Your search keyword '"Construction Industry instrumentation"' showing total 65 results

1. Wearable heart rate sensing and critical power-based whole-body fatigue monitoring in the field.

Author

Lee G, Bae J, Jacobs JV, and Lee S

Subjects

Humans, Adult, Male, Construction Industry instrumentation, Monitoring, Physiologic instrumentation, Monitoring, Physiologic methods, Female, Middle Aged, Young Adult, Workplace, Occupational Health, Heart Rate physiology, Wearable Electronic Devices, Fatigue

Abstract

Whole-body fatigue (WBF) presents a concerning risk to construction workers, which can impact function and ultimately lead to accidents and diminished productivity. This study proposes a new WBF monitoring technique by applying the Critical Power (CP) model, a bioenergetic model, with a wrist-worn heart rate sensor. The authors modified the CP model to calculate WBF from the percentage of heart rate reserve (%HRR) and generated a personalized model via WBF perception surveys. Data were collected for two days from 33 workers at four construction sites. The results showed that the proposed technique can monitor field workers' perceived WBF with a mean absolute error of 12.8% and Spearman correlation coefficient of 0.83. This study, therefore, demonstrates the viability of wearable WBF monitoring on construction sites to support programs aimed at improving workplace safety and productivity., Competing Interests: Declaration of competing interest The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: The intellectual property stems from this paper is licensed to Humanca LLC, co-owned by Prof. SangHyun Lee., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

2. Power saw noise levels during steel stud cutting tasks on commercial construction sites: a tool characterization from a worker exposure standpoint.

Author

Schutt D, Lipsey T, Van Dyke M, and Brazile WJ

Subjects

Humans, Hearing Loss, Noise-Induced etiology, Noise, Occupational adverse effects, Occupational Exposure analysis, Steel, Construction Industry instrumentation

Abstract

Construction framers who cut and install steel studs as part of their daily tasks are exposed to hazardous noise levels during their work shift in large part due to the power saws they use to cut steel studs. This investigation characterized the sound pressure levels of power saws used to cut steel studs on active construction sites. Further, the length of time it took to cut various studs on a construction site was investigated to understand worker exposure times to saw noise. In general, power saws used on the study sites to cut steel studs had a mean A-weighted equivalent continuous sound pressure level (LAeq) of 107.2 dB and a C-weighted peak sound pressure level (LCpeak) of 120.1 dB. Three of the saws-the chopsaw, the cut-off saw, and the grinder-had similar noise levels, whereas the cordless circular saw had higher noise levels. It took an average of 13.2 s to cut each stud, and workers in the study used power saws to cut steel studs for an average of 371.5 s per day. This average exposure time at the average recorded sound pressure levels (SPLs) suggests these saws can increase the risk of occupational noise-induced hearing loss, according to National Institute for Occupational Safety and Health (NIOSH) recommendations., (© The Author(s) 2024. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published

2024

3. Effects of using an active hand exoskeleton for drilling tasks: A pilot study.

Author

Ibrahim A, Okpala I, Nnaji C, and Akanmu A

Subjects

Humans, Male, Pilot Projects, Adult, Hand Strength physiology, Muscle, Skeletal physiology, Young Adult, Physical Exertion physiology, Task Performance and Analysis, Construction Industry instrumentation, Electromyography, Exoskeleton Device, Hand physiology

Abstract

Introduction: Several studies have assessed and validated the impact of exoskeletons on back and shoulder muscle activation; however, limited research has explored the role that exoskeletons could play in mitigating lower arm-related disorders. This study assessed the impact of Ironhand, an active hand exoskeleton (H-EXO) designed to reduce grip force exertion, on worker exertion levels using a two-phase experimental design., Method: Ten male participants performed a controlled, simulated drilling activity, while three male participants completed an uncontrolled concrete demolition activity. The impact of the exoskeleton was assessed in terms of muscle activity across three different muscles using electromyography (EMG), perceived exertion, and perceived effectiveness., Results: Results indicate that peak muscle activation decreased across the target muscle group when the H-EXO was used, with the greatest reduction (27%) observed in the Extensor Carpi Radialis (ECR). Using the exoskeleton in controlled conditions did not significantly influence perceived exertion levels. Users indicated that the H-EXO was a valuable technology and expressed willingness to use it for future tasks., Practical Applications: This study showcases how glove-based exoskeletons can potentially reduce wrist-related disorders, thereby improving safety and productivity among workers. Future work should assess the impact of the H-EXO in various tasks, different work environments and configurations, and among diverse user groups., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 National Safety Council and Elsevier Ltd. All rights reserved.)

