Occupational Physical Stress Faced by Construction Workers & Painters and Improvement of their Work Activity; a Literature Review
Reenu Singh*, Ashok K Pundir and Rauf Iqbal
National Institute of Industrial Engineering, Mumbai
*Address for Correspondence: Reenu Singh, National Institute of Industrial Engineering, Mumbai, Tel: +919-619-601-015; ORCID iD: 0000-0003-2476-5465; E-mail: firstname.lastname@example.org
Submitted: 21 July 2019; Approved: 26 August 2019; Published: 11 September 2019
Citation this article: Singh R, Pundir AK, Iqbal R. Occupational Physical Stress Faced by Construction Workers & Painters and Improvement of their Work Activity; a Literature Review. Sci J Musculoskelet Disord. 2019;3(1): 001-010.
Copyright: © 2019 Singh R, et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited
Keywords: Construction; Equipment; Musculoskeletal disorders; Painters
Studies related to chemical exposure and organ cancer have been carried out with regards to construction workers across the countries. However, few studies include occupational physical stress faced by construction painters in finishing task. Similarly, a handful deals with product design and tool design that can be used to alleviate their occupational stress. The paper includes literature review of occupational stress experienced by construction workers, improvement of work quality, musculoskeletal disorders experienced by construction workers, health issues faced by construction painters, design interventions which include tools and equipment) and patents of products and tools designed for construction painters. Multiple combinations of keywords were used which comprised of; construction, physical stress, Musculoskeletal Disorders (MSDs), ergonomics, painter, worker, high-rise buildings. Several authors have focused on studies related to health issues which deals with effects of noise and fumes on the health of construction workers while others have discussed automation, and few have carried out experimental studies that consist of task analysis, impact of temperature & height on the occupational performance and health of the industrial and construction workers. The article will provide insightful information for medical practitioners, safety & health consultants and industrial designers alike.
COPD: Chronic Pulmonary Disease; CWFIGS: Construction Workers Federation of India; DOE: Design of Experiments; FEM: Finite Element Method; KPMG: Klynveld Peat Marwick Goerdeler; MSD: Musculo Skeletal Disorder; NSDC: National Skill Development Corporation; OSHA: Occupational Safety and Health Administration; TAMIR: Technion Autonomous Multipurpose Interior Robot; WEP: Water Based Paint
Unskilled construction workers constitute 83.3% of the total construction manpower . Construction workers face injuries, health issues and suffer death due to various reasons. Apart from exposure to solvents and chemicals in the paint mixing and application, painters experience musculoskeletal disorders in various regions of their body. Studies related to chemical exposure and organ cancer have been done with regards to construction workers across the countries. However, very few studies have been conducted on product designing of better tools and equipment that can alleviate the musculoskeletal disorders and increase efficiency as well. Workers who are employed by standalone contractors are high in number. There are about 120000 such contractors in the country . 32 million workers are engaged in Construction activities in India. Out of these 22.2 million workers are not registered workers. Out of 15.2 million short-duration out-migrant workers, 36.2 % are employed in construction sector. Construction workers’ job and social security is at a threat from companies in both private as well as public sector. Every year in public sector, the number of permanent workers is decreasing including the technicians, engineers and architects.
To understand efficiency, comfort of the painters needs to be studied. With rise in construction activity in India since last fifteen years, need of the informal unskilled workers have risen immensely. By 2022 there will be about one million construction and maintenance finishing workers employed in India (figure 1).
Painting is a part of finishing process. Due to weathering and washing of exterior paint due to constant exposure to rain and varied temperatures, the old construction need maintenance painting every five years. Therefore, the painting work is rather a continuous process which is carried all through the life of a building. The demand of painters and need to thus solve issues faced by the work force is significant to contribute to efficiency and productivity of the workers. The following content of the article deals with occupational stress and design interventions that have been carried out to improve the task of construction and maintenance painters.
Construction activity consists of various actions and processes. Some of these processes fall under the two heads; site preparation and site operations . A construction project consists of various steps and processes. Each following the other and few are carried out simultaneously. Broadly a project starts with project brief which is more about planning and design followed by detailing and certain decisions pertaining to electrical, plumbing, HVAC (Heating Ventilation and Air conditioning), finishing, site design and detailing, marketing and sales and so on. The work is either in house or is done with outside contracts with contractors and consultants. Depending on the different processes and the capability of the firm to handle the tasks, the firm uses in house team or collaborates with other firms and consultants to carry out the different stages of construction and finishing.
