members of the ergonomics group. During this initial training, the job analysis tools used were outlined. With the ergonomists’ help, the ergo group focused on hazardous work situations. The entire process was demonstrated in an initial complete study closely guided by the two ergonomists.

The second step in training was interactive, involving a type of mentorship system. Indeed, beginning with the second job, the members of the ergo group were responsible for conducting the meetings and all of the steps in the job analysis process. However, one ergonomist attended each ergo group meeting, but solely in a supporting role in order to answer the participants’ questions and to intervene as needed to fill in any gaps. The expectation was that this ergonomist would intervene less and less. A second ergonomist also attended the meetings but this was mainly to document the progress.

Training therefore took several forms with several objectives: the acquisition of basic knowledge about WMSDs, risk factors and the core concepts of ergonomics; the development of a certain ability to understand the work activity as it is carried out, as well as the variability and the determinants; promoting the integration of the viewpoint and knowledge of several people, including the workers doing the job studied; and the development of multiple solutions and their critical analysis.

A major concern in these projects was to be able to identify the aspects in the process and tools developed that needed improvement. Of the different possible options, one approach in this diagnosis was to analyze the difficulties encountered in learning the proposed analytical methods.

However, analyzing the interactions between the participants and ergonomists during numerous work meetings is a very cumbersome and difficult undertaking. A methodological tactic was therefore used: we assumed that an analysis of the active ergonomist’s interventions during the meetings would provide information on the difficulties encountered by the groups’ participants and we therefore focused the analysis on these interventions. The ergonomist intervened to fill in any gaps, answer questions, and give explanations so that the concepts could be understood. The ergonomists’ interventions during these meetings were recorded, and then transcribed and recoded for the purposes of analysis (St-Vincent et al. 1996a, 2000). The analysis of these interventions was further developed in the project on non-repetitive tasks, so that the two plants studied could be compared. The ergonomist also had to assess whether or not the participants successfully applied each of the steps.

The entire process is summarized in table 1: the planned steps, the means proposed, and the people involved.

The first step consisted of collecting preliminary information through interviews with the foreman and several workers doing the job. The group had a simple questionnaire to give to the workers and supervisors. A summary sheet summarized the information so that it could be presented to the group.

The second step—one of the most original aspects in our process— consisted of establishing a sampling plan to determine which workers and production conditions or work situations would be observed or filmed. The proposed tool presents basic guiding principles in the choice of situations and workers to be filmed.

The third step consisted of breaking down the filmed activity into smaller units or actions and of identifying the risk factors using an analytical grid. This risk-factor identification step has generated the most proposals in the literature, ranging from the simplest (e.g., checklists, binary response as presence/absence; Braun 1992; Lifshitz and Armstrong 1986, Kemmlert 1995) to the more complex (e.g., analytical grids, evaluation of the duration or frequency of risk factors; Keyserling et al. 1992, 1993; Li and Buckle 1998). In the present case and similar to other authors (Armstrong et al. 1982; Braun 1992; Reynolds et al. 1994), the grid developed was specific to repetitive work and was based on a prior breakdown of the cycle into actions and then, for each action, the identification of the different risk factors as commonly recognized in the literature (e.g., posture, force, presence of mechanical pressure). This grid is very similar to that of Braun (1992), but with a few additions. In our approach, the risk factors were systematically documented, but no quantification effort was required of the participants.

The aim of the fourth step was to prioritize the problems before starting to identify the determinants. This step involved ranking the most hazardous actions within a given task; in other approaches, prioritization may instead involve ranking each job in relation to the others. The literature contains many attempts to quantify the establishment of priorities. This quantification might involve calculating an overall rating that is based on the sum of the positive responses to the questions in a checklist (Lifshitz and Armstrong 1986), or weighted according to the exposure duration or frequency (Keyserling et al. 1992, 1993; Li and Buckle 1998). The aim of the overall rating is therefore to situate one job in relation to others and/or to identify the jobs that must be analyzed in greater detail. For example, Reynolds et al. (1994) proposed a formula based on frequency, posture, and force requirements, while McAtamney and Corlett (1993) suggest an overall rating calculation that integrates different tables of ratings. As the authors themselves emphasized, the scientific bases for the quantification methods are not always clear. However, in order to be used correctly, these quantitative approaches require the implementation of a systematic observation process, which, to be reliable, requires observation-specific training (Denis et al. 2000). A qualitative approach, based on the understanding and integration of several sources of information, therefore seemed more appropriate. The criteria given to the participants for establishing their priorities were simply to take into account risk factor characteristics (intensity, duration, frequency), reported pain and the workers’ perceptions.