Published

2024

4. Characterization of particle exposure during tunnel excavation by tunnel boring machines.

Author

Ervik TK, Leite M, Weinbruch S, Nordby KC, Ellingsen DG, Ulvestad B, Dahl K, Berlinger B, and Skaugset NP

Subjects

Humans, Inhalation Exposure analysis, Environmental Monitoring methods, Environmental Monitoring instrumentation, Quartz analysis, Dust analysis, X-Ray Diffraction methods, Construction Industry instrumentation, Particle Size, Occupational Exposure analysis, Particulate Matter analysis, Air Pollutants, Occupational analysis

Abstract

Tunnel boring machines (TBMs) are used to excavate tunnels in a manner where the rock is constantly penetrated with rotating cutter heads. Fine particles of the rock minerals are thereby generated. Workers on and in the vicinity of the TBM are exposed to particulate matter (PM) consisting of bedrock minerals including α-quartz. Exposure to respirable α-quartz remains a concern because of the respiratory diseases associated with this exposure. The particle size distribution of PM and α-quartz is of special importance because of its influence on adverse health effects, monitoring and control strategies as well as accurate quantification of α-quartz concentrations. The major aim of our study was therefore to investigate the particle size distribution of airborne PM and α-quartz generated during tunnel excavation using TBMs in an area dominated by gneiss, a metamorphic type of rock. Sioutas cascade impactors were used to collect personal samples on 3 separate days. The impactor fractionates the dust in 5 size fractions, from 10 µm down to below 0.25 µm. The filters were weighted, and the α-quartz concentrations were quantified using X-ray diffraction (XRD) analysis and the NIOSH 7500 method on the 5 size fractions. Other minerals were determined using Rietveld refinement XRD analysis. The size and elemental composition of individual particles were investigated by scanning electron microscopy. The majority of PM mass was collected on the first 3 stages (aerodynamic diameter = 10 to 0.5 µm) of the Sioutas cascade impactor. No observable differences were found for the size distribution of the collected PM and α-quartz for the 3 sampling days nor the various work tasks. However, the α-quartz proportion varied for the 3 sampling days demonstrating a dependence on geology. The collected α-quartz consisted of more particles with sizes below 1 µm than the calibration material, which most likely affected the accuracy of the measured respirable α-quartz concentrations. This potential systematic error is important to keep in mind when analyzing α-quartz from occupational samples. Knowledge of the particle size distribution is also important for control measures, which should target particle sizes that efficiently capture the respirable α-quartz concentration., (© The Author(s) 2024. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published

2024

5. Effects of upper-limb exoskeleton on muscle activity in tasks requiring arm elevation: Part II - In-field experiments in construction industry settings.

Author

Mänttäri S, Rauttola AP, Halonen J, Karkulehto J, Säynäjäkangas P, and Oksa J

Subjects

Humans, Male, Adult, Electromyography, Biomechanical Phenomena, Arm physiology, Heart Rate physiology, Task Performance and Analysis, Exoskeleton Device, Construction Industry instrumentation, Construction Industry methods, Upper Extremity physiology, Muscle, Skeletal physiology

Abstract

Background: The body of literature regarding the use of an upper limb exoskeleton during authentic working conditions is sparse., Objective: The aim of this study was to evaluate the effectiveness of an upper limb exoskeleton in reducing muscle strain during authentic industrial construction work., Methods: Fifteen male participants, comprising of roofers, scaffolders, builders, bricklayers, and graders performing overhead work participated in the study. During work without (REF) and with exoskeleton (EXO), muscle activity from 8 muscles, heart rate (HR), metabolic equivalent (MET), and upper arm elevation angles were recorded., Results: When using the exoskeleton, a significant reduction of 20.2% in average muscle activity of 8 muscles was found. The largest effect focused on m. deltoideus, where 46.2 and 32.2% reduction occurred in medial and anterior parts of the muscle, respectively. HR and MET were unaffected. Upper arm elevation angles were similar between REF and EXO, indicating equal biomechanical loading., Conclusions: This study indicates that exoskeletons show great promise in reducing the potential for musculoskeletal strain during authentic overhead construction work.

