The five crews and foremen of the machine line form the collective subject of paper making. They are therefore the main subject of the development and learning process as well. During the program, each crew and its foreman work as a group externalizing its own models of the parts of the work process. During this process the crews learn to use all the knowledge available in the group. The models constructed are verbalized representations of the work process, and they are written down in a file, in order to allow all the group members to follow the development of the group’s thinking and to compare their own models to the final models drawn up on the basis of the models of all five crews, and of the discussions in the large groups.

The production manager and the production engineer of the production process, the experts of process chemistry, the experts of automatic operation system engineering, and the marketing officer participate in the development program discussions on the basis of their own expertise. Their role is twofold. On the one hand, they are part of the work community, and broadly speaking the subject of paper production, and therefore they must participate in the development of those phases of the entire production process with which they work. On the other hand, they serve as informants or theoretical advisers on questions dealing with discrepancies in the work process, e.g. some quality parameters of paper may be difficult to attain, but the customer still requires these parameters. The sales personnel can usually explain the reasons for the requirements. Engineers, chemists and other technical experts can give theoretical explanations for the process phenomena and predict their controllability from the viewpoint of technology.

The development program is usually organized in four 2-day sessions. Pauses between the sessions are reserved for rethinking the issues handled, and for collecting empirical data for the future sessions. Each session is arranged twice as, because of shift-work, either 2 or 3 shifts participate in each session. The models prepared by the crews participating in the same session are discussed in a larger group including the crews, other experts related to the production process studied, and the researchers or trainers. The crews learn from each other and also from the questions of other participants. They also learn to ask questions to the various experts and the material available (e.g. technical drawings) regarding the issues studied. The same groups do not participate every time in the training with each other, and this gives all crews a chance to work with all the other four crews in order to improve their co-operation and communication, as these skills are crucial during the change of crews at work. When a shutdown of a line has occurred, all five crews have sometimes participated in the program. This is an ideal way of tackling a problem.

During the program, the work process and its development needs are analyzed with the aid of models representing the work as an activity. Products and raw materials, the object of work, are analyzed first (Table 1). Externalization of the knowledge concerning the actual work process is the first phase in the construction of every model. This is done by listing, for example, the products of the machine line. With the help of the production engineer, the basic lists of two or three crews form a comprehensive list of the products. When the participants have reached agreement on the products, they start to analyze the use of the product, the related requirements for quality parameters, and why (Table 2). The next question deals with the special requirements for the way of acting when the product is made. The potential problems in production are also analyzed, as well as the proportion of the product in the entire volume of production. The models of the raw materials and the machinery used are analyzed in a similar way (Table 2). In this process, the crew members’ different views of the functions and characteristics of this part of the process emerge and complement the mental models of the participants. But incorrect or stereotypic ideas or views may also be reinforced. To avoid this, after finishing their proposition for a model, the crews also analyze their models together with the experts on the issues dealt with. For instance, the model of raw materials, their functions in the process, effects on the quality of the product and the production process in a normal situation, and in the case of over- or underdose, are analyzed with the production engineer and the chemist responsible for quality control in the laboratory. These analyses support the improvement of the crews’ conceptual mastery of the chemistry in paper making and sometimes lead to the need for a deeper understanding of the principles of chemistry.

The phases of the production process are analyzed from beginning to end. The analysis of paper-making starts from the point when the control of the pulp is transferred from the pulp department to the paper makers. The aim of this phase of the program is to improve the conceptual model of production process and the principles of paper making in general. This analysis is needed because the processes are nowadays so complex and hidden that the workers cannot observe the phases of the process in practice. Sometimes old paper making processes are also analyzed from videotapes. These show that although paper making is now both complex and vast in scale, the basic process phases have remained the same for decades. The history of paper-making and the phases of the production process that require improvements and technological innovations are also discussed.

In the model of the paper machine (Table 2) the functions of every part in the production process are analyzed. The crews analyze why every part is needed in the machine and what are the characteristics of the part in question, and what makes the part capable of performing its task. The characteristics of the part are also analyzed from the viewpoint of the usability and reliability of the production process. Because the functioning of technical devices is usually described by the means of technical drawings or formulas of physical phenomena, the participants customarily use these modeling tools to specify the functioning or characteristic of some part that is difficult to understand.