Rise in population of construction workers
As indicated in the figure 2, there is a steady rise in the unskilled workers from 1995 to 2004. However, 2005 onwards the rate of increase has gone up. This was the time when construction activity in India had experienced a sharp rise and supply of construction projects was suddenly high due to increase in economic activity in the commercial and industrial systems.
The tasks of completing and completing construction works is predicted to be more than the other stages of activities that are part of a building construction activity. Therefore, demand of completion and finishing workers will increase over the next five years (figure 3).
Thus need to study the occupation health& safety becomes essential for the efficiency of the workers engaged in completion and finishing of buildings. Construction workers experience several issues due to nature of their work, task performance with their equipment, safety issues, social and peer issues, exposure to chemicals and pollutants among others.
Issues faced by construction workers
Construction labour form around 7.8% of the world labour force. The fatal deaths of construction workers account to 16.4% of the total deaths across the globe . After agriculture, construction is the second largest economic activity in India. The maximum number of deaths are resulted by falls followed by electrocution and then by fire. Any construction project includes preparation of site, building of sub-structure, superstructure and followed by finishing. These steps of building construction can be further integrated into smaller processes and sequences depending on the architectural design and chosen manufacturing process. Plastering, Painting, landscaping, electrical fittings and fixtures, paving is some of the activities that follow completion of the super structure of a building. The status of construction workers is largely uncertain as they consist mostly of informal workforce. Most processes in the construction processes employ unskilled workers on large scale. As less number of studies have been done on construction workers and their occupational issues, the health and safety of the workers has been neglected. Issue faced by construction workers.
Relationship of Worker with Work and Workstation
Workers perform with their tools and equipment. The workstation and the immediate exterior activity area is the workstation of a construction worker. For construction finishers and painters, the job includes gathering teammates, expected extent of the surface to be painted, making of the paint mixture, procurement of harness and helmet, extension poles/sticks, material to fix one end of rope or support at the roof, smaller bucket to refill with paint mixture, rough cloth and brushes. His personal belongs which the painter and cleaner wears on himself includes, his attire, cell phone, lighter and bidi or cigarette, tobacco and calcium paste. Figure 04 shows interrelationship between a worker, work (task) and workstation (workspace) .
Worker performs the task in a specific space which is affected by surrounding physical, social and environmental factors. Work on the other hand is the task which is a defined set of actions that are carried out with the help of tools and equipment and required interaction with the environment, peers and cognitive abilities. Workspace is the area in which the task is performed which sometimes constitute to a portion of the task as well as is evident in case of construction painting task where the wall surface and whole access on scaffolding becomes the workspace.
The health hazards a painter experiences are of varying nature. There are risks of falling from the hanging rope, slipping from the scaffolding, ill functioning of the harness resulting in fall of the painters, maintaining balance and falling off, movement in precarious positions and postures resulting in loss of balance, muscle strain, breathing disorders due to inhalation of powder paint and fumes. Stressful weather conditions, conflict with peers and supervisor leading to mental stress. Such issues are pertinent to occupational efficiency and wellbeing of the building painters. Thus, to understand wellbeing of construction workers, it is important to closely review the role of tools and equipment which directly affects their work at hand at a given time.
Construction activities on site require workers to move arms above shoulder while carrying out activities of carrying heavy and awkward load or performing a task. Hence tasks and activities of construction is an issue in ergonomics . Materials may also be heavy and inconveniently sized and shaped, thus presenting manual materials-handling problems to the workers. Moreover numerous construction tasks pose significant ergonomic risks to workers . Several studies in the past have focused on manual construction workers however no study has been conducted so far on occupational issues faced by construction and maintenance painters.
Research papers available online at various web sites including Science Direct, PubMed, Google Scholar and ProQuest were searched using sets of keywords. In multiple combinations research papers were searched using the following keywords: ergonomics, external wall, painting, construction, painting, and worker, high-rise housing . Various authors have thus found to have focused on studies related to health issues related to noise and fumes that are faced by construction workers in general. While some authors discussed automation in construction industry in the world, few have carried experimental studies in the areas of impact of temperature, height and task analysis. Since 1998 some ergonomic studies have been carried out in the sector of building construction . However, there is observed a lack of task studies and analysis of workers that are employed in jobs of finishing, painting, scaffolding and shuttering fastening among others.