Published

2024

6. A three-dimensional intelligent engineering management and control system for the construction of a long-span valve hall project based on a microservice architecture.

Author

Zeng Q, Ming W, Luo J, Zhang S, Hu W, Liu Z, and Zhou C

Subjects

China, Humans, Communication, Construction Industry instrumentation, Electric Power Supplies statistics & numerical data, Electricity, Engineering methods, Intelligence, Software

Abstract

Three-dimensional intelligent engineering management and control systems (EMCS) based on the browser/server (B/S) model are an important part of intelligent engineering development. These systems are used for solving the difficulties encountered in engineering management with frequent cross-specialties and are vital tools for data exchange and service sharing among multiple departments. Currently, most engineering management and control systems are based on service-oriented architectures (SOAs). The integration mechanism and high coupling of SOAs leads to the reduction in system expansibility, service quality and service safety of the engineering system, making it difficult for these architectures to serve the construction of long-span valve hall engineering. To address these concerns, the management and application technology of the multidisciplinary data of valve hall engineering based on a microservice architecture (MSA) is proposed to improve the management efficiency of engineering data. A 3D integration modeling method for valve hall engineering structures and geological environments is proposed to establish the topological association between engineering structures and geological environments, without increasing the amount of model data required. A 3D intelligent engineering management and control technology for the entire process of the construction of long-span valve hall engineering is proposed, which realizes the entire process simulation and control of engineering construction based on WebGL technology. Accordingly, a three-dimensional intelligent engineering management and control system for the entire construction process of a long-span valve hall project in Southeast China is established, which can effectively manage and apply the data, display and analyze the three-dimensional model, and control and make decisions regarding the construction schedule. This study provides support for the construction of "smart engineering", promotes information communication and transmission between different project units, and speeds up the transformation from traditional construction management relying on drawings to three-dimensional intelligent construction management based on cloud services., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

7. Nail gun injuries: not just an occupational hazard.

Author

McGuinness MJ, Thompson G, Haysom S, and Civil I

Subjects

Adult, Equipment Safety, Female, Head Injuries, Penetrating therapy, Hospitalization, Humans, Injury Severity Score, Intensive Care Units statistics & numerical data, Length of Stay statistics & numerical data, Male, Middle Aged, Mortality, New Zealand, Occupational Injuries therapy, Self-Injurious Behavior therapy, Surgical Procedures, Operative, White People, Wounds, Penetrating therapy, Construction Industry instrumentation, Extremities injuries, Head Injuries, Penetrating epidemiology, Occupational Injuries epidemiology, Self-Injurious Behavior epidemiology, Wounds, Penetrating epidemiology

Abstract

Introduction: Nail guns are commonly used in the construction industry. They represent an occupational hazard, and in the context of mental illness can pose a threat to life., Aim: To determine the number of patients admitted to Auckland City Hospital (ACH) with a nail gun injury, and to review the current New Zealand legislation surrounding nail guns., Methods: A 25-year retrospective review of patients admitted to ACH with a nail gun injury was performed by searching the ACH Trauma Registry. New Zealand legislation was reviewed., Results: Between 1994 and 2019, 45 patients were admitted to ACH with a nail gun injury. Two subgroups were identified: 31% with an intentional injury; 69% with an unintentional injury. All patients were male. The mean age was 36.3. Patients with an intentional injury had a higher mortality rate (21.4% vs 9.5%), Injury Severity Scores (24.2 vs 3.4) and ICU admission rate (50% vs 3%) and required more intensive post-injury care when compared to unintentional injuries. There is currently no legislation in New Zealand specifically governing the use of nail guns. Only powder-actuated nail guns require certification., Conclusion: The continued occurrence of unintentional nail gun injuries and the high lethality of intentional injuries represent two distinct areas of concern. The Government should publish guidance aimed at improving safety and reducing the rate of intentional injury., Competing Interests: Nil.

Published

2021

8. Flexural strengthening of beams using post-tensioned metal straps fully wrapped around steel channels anchored to normal steel reinforced concrete beams.