The fifth step was the identification of the determinants for the different risk factors observed. Different classes of determinants to be investigated are proposed: working tools, work method, material feed, dimensions of a workstation and work organization. This step is rarely identified in the grids proposed, but is typical of a work analysis process.

The sixth step involved solution-finding. Technical specialists were then invited to join the group. As previously mentioned, this aspect is not extensively dealt with in approaches involving WMSDs. We attempted to formalize this step and we structured it into four additional steps. The first proposes using brainstorming techniques to generate a wide range of solutions. The second step consists of organizing the different ideas presented into solution scenarios. Then, through discussion, solution proposals are sought for some aspects of the job, rather than independent solution elements. Two or three scenarios can be developed by the different group members. These scenarios are then critically analyzed. For example, does the solution actually correct the targeted problem? If so, is the solution economically and technically feasible? Will it be compatible with the workers’ work methods and characteristics? Could it have negative impacts on the jobs upstream or downstream? Finally, the fourth step, the detailing of solutions, is done using a summary sheet identifying the tasks to be performed. Several means are proposed: mock-ups, scale drawings and field simulations.

The final step is solution implementation and follow-up. Steps to be followed are proposed, as well as a summary sheet. Similar to Keyserling et al. (1991) and Reynolds et al. (1994), prototypes are recommended whenever possible before the final implementation of solutions.

The approach is articulated around the ergo group but importance is given to the workers in the jobs studied. Therefore, each time that a specific job is analyzed, one or two workers doing the job join the ergo group for the duration of the job analysis. At different times in the process, other workers doing the job are involved. At the beginning of the analysis, workers are questioned and some of them, or others, are then filmed. Throughout the solution-finding process, the workers doing the job are informed about the progress in the work. During the field tests, the workers are consulted and, finally, when a prototype is implemented, the members of the ergo group ask for an assessment by the workers doing the job.

The detailed results of the difficulties encountered by the participants from two companies in the electrical products sector are presented in another publication (St-Vincent et al. 1996a); only the highlights are reported here.

These ergonomic interventions in two other companies in the metal products sector were carried out after those described above. Plant 1 was a small economically healthy company, with a participatory culture and cordial work relations. Plant 2, on the other hand, had serious economic problems, work relations were strained, and there was no participatory culture. As will be seen, the method was modified on the basis of the knowledge acquired from previous projects, but mainly to take into account the new context of varied tasks. In fact, the analysis of varied (non-repetitive) tasks introduced two new major methodological difficulties: sampling, and risk factor interpretation.

Sampling. When a repetitive task is analyzed, a rather representative picture of the work carried out can be obtained by questioning the worker about the variations in his work and by filming a few work sequences. With non-repetitive work, it is more difficult to have a representative picture of the work carried out: the cycles are longer (when there are any) and there can be several work sites and different equipment and layouts. Knowing what to film is the initial challenge and requires a good prior understanding of the work.

Interpretation of risk factors. It is recognized that the severity or impact of a risk factor depends on its dose, which is evaluated by three parameters: duration, amplitude or intensity, and frequency. These are more difficult to estimate in the case of non-repetitive tasks, requiring a lot of time. In addition, even if the duration, intensity and frequency are known, the results can be difficult to interpret because the literature does not always give precise reference values. Evaluating a risk factor’s dose is clearly beyond the competence of a participatory working group.

To get around these two difficulties characteristic of varied tasks, two steps were significantly modified: the collection of preliminary information through interviews and the analysis of video sequences.

With repetitive work, one of the goals of the preliminary interviews was to document the sources of variations. For varied (non-repetitive) work, these interviews were refocused on the identification of the different operations, layouts, tools, equipment and material used, and also the perceived difficulties. The “sampling plan” step was consequently retained but the guideline was simply that the sample be representative of the situations that the workers identified as the most difficult.