Literature review of studies on issues faced by construction workers in painting task
Area of research being Health, Hazards, Tools, equipment pertaining to job of construction painters, the papers so found were screened further. Literature Review of issues faced by construction workers across the research studies done from.
Issues faced by construction workers in construction and painting task
Construction painters suffer from solvent related health issues, respiratory disease and skin disease [8,9]. According to Fiddler, construction painters are observed to have contact sensitivity issues which are related to solvent exposure in paints. Contact sensitivity is associated with usage of paint, glue and putties. Solvents affect neuro-behaviour and causes arm weakness [9,10] found that construction painters who are exposed to chronic solvents suffer from neuropsychiatric symptoms. Though, conjunctivitis is not found related to painting task by asthma, rhinitis and bronchitis is related to painting task. Painters with experience of 1-10 years and long working history has three-fold higher risk of developing asthma than other construction workers [15,18]. Construction painters are susceptible to develop Chronic Obstructive Pulmonary Disease (COPD) . However, since past two decades epoxy and urethane has been used less in construction painting . Dust and other impurities at construction painting site affects respiratory health of construction painters [14,18,19]. Studies on respiratory effects in construction painters is less than on other trades . Water based paints have replaced solvent based paints in recent decades and User-friendly, low-emitting photocatalytic materials in the indoor wall painting [15,24,26]. Photocatalytic paint in indoor wall paints reduce air pollution [27-29]. Photocatalytic titania based surfaces can improve environment . Lead was used in old constructed buildings. Lead content is highest in railings, metallic structure, yellow paint on road dividers, public play grounds .
Besides natural landscape features that lie next to construction site, weather and physical onsite machinery, physical entities related to job of construction painters can be integrated into three basic entities. 1) Individual; the construction painter’s physical self which is involved in tasks of repeated movements and load bearing along with cognitive abilities employed in sensing precision and hand feet coordination in reaching out. In doing so the body of the painters experience various stress at different parts which leads to Musculoskeletal Disorders. Different body parts suffer physical stress differently depending on the expected intensity of work. 2) Essentials entities specific to Construction painting; this consist of task design, tool and equipment, aids that help the painter in performing the painting task with less stress and fatigue and costume which is immediately on his self. Costume thus plays an important role in giving comfort of movements and easy stretch of arms and legs in reaching and twisting movements. 3) External supporting elements essential to construction painters: these are the infrastructure tools and structures that give physical support and aid to move up and down the building façade and carry his paint and other equipment around his workspace (workstation (figure 4)).
Wall painting robots
Finishing task of newly constructed building as well as maintenance of old buildings require painting work. Several studies have shown design interventions to automate the painting task. Such studies deals mainly with robots that paint a wall surface. Specifications and limitations of these designs are highlighted in table 2.
Automation of wall painting by wall painting robots
Spray painting robot was designed in 2013 that can be used to paint interior walls of a buildings . This prototype robot moves on floor surface. A safety robot was designed that can be used for maintenance and cleaning work as well as for inspection of the buildings . Asakawa and Takeuchi worked on control commands for robot to function without special knowledge. The robot was used to paint car bumper to test the functioning of command on a contoured surface. The painting activity resulted in uniform thickness of the paint coating on the contour surface of the bumper . Moon and his team worked on locomotion and adhesion based robot that can be used for painting walls . TAMIR (Technion Autonomous Multipurpose Interior Robot) was designed by adaptation of mobile carriage which had attached working tools and fitted material feeding system. It had a painting arm with a radius of 1.5 m . Moon and his team again built a prototype robot that had built-in guide rail. Moon’s robot could work for maintenance of building . Koleka and his team studied various robot structures and their respective workspaces. He suggested that the most important aspects of design of robots are degrees of freedom, ease of programming, work accuracy, character of workspace and arm configuration for apt movement and reach . Another robot was designed in which the distance of the reach of wall surface is fed by supervising worker and once paint other materials are set the robot starts to paint the wall autonomously . A painting robot was developed that could paint only ceilings of a room. The size was a limitation as it could not be moved through narrow door openings and other spaces in residential buildings . A multifunctional robot was designed for construction sites that could do four tasks which are painting, plastering, tiling and masonry . It had limitations that due to its heavy weight it cannot climb and was cumbersome to be transported at the painting spots inside the buildings. A couple of spray painting robots were designed which was again very heavy [60, 61].