Author

Abdullah W and Rafiq SK

Subjects

Compressive Strength, Construction Industry methods, Tensile Strength, Construction Industry instrumentation, Construction Materials, Steel

Abstract

The efficacy of post-tensioned metal straps PTMS, wrapped around steel channels anchored to normal reinforced concrete (R.C) beams is tested in increasing the flexural capacity of the beams. For this purpose, nine normal R.C beams with dimensions of 160 mm x 240 mm x 2100 mm are constructed to fail in bending. The location and the number of the straps are considered as the main variable. It is found that using PTMS can enhance the load-carrying capacity of the beam by 29% to 63%. The decisive factors affecting the increase are the location of the straps (at the bottom or sides), shape of the flange and web edges (squared or rounded) and alignment of the flanges (vertical or inclined). A complete guide can be found in the paper as it is a novel method of strengthening beams which can be applied to the beams cast in place with integral slabs., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

9. Development of the fall prevention index on the movable scaffold for construction workers.

Author

Min SN, Subramaniyam M, Park SJ, and Lee KS

Subjects

Adult, Humans, Male, Postural Balance, Republic of Korea, Safety, Workplace standards, Accidental Falls prevention & control, Accidents, Occupational prevention & control, Construction Industry instrumentation

Abstract

Background: Falls are caused by difficulties in maintaining stable posture or center of pressure (COP). Studies on construction-related falls and their prevention are limitedOBJECTIVE:To propose a fall prevention index (FPI) based on the working environment at height (with or without a handrail) and experience of workers on movable scaffolds., Methods: Thirty participants were enrolled, and their COP distances were measured at the time of falling in the anterior-posterior (AP), mediolateral (ML), and diagonal directions., Results: The probability of falling in the diagonal direction is almost zero for workers with more than 20 years of experience and that in the AP direction is almost zero for workers with up to 30 years of experience. There was almost zero probability of falling in the ML direction for workers with >15 years of experience. This index can be used as a tool for predicting the risk of falls, screening workers, and implementing proactive measures to prevent falling accidents on work sites., Conclusions: Preventing falls from movable scaffolds (and height in general) is needed in the construction industry. We propose a fall prevention index based on the working environment (at height, with or without handrail) and experience of workers on movable scaffolds.

Published

2020

10. Ergonomic Benefits of an Angle Grinder With Rotatable Main Handle in a Cutting Task.

Author

Reinvee M, Aia S, and Pääsuke M

Subjects

Adult, Construction Industry instrumentation, Electromyography, Equipment Design, Humans, Male, Occupational Health, Task Performance and Analysis, Wrist physiology, Ergonomics instrumentation, Forearm physiology, Muscle, Skeletal physiology

Abstract

Objective: The aim of this study was to evaluate the ergonomic benefits of an angle grinder with a rotatable main handle in a cutting task., Background: Angle grinder manufacturers rarely address ergonomic features in their advertisements, and if they do, the benefits are expressed in a qualitative manner. Meanwhile, quantitative information about the effects of the device on the worker is required to make informed decisions during tool selection and cumulative trauma prevention., Method: Eleven maintenance workers and metalworkers used an angle grinder to cut a horizontal steel rod using three wrist postures. Only one of the postures was exclusively available in the case of a rotatable main handle. The postural effect was evaluated objectively with electromyography and a force-sensing-resistor-based force glove. Subjective ratings about discomfort and control were obtained with a visual analog scale., Results: The subjective ratings favor the near-neutral wrist posture. The forearm muscles' electromyographic activities were similar across the postures. Forces on the hand-handle interface were concentrated on the intermediate phalanges. If the device is operated without gloves, the forces on the intermediate phalanges may exceed the discomfort pressure threshold regardless of wrist posture., Conclusion: In the cutting task, the subjective measures favor the posture with a near-neutral wrist, which is a feature of the rotatable main handle. The objective measures did not allow one to prefer one posture to another., Application: The findings give insight into the impact of wrist posture on muscle activity, forces on the hand-handle interface, and discomfort. This is useful information for the person responsible for tool selection.

Published

2019

11. Effects of exoskeleton design and precision requirements on physical demands and quality in a simulated overhead drilling task.