Video analysis. A grid (see table 2) was developed. The breakdown into actions was replaced by a breakdown into operations, which are larger entities that encompass more actions and movements. They correspond to the major steps in production. The identification of WMSD risk factors is retained, without quantification, and the risks of injuries, such as falls or cuts, have been added. The major difference is that the group members now had to identify the difficulties and the determinants of the problems. The concept of difficulty is related to any element that presents a problem in work execution. The descriptions of the difficulties are expressed freely, which implies that the members of the group have acquired an understanding of the concept of difficulty as well as master a basic typology of these difficulties. A guide given to the participants presents a typology of possible difficulties with examples: tools, equipment, physical layout, material, incidents/contingencies, knowledge/work method, etc. The participants do not have to rank the different difficulties identified. In fact, at this stage, the video analysis is mainly a means of helping the participants to verbalize more openly about the difficulties identified. The proposed grid is therefore more elaborate than the first one developed for repetitive tasks and risk factor identification is no longer the central focus. An example is presented in table 3. It describes the difficulties associated with an operation involving the threading and attaching of strips of scrap metal. Clarification of the problem and activity provides information about the determinants, or at least makes them easier to identify. Solution-finding is consequently easier.

In the case of varied tasks, the approach chosen for video analysis generated an analytical method much less linear than for the analysis of repetitive tasks. The approach developed is now more similar to the systemic approaches widely used on the francophone literature. Information on the activity can therefore be more easily collected. In contrast, this information emerged less during the analysis of repetitive tasks, since the participants were basically focused on observing postures, the degree of effort and the presence of mechanical pressures.

Training problems within the context of participatory processes implies two types of solutions: developing processes and tools that are learning tools, and improving the quality of learning. The job analysis tools formalized here were learning tools for the participatory groups. By using video material for non-repetitive tasks and by focusing on the identification of difficulties, the participants were therefore able to assimilate relatively spontaneously and concretely the difficult concepts of activity and determinant.

For participatory processes, effective strategies must be found because the time available is a major constraint. In this respect, a progressive learning formula proved effective. The participants pursue their learning in an application context, and they can see the results of their actions in a reasonable amount of time. Since the situations analyzed differ, this encourages the development of transfer skills. It is important, however, that the ergonomist orient the choice of initial jobs studied towards situations with a reasonable level of complexity. This requires a relatively long follow-up: two ergonomists attended all the meetings for about two years. At the end of the process, the degree of autonomy achieved varied by case. For the cases involving repetitive work, a clear evolution was observed in the two plants, even though full autonomy was not achieved. In the cases involving varied tasks, the results contrast greatly. In one plant, a very good level of autonomy is achieved, while in the other, the level of autonomy is very low.

The results of these projects are difficult to generalize because of the variation in the plants and in the type and degree of difficulty in the work situations analyzed. The groups’ dynamics also depended in part on their composition, which was somewhat unpredictable. The results, however, provided pertinent information about the difficulties that can be encountered and about what can be expected from such groups.

The tactic used here, namely the analysis of the ergonomists’ interventions, proved to be an interesting way of dealing with the difficulties encountered by the participants. However, it is clear that the interventions also reflected the ergonomists’ reaction to how these meetings were progressing. The ergonomists’ interventions were modulated by at least three factors: what was felt to be important, what was thought to be a deficient, and by the experience with participatory groups. Very experienced ergonomists were involved here, both in job analysis and interactions within groups of workers. The work experience gained in participatory groups undoubtedly facilitated the process.

The results also show that the difficulties are contextual and that the processes and tools used must be adapted. Therefore, in the context of repetitive work, taking variability into consideration was the most difficult aspect. It is a concept that may in fact seem paradoxical in the case of short-cycle tasks since it was difficult to formalize precisely. For non-repetitive tasks, variability caused fewer difficulties, contrary to expectations. However, the time problem became important.

The method of linear and structured analysis in distinct steps worked well with repetitive tasks. In both plants, the participants clearly evolved even though, by the end of the project, complete autonomy was not achieved. However, at the end of the study, the participants used the different steps properly (St-Vincent et al. 1996a). This structuring of the process has been identified as a condition for a successful participatory process (St-Vincent and Chicoine 1996b). However, this process seemed inappropriate for non-repetitive tasks. The process adopted remained structured but the video analysis step became much more open. With this process, a good degree of autonomy was observed in plant 1 at the end of the project, with a proper use of the various steps. In plant 2, autonomy was less clear-cut. The participants did not do the filming themselves, and in the video analysis step, they did not discuss the methodology, but instead blamed the workers and wanted to limit solution-finding to questions of physical load, ignoring safety problems. The video analysis step was therefore not used as planned and, in this plant, did not really involve questioning the activity, difficulties and determinants. In addition, during the solution-finding, there was very little discussion about critical analysis of solutions. The purpose of the ergonomists’ interventions was instead to help the participants specify the solutions and to encourage collaboration with the engineers.