Design of tools and equipment
Physical interaction of workers with their tools play an important role in providing comfort in carrying out their task easily. Physical comfort of good grip and unwanted body posture due to absence of correct tool and equipment thus affects physical health of the construction workers. Table 3 shows the studies that deals with design intervention related to tasks of manual construction workers and improvement of tools and equipment.
Design interventions of tools and equipment
Areas of improvements are design of equipment and re-engineering [44, 45, 47, 49]. Design of materials, packaging and delivery method can reduce accident more than third of all the risks at construction site . Kerbs had been redesigned for better and easier edging of the surfaces . Usability of trowels has been tested . Stability of saws had been evaluated for better interaction and function . A pilot investigation for comparison of usability of random orbit sanders and ergonomic evaluation had been conducted . Brick laying device was designed . Ergonomic quality of hand tools used at construction site which were used during construction process were studied . Accidents are associated with design of equipment, support and tools that are used in material handling . Construction safety is linked with barrier at construction sites that cordon potentially hazardous activities and site areas . Parapet wall should be 42 inches high. Inappropriate installation of roofs and facades are hazardous for construction workers and that technical faults are caused by poor workmanship and not by quality of the material. 27% of OSHA (Occupational Safety and Health Administration)  reports are linked to Design of entities and system at construction sites.
Designs of painting tools and equipment
Several painting tools have been designed that help construction painters in their task. Table 4 highlights these studies. Some deals with platforms, organisers, buckets while others deal with belt, raised platform among others.
Product design patents for construction painters
William porter’s ‘Adjustable foldable horse for painters’ is a foldable support, base width is controlled with screws. Willia Hoehm’s ‘Improvement in painter’s scaffold’ is a platform of timber made up of longitudinal and transverse members. It is portable and when in use can be fitted on base rods. Charles Sprague’s ‘Platform for painters’ is a folder platform, fitted on metal ladder used only for interior wall painting. Martin Mattson’s ‘Painter’s roof bracket’ is used to support a platform for painters to stand. The platform is fixed on slant roofs supported by ‘C’ shaped pair of brackets. John Wright’s ‘Jack for roofers and carpenters’ is secured to roof. It is a scissor shaped jack used to support a small plank or a platform. ‘Carrying case for wet and dry painting booth’ comprises of Drainable tray occupying two sides of a case. Limitation of low capacity of containment of paint and is used for interior wall painting (by Joseph Rocco). ‘Brush Kit’ is a case holder with housing to hold different sizes of paint brushes (by Oddo Charles). ‘Multiple roller corner painting tool’ is essentially a set of rollers at right angle on the handle additionally the product is foldable. Used to paint corner of the walls (by Hugo Rivadeneira) ‘Adjustable holder assembly for painting tools’ comprises of an adjustable arm used as a holder for painting accessory. Arm can be fixed to a round pipe (Chad Posser, Erick Rudnick). ‘Painter’s pouch’ by Carl D. Robinson is a rigid box with paint container and other pouch to store paint accessories. Bag is carried with support on shoulder and back. Issues may arise for external wall painter to carry the (insufficient) load on body for hours. ‘Multipurpose paint brush’ by Bert H Abbey consists of a bucket with a short handle; can be hung on a bar/pole member and is meant for interior painting due to small size and absence of hanging feature. ‘Apparatus for carrying a spray paint’ (Mark E. Devine) consists of a belt with a housing attached to hold spray cans. Not meant for wall painting. ‘Painter’s utility belt’ (by Charles L. Byrd) is a wearable belt with a pouch on one side. Robert Scholl’s ‘Paint holder and delivery device’ comprise of a bucket with a spout; held in hand; no attachment feature. ‘Multipurpose paint bucket’ includes a main compartment along with smaller spaces for different paint in unequal quantity. Preferred use in in interior wall painting; low paint capacity (by Bert H Abbey). ‘Painting machine and control unit for use in a painting booth’ is a painting booth; not usable for wall painting (by Fujio Soshi, Masaharu Okuda, Koichizo Asami).
Causes of discomfort and problem areas in the regions of body of construction painters is mainly due to lack of improved design of tools and equipment, as has been established by Smallwood in his past studies. Hence to make the task less stressful, the physical strain in inconvenient body postures should be avoided. Design interventions that provide convenient working and less postural stress will thus lower the Musculoskeletal Disorders (MSDs) and intensity of the work for the construction and maintenance painters.
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