Author

Alabdulkarim S, Kim S, and Nussbaum MA

Subjects

Adult, Computer Simulation, Electromyography, Female, Humans, Male, Muscle, Skeletal, Musculoskeletal Diseases prevention & control, Occupational Diseases prevention & control, Occupational Health, Shoulder, Young Adult, Construction Industry instrumentation, Equipment Design methods, Ergonomics methods, Exoskeleton Device, Task Performance and Analysis

Abstract

We compared three passive exoskeleton designs in a mock drilling task under three precision requirements levels, defined by required hole sizes, in terms of physical demands (perceived exertion and muscular activation) and quality. The investigated designs were: 1) an upper-body exoskeleton mainly supporting the shoulder; and both 2) full-body, and 3) upper-body exoskeletons, each with connected supernumerary arms. At a fixed pace, participants (n = 12) repeated "drilling" two same-sized holes for 2 min. A fairly consistent result across exoskeleton designs was that higher precision demands increased some muscle activation levels and deteriorated quality. Designs with supernumerary arms led to the largest reductions in quality and increased physical demands overall, mainly in the low back. The shoulder-focused exoskeleton reduced shoulder demands but appeared to reduce quality with the highest precision requirement. Although future work is needed under more diverse/realistic scenarios, these results might be useful to (re)design occupational exoskeletons., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

12. Malignant mesothelioma in construction workers: the Apulia regional mesothelioma register, Southern Italy.

Author

Vimercati L, Cavone D, Caputi A, Delfino MC, De Maria L, Ferri GM, and Serio G

Subjects

Adult, Aged, Aged, 80 and over, Construction Industry instrumentation, Humans, Incidence, Italy epidemiology, Lung drug effects, Lung pathology, Lung Neoplasms chemically induced, Lung Neoplasms diagnosis, Lung Neoplasms pathology, Male, Mesothelioma chemically induced, Mesothelioma diagnosis, Mesothelioma pathology, Mesothelioma, Malignant, Middle Aged, Asbestos adverse effects, Environmental Exposure adverse effects, Lung Neoplasms epidemiology, Mesothelioma epidemiology, Occupational Exposure adverse effects, Registries

Abstract

Objective: Asbestos was widely used in construction in both a friable and a compact form until the 1990s, before its use was banned. Today, many of these materials are still in situ and represent a source of risk for construction workers. The objective of the study was to analyse the cases of mesothelioma arising among construction workers registered in the Apulia regional register of mesothelioma., Results: For the period 1993-2018, there were 178 male cases, and 10.2% of the cases were present in the regional register. The average age at diagnosis was 64.7 years. The site was pleural in 96.06% of cases, with a diagnosis of certainty in 86.5% of the total cases and 61.8% of cases with epithelial histology. The average latency is 43.9 years. In 75.2% of cases, the exposure began between 1941 and 1970, with an average duration of 24.3 years. The age at the start of exposure in 68.5% of cases is between 8 and 20 years. The ORs were 2.5 (C.I. 95% 1.01-6.17) for the epithelioid histotype and the high duration of exposure. The data underline the need for prevention and information on all activities involving construction workers in which asbestos-containing materials are still used.

Published

2019

13. Penetrating neck trauma with common carotid artery injury caused by a percussive drill: A case report.

Author

Wang D, Zhao Y, Cha B, Fang P, and Liu Y

Subjects

Carotid Artery Injuries etiology, Construction Industry instrumentation, Foreign Bodies etiology, Humans, Male, Middle Aged, Neck Injuries etiology, Wounds, Penetrating etiology, Carotid Artery Injuries surgery, Carotid Artery, Common surgery, Foreign Bodies surgery, Neck Injuries surgery, Wounds, Penetrating surgery

Abstract

Rationale: Penetrating neck traumas are dangerous and have a high mortality rate, particularly in patients with common carotid artery injuries. Advances in diagnostic imaging technology have shifted management of penetrating neck injuries from mandatory exploration to selective management. The question is now regarding optimal selection of auxiliary examinations to assess "stability" rapidly and guide clinics in managing such patients., Patient Concerns: A 56-year-old man suffered neck trauma with the right common carotid artery caused by a percussive drill. The carotid artery could not be clearly displayed in computed tomography (CT) angiography imaging., Diagnoses: Penetrating neck trauma due to percussive drill bit with common carotid artery injury., Interventions: X-ray and bedside duplex ultrasound with color Doppler flow imaging were used to assess the state of trauma and the foreign body was removed under general anesthesia., Outcomes: The patient was discharged at postoperative day 10 with no complication. The patient had no sequelae from this injury at 6-month follow up., Lessons: X-ray provides a comprehensive assessment of damage, and can efficiently detect foreign bodies in the skull and cervical vertebrae. Duplex ultrasound to be a viable method to exclude macrovascular injury in unstable patients who are not eligible for computed tomography angiography (CTA) or catheter angiography imaging. Widely available duplex ultrasound and x-ray should be considered in emergency situations.