The interface and man-machine interaction is analyzed by asking the following questions:

• What function or characteristic of the part is changed during production or in certain situations (for example, the level of the surface in a tank or the revolution speed of a pump)?

• How the function or part is operated (automatically or manually) and where (in the control room or near the machine)?

• What information is available on the part and its functioning and how is it distributed? What is the sufficiency and usefulness of information in various situations?

The quality of the man-machine interface is often analyzed further. The possibility to control the functioning of a part and the appropriateness of the control devices has been analyzed. The machine, automatic operation system and the allocation of tasks between the human operators and the automatic operation system are analyzed to improve the workers’ conceptual mastery of the principles of the functioning of the technical system and its limitations and development needs.

After this the crews analyze the critical situations arising in production (Table 1). Disturbance situations, changes in grade, shutdowns and start-ups of the process are analyzed on the basis of the tasks derived from real-life information, videotapes of actual work activities, or various simulations of the situations. At this phase of the program, the use of the new conceptual tools adopted during the construction of the various models can be rehearsed in the analysis of activity in critical work situations.

Paper making is a complex system and therefore requires people to work together to make the process function properly. Analysis of the organization and division of work leads to the analysis of co-operation and communication within one crew, between the crews of one machine, between the crews of the related production processes, for example pulp mixing, and also between the personnel in production, production planning, maintenance and quality control. The issues vary to some extent but in all cases an analysis is conducted of the co-operative situation or question dealt with, the participants and the means of co-operation (Table 3).

During the analyses of co-operation the participants learn a lot about the requirements of the related work processes. The participants also learn to ask questions about the work processes of other teams and, very often, the participants create new ways of acting in various co-operative situations.

Every development proposal that comes up during the analysis will be specified further (Table 1). Reasons for the proposal, alternative proposals, the benefits and disadvantages of the proposals, and the necessary resources required are discussed. After a joint view of the required actions is formed, the organizational level on which the decision could be made will be defined and the decision will be made. Finally, those responsible for implementation and the schedules for the proposed actions will be defined. The thorough analysis of development proposals is important, because the participants learn that they can, through systematic analysis of their actual work process and its development needs really affect the development of their work. But they also learn that although there may be development needs in some part of the process, their realization can cause problems in some other part or function of the system, or the analysis may reveal that technological innovation is required to solve the problem or develop the process further.

The changes in the results of a group in the conceptual mastery of work, and in the self-assessments of work and well-being were studied with Wilcoxon’s test. The relations of the conceptual mastery of work, mastery in disturbance handling, development orientation, assessment of work characteristics, and perceived well-being were analyzed with Pearson’s product-moment correlation coefficients. Although the measurements were on an ordinal level, the possibility that the variance of the measures of well-being is explained by several variables was studied with regression analysis in the second phase of the study. The relations between the variable groups were studied separately for the whole group (n = 22) and for the group of workers (n = 17).

Conceptual mastery, mastery of disturbance handling, and their development. Before the development program, 65% of the answers to the diagnostic test measuring conceptual mastery of the work process were correct, whereas afterwards 79% of the answers were correct; 18 out of 22 subjects had a better result in the second measurement than in the first one. The change was statistically significant (p < .001).

The occupational groups differed in their conceptual mastery of the work process before the development program but not after it. Both worker groups increased their conceptual mastery of the work process by statistically significant margins (Table 6). The conceptual mastery of the work process did not increase in the foremen’s group, but it was high (80%) even before the development program. The professional groups did not differ from each other in disturbance handling in either of the measurements. However, when the development of the diagnoses and analyses of the disturbance situation were analyzed qualitatively, some differences in the development of the mastery of disturbance handling were noted between the groups. Before the development program only one foreman and two machine operators made a comprehensive diagnosis and analysis of the situation. After the development program, seven subjects both diagnosed and analyzed the disturbance situation comprehensively and two of them came from the group of reel men. The crews did not differ from each other in either research phase with respect to mastery of the work process.

Appraisals of work characteristics, subjective development qualifications, and the indicators of well-being. The assessments of work characteristics and well-being were positive both before and after the development process and they did not change significantly during the development program. To some extent, the subjects wanted to participate in the development of their work both before and after the development program. After the development program, the participants felt that they were more qualified to participate in the development of their work (p < .05). There were no differences between the occupational groups or the crews in their assessment of their work characteristics or subjective well-being either before or after the development program. There were also only some suggestive differences between the assessments of the work groups.