Therefore, in plant 2 the different steps in the tool were not used as planned and, at the end of the project, complete autonomy had not really been achieved. With varied tasks, particularly with an open approach in the video analysis, autonomy can be considered as being more difficult to achieve by an ergo group and only possible in the case of an optimal company context, as was the case for plant 1. However, because of the very good results obtained in one of the plants, particularly in the level of understanding of the work activity by the participants, the concepts retained for non-repetitive tasks (an open method not focused on the identification of risk factors) could have been considered an interesting strategy, even in the case of repetitive tasks.

Some of the difficulties encountered in plant 2 seem to be directly related to this company’s context and specific culture (St-Vincent et al. 2000). It was noted that the participants had inadequate representations of the fundamentals and objectives of ergonomics and that they wasted a lot of energy blaming their peers. These problems can be explained by a lack of employee recognition by management and by marked difficulties in work relations. Communication problems may have been the reason for the participants’ reluctance to collaborate with the company’s engineers. This suggests that the use made of the ergonomic analysis tools is affected by company culture phenomena, which should be better understood. Although company culture may affect the results, the effect of individual factors cannot be denied. In our study, the participants’ professional skills were similar, but other characteristics such as the ease in working as a team, receptiveness to new approaches, and the ability to listen are characteristics that helped explain the differences between the two plants. This prompts us to think that the desired characteristics of the members of the ergo groups should be better defined.

As has been seen, there is a significant difference in the way videos are analyzed for repetitive tasks and varied tasks. The more open method used for varied tasks, which was based on free expression by the participants, seemed to provide richer information for understanding the activity and for finding solutions, in contrast to a systematic identification of the risk factors as was the case for repetitive tasks. The open method was effective for solution development.

However, the open approach used for varied tasks leads to a major problem in following up on the solutions implemented. The aim during follow-up is to demonstrate that the solutions improved the work and reduced the risk factors. For varied tasks, there was no initial systematic analysis of the risk factors and it was therefore difficult to assess the impact of the solutions in this regard. Follow-up was therefore based on interviews with the workers doing the job for the purpose of verifying that the problems identified during the video analysis had actually been improved. There was also an expert’s assessment of the severity of the risk factors present, based on the videos, which was also subjective information. No systematic data were therefore obtained on the impact of the solutions on the severity of the risk factors, which is clearly a major deficiency. This was not the case for repetitive tasks, where systematic data were obtained for evaluating the impact of the solutions on the risk factors (St-Vincent et al. 1996a, 1998).

This leads to more general conclusion about the follow-up or evaluation of an ergonomic intervention. Our projects on varied tasks have shown that a systematic risk analysis was not necessary to proceed with the intervention. This raises the question of pertinent data for validating the solutions resulting from an ergonomic intervention. A systematic analysis of risk factors in the case of varied tasks is known to be demanding in terms of time. The work must be sampled, and the duration, frequency and amplitude of the different risk factors must be quantified. Furthermore, such systematic risk analyses, contrary to ergonomic work analysis, do not provide information about work-related difficulties and constraints nor about the work execution conditions. Thus a before-after evaluation focused solely on a detailed risk analysis provides very little information about the aspects of the work that were actually improved. To properly evaluate an ergonomic intervention using reasonable means, we should probably differentiate it from the classical epidemiological model and rethink our approach. An interesting avenue for evaluating solutions is to use systematic perception data to measure the before-after changes. Workers can therefore be asked to rank, using a perception scale (from 1 to 5), the variations in the difficulty factors identified during the job analysis, particularly in the physical effort and postural stresses. For a more complete evaluation, it would be useful to complement these perceptual data with biomechanical measurements appropriate to the work situations analyzed. However, although perceptual data are realistic for ergo groups, biomechanical measurements require an even more expert context.