Published

2019

14. Effect of hollow bit local exhaust ventilation on respirable quartz dust concentrations during concrete drilling.

Author

Rempel D, Barr A, and Cooper MR

Subjects

Construction Industry instrumentation, Dust analysis, Inhalation Exposure analysis, Occupational Exposure prevention & control, Air Pollutants, Occupational analysis, Quartz analysis, Ventilation methods

Abstract

Drilling large holes (e.g., 10-20 mm diameter) into concrete for structural upgrades to buildings, highways, bridges, and airport runways can produce concentrations of respirable silica dust well above the ACGIH ® Threshold Limit Value (TLV ® = 0.025 mg/m 3 ). The aim of this study was to evaluate a new method of local exhaust ventilation, hollow bit dust extraction, and compare it to a standard shroud local exhaust ventilation and to no local exhaust ventilation. A test bench system was used to drill 19 mm diameter x 100 mm depth holes every minute for one hour under three test conditions: no local exhaust ventilation, shroud local exhaust ventilation, and hollow bit local exhaust ventilation. There were two trials for each condition. Respirable dust sampling equipment was placed on a "sampling" mannequin fixed behind the drill and analysis followed ISO and NIOSH methods. Without local exhaust ventilation, mean respirable dust concentration was 3.32 (± 0.65) mg/m 3 with a quartz concentration of 16.8% by weight and respirable quartz dust concentration was 0.55 (± 0.05) mg/m 3 ; 22 times the ACGIH TLV. For both LEV conditions, respirable dust concentrations were below the limits of detection. Applying the 16.8% quartz value, respirable quartz concentrations for both local exhaust ventilation conditions were below 0.007 mg/m 3 . There was no difference in respirable quartz dust concentrations between the hollow bit and the shroud local exhaust ventilation systems; both were below the limits of detection and well below the ACGIH TLV. Contractors should consider using either local exhaust ventilation method for controlling respirable silica dust while drilling into concrete.

Published

2019

15. Pneumatic rock drill vs. electric rotary hammer drill: Productivity, vibration, dust, and noise when drilling into concrete.

Author

Rempel D, Antonucci A, Barr A, Cooper MR, Martin B, and Neitzel RL

Subjects

Efficiency, Environmental Monitoring methods, Humans, Manikins, Noise, Occupational, Construction Industry instrumentation, Construction Materials adverse effects, Dust analysis, Occupational Exposure analysis, Vibration adverse effects

Abstract

Objectives: Both pneumatic rock drills and electric rotary hammer drills are used for drilling large holes (e.g., 10-20 mm diameter) into concrete for structural upgrades to buildings, highways, bridges, and airport tarmacs. However, little is known about the differences in productivity, and exposures to noise, handle vibration, and dust between the two types of drills. The aim of this study was to compare these outcomes with similar mass electric rotary and pneumatic rock drills drilling into concrete block on a test bench system., Method: Three experiments were conducted on a test bench system to compare an electric (8.3 kg) and pneumatic drill (8.6 kg) on (1) noise and handle vibration, (2) respirable silica dust, and (3) drilling productivity. The test bench system repeatedly drilled 19 mm diameter x 100 mm depth holes into cured concrete block while the respective exposure levels were measured following ISO standards., Results: Productivity levels were similar between the electric and the pneumatic drill (9.09 mm/s vs. 8.69 mm/s ROP; p = 0.15). However, peak noise (L Peak : 117.7 vs. 139.4 dBC; p = 0.001), weighted total handle vibration (a hw : 7.15 vs. 39.14 m/s 2 ; p = 0.002), and respirable silica dust levels (0.55 vs. 22.23 mg/m 3 ; p = 0.003) were significantly lower for the electric than the pneumatic drill., Discussion: While there were no differences in drilling productivity between an electric and pneumatic drill of similar mass, there were substantial differences in exposure levels of noise, handle vibration, and respirable silica dust. Structural contractors should switch from pneumatic rock drills to electric rotary hammer drills for structural drilling into concrete in order to reduce worker exposures to the hazards of noise, hand vibration, and silica dust., (Copyright © 2018. Published by Elsevier Ltd.)