Relationships between the mastery of work, subjective assessments of development qualifications, work characteristics, and well-being. A prerequisite for health and well-being at work is that the objective work process itself is not hazardous to the workers and supports the development of competence. Secondly, the workers’ assessment of their work process should be realistic. Thirdly, they should have the means to act in the situation and to control it. Finally, they should appraise these means adequately. If the work is unhealthy, if its mastery is poor or if the appraisal of work or its mastery do not correspond to the reality, problems can arise in the well-being of workers. A low level of disturbance handling was related to a high level of self-assessed qualification in work development before the development program started. The workers who were better at handling disturbances experienced more stress and less competence than did the workers with a lower mastery of disturbance handling.

After the development program, a high level in the mastery of disturbance situations was related to job satisfaction. The other indicators of subjective well-being, for example stress, were not related to the conceptual mastery of work nor to the mastery of disturbance handling. In the regression analysis of the workers group, 72% of the variance in job satisfaction was explained by mastery of disturbance handling, together with a positive appraisal of the challenges at work and an active outlook towards work development.

Development needs and the level of learning. Most of the development proposals made during the program dealt with the improvement of the technical production system because of problems in system efficiency and, consequently, the productivity of the system (Table 7). The majority of the proposals aiming at the improvement of problems affecting the quality of the product were technical in nature. But the proposals aiming at the further development of system efficiency and product quality dealt mainly with co-operation with personnel.

The proposals to improve the technological production process started from the perception that the technical system did not work as originally planned or that there were ergonomic problems hindering the working. The primary ideas were sometimes quite fragmentary but when the personnel of the machine line analyzed them systematically, concrete, feasible solutions emerged. Most of the improvements were scheduled at once and implemented during the program. However, proposals to improve the technical system to function as it should, represent only the lowest level of learning, for instance mere adaptation to the context.

The proposals to improve the crews’ ways of acting or to increase cognitive mastery of the process dealt with the improvement of the documentation of process history or with the need to get more information on the measurement of quality parameters. These proposals indicate that the participants also regarded their own activity as an object of development and that the need for a thorough understanding of the work process has also increased. This indicates that the object and motive to work were growing.

The proposals aiming at the further development of the work process dealt mainly with the improvement of co-operation between different organizational parts (Table 7). Paper-making as the core work process is dependent on several other work processes in the organization. Production planning gives paper makers their production program, the concrete goal of their activity. The workers in maintenance ensure the usability of the paper machine, the papermakers’ tool, through preventive maintenance and repair of faults. The laboratory assistants measure the quality parameters of the paper, the object of the papermakers’ work, and inform them about trends and deviations in the parameters. The efficiency of the system depends on the co-operation between these work processes. But when dozens of people worked in every process, the joint goal of the different work processes was not clear enough. The proposals aiming at better co-operation included both the improvement of work activities and the division of labour, but also the need to understand better the internal logic of the related work processes.

This study followed up the groups staying on the old production line (n = 23) and those leaving for the new one (n = 18), 62% of the subjects in the first measurement also participated in the follow-up. This study was also cross-sectional. The two basic groups were compared with each other at two different points of time and with the new groups coming from outside (n = 37 for the old production line, 60 for the new one). Altogether, 79% of the personnel on the old production line and 91% of the personnel on the new one participated in the study.

Those who stayed on the old production line were statistically significantly older (p < .01) than those who moved to the new line and also older (p < .001) than the newcomers to the old production line. Those who stayed on the old production line were also less educated than the other three groups.

Those who stayed on the old production line felt more competent in the second measurement to participate in the development of their own work than in the first measurement. They also assessed their work as more challenging, were more satisfied with their work, experienced their future as more positive, and their work environment as better in the follow-up measurement. Those who transferred to the new machine line were also more satisfied with their work and work environment in the follow-up. They also felt that their control over their own work had increased.

There were very few differences between the groups in the first and the follow-up measurement. There were no differences between the groups in the conceptual mastery of work or in the assessments of work characteristics, job satisfaction or other indicators of subjective well-being measured by the sum scales.