Published

2019

16. Nomination of controls of various layouts for heavy machinery.

Author

Chan AHS, Siu YS, and Hoffmann ER

Subjects

Equipment Design, Female, Humans, Male, Task Performance and Analysis, Young Adult, Construction Industry instrumentation, Man-Machine Systems

Abstract

Background: Control selection in heavy machinery may be a problem due to the poor compatibility of the commonly-used single line of vertical levers for controls., Objective: This study examined the effects of control arrangements on directional compatibility and participant responses in terms of choice/function of controls., Methods: We investigated experimentally, for a number of new designs of control arrangements, the selection of controls for requested functions of four different machines: fork lift trucks, excavators, tower cranes, and telescopic cranes. Control arrangements were designed with different levels of directional compatibility and participants were requested to nominate which control was related to each of the machine motions and to make ratings of certainty of response. A second part required participants to rank the various control arrangements in terms of their compatibility., Results: The in-line control arrangement was worst for each machine and increased directional compatibility improved the stereotype strength, certainty of response and ranking of control arrangement., Conclusions: Directional compatibility is the main factor in the design of control/machine output arrangements due to its effect on stereotype strength and correct selection of control of a given function.

Published

2019

17. Influences of different exoskeleton designs and tool mass on physical demands and performance in a simulated overhead drilling task.

Author

Alabdulkarim S and Nussbaum MA

Subjects

Adult, Computer Simulation, Female, Humans, Male, Muscle, Skeletal physiology, Shoulder physiology, Weight-Bearing physiology, Construction Industry instrumentation, Equipment Design, Ergonomics methods, Exoskeleton Device, Task Performance and Analysis

Abstract

We compared different passive exoskeletal designs in terms of physical demands (maximum acceptable frequency = MAF, perceived discomfort, and muscular loading) and quality in a simulated overhead drilling task, and the moderating influence of tool mass (∼2 and ∼5 kg). Three distinct designs were used: full-body and upper-body exoskeletons with attached mechanical arms; and an upper-body exoskeleton providing primarily shoulder support. Participants (n = 16, gender-balanced) simulated drilling for 15 min to determine their MAF, then maintained this pace for three additional minutes while the remaining outcome measures were obtained. The full-body/upper-body devices led to the lowest/highest MAF for females and the lowest quality. The shoulder support design reduced peak shoulder muscle loading but did not significantly affect either quality or MAF. Differences between exoskeleton designs were largely consistent across the two tool masses. These results may be helpful to (re)design exoskeletons to help reduce injury risk and improve performance., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2019

18. Unstable behavior of segmental ring under various pressures and its discrete element simulation.

Author

Kikkawa N, Hiraoka N, Itoh K, and Orense RP

Subjects

Humans, Japan epidemiology, Pressure, Accidents, Occupational mortality, Construction Industry instrumentation, Equipment Failure

Abstract

In February 2012, a serious accident which resulted in five fatalities happened during a TBM-tunnel construction under the seabed in Japan. The cause of the accident appeared to be due to the Key-segment slipping out of the segment ring by the thrusting tailskin (wire brushes) of the TBM into the segment ring. This resulted in the collapse of the rings, causing the seabed ground and seawater to flow into the tunnel. We investigated how thin and thick segments without any circumferential joints behave under isotropic and anisotropic pressures using small-scale physical model. In the model tests, pressures were applied to the surroundings of the segment rings and the strains at each segment were measured in order to evaluate the damage. In addition, cases where lubrication on the contact area between the K- and B-segments was present or not were investigated and their discrete element simulations were also conducted.

Published

2018

19. Glance behavior as design indices of in-vehicle visual support system: A study using crane simulators.

Author

Chew JY, Ohtomi K, and Suzuki H

Subjects

Attention, Computer Simulation, Emotions, Equipment Design, Female, Humans, Male, Task Performance and Analysis, Construction Industry instrumentation, Data Display, Eye Movements, Fixation, Ocular

Abstract

A prediction model is used to predict subjective responses of crane operators with respect to different designs of In-Vehicle Visual Support (IVVS). Selected gaze metrics are used as objective metrics to minimize prejudice, which is commonly caused by subjective measures. Experiments are carried out using crane simulator to measure glance behavior of novice operators and the 3D perspective projection method is used for autonomous mapping of gaze fixations to dynamic Area-of-Interests (AOIs). Subjective responses, such as operators' emotion and usability of IVVS, are evaluated using the Likert scale of the Semantic Differential method. Correlation between gaze metrics and subjective responses is established using multiple linear regression. Glance behavior exhibits a statistically significant difference when information on IVVS is perceived as useful to ease operation and reduce tension. Despite this, there are no significant signs of distraction. Glance behavior is found to be a reliable sub-conscious indicator of subjective response and distraction. More importantly, the proposed gaze metrics are found to be a good representation of glance behavior, such as randomness and distribution of attention. The methods and findings are useful to evaluate impact of IVVS, which is becoming more common in many other applications., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

20. A Fall From a Scaffold, an Ignited Smartphone, and a Burn on the Buttocks.

Author

Bosch SH

Subjects

Adult, Burns physiopathology, Buttocks physiopathology, Humans, Male, Smartphone trends, Accidental Falls, Burns etiology, Buttocks injuries, Construction Industry instrumentation, Smartphone standards

Published

2018

21. Capture efficiency of portable high-efficiency air filtration devices used during building construction activities.

Author

Newcomer DA, LaPuma P, Brandys R, and Northcross A

Subjects

Air Pollutants, Occupational, Construction Industry instrumentation, Particle Size, Filtration instrumentation, Occupational Exposure prevention & control, Particulate Matter

Abstract

The portable high-efficiency air filtration (PHEAF) device is used to control particulate matter (PM) generated from construction-type activities occurring within the built environment. Examples of activities where PHEAF devices are mobilized include building renovation, asbestos abatement, remediation of microbial contamination, and lead-based paint projects. Designed for use on short-term, temporary projects the PHEAF device captures airborne PM using a high-efficiency particulate air (HEPA) filter. This study sought to evaluate the capture efficiency of the PHEAF device in a field setting. An aerosol generator and photometer were used to measure particle penetration through 85 PHEAF devices. Average overall capture efficiency ranged from 41.78% to ≥99.97% with more than 88% of the tests failing to achieve 99.97% capture efficiency. Approximately 73% of the PHEAF device sample population failed to demonstrate HEPA performance criteria during any test round. A higher occurrence of PM concentrations measured around the perimeter of the filter suggested the presence of bypass leakage. While PHEAF devices were effective in capturing a significant quantity of aerosol test agent, these findings suggest that routine testing of the PHEAF device should be conducted to validate performance.

Published

2018

22. Evaluation of postural sway and impact forces during ingress and egress of scissor lifts at elevations.

Author

Pan CS, Chiou SS, Kau TY, Wimer BM, Ning X, and Keane P

Subjects

Adolescent, Adult, Humans, Male, Movement, Occupational Health, Task Performance and Analysis, Young Adult, Accidental Falls prevention & control, Accidents, Occupational prevention & control, Construction Industry instrumentation, Equipment Design, Postural Balance

Abstract

Workers are at risk when entering (ingress) or exiting (egress) elevated scissor lifts. In this study, we recorded ground impact forces and postural sway from 22 construction workers while they performed ingress and egress between a scissor lift and an adjacent work surface with varying conditions: lift opening designs, horizontal and vertical gaps, and sloped work surfaces. We observed higher peak ground shear forces when using a bar-and-chain opening, with larger horizontal gap, with the lift surface more than 0.2 m below the work surface, and presence of a sloped (26°) work surface. Similar trends were observed for postural sway, except that the influence of vertical distance was not significant. To reduce slip/trip/fall risk and postural sway of workers while ingress or egress of an elevated scissor lift, we suggest scissor lifts be equipped with a gate-type opening instead of a bar-and-chain design. We also suggest the lift surface be placed no more than 0.2 m lower than the work surface and the horizontal gap between lift and work surfaces be as small as possible. Selecting a non-sloped surface to ingress or egress a scissor lift is also preferred to reduce risk., (Published by Elsevier Ltd.)

Published

2017

23. Effect of bit wear on hammer drill handle vibration and productivity.

Author

Antonucci A, Barr A, Martin B, and Rempel D

Subjects

Humans, Construction Industry instrumentation, Occupational Exposure analysis, Vibration

Abstract

The use of large electric hammer drills exposes construction workers to high levels of hand vibration that may lead to hand-arm vibration syndrome and other musculoskeletal disorders. The aim of this laboratory study was to investigate the effect of bit wear on drill handle vibration and drilling productivity (e.g., drilling time per hole). A laboratory test bench system was used with an 8.3 kg electric hammer drill and 1.9 cm concrete bit (a typical drill and bit used in commercial construction). The system automatically advanced the active drill into aged concrete block under feed force control to a depth of 7.6 cm while handle vibration was measured according to ISO standards (ISO 5349 and 28927). Bits were worn to 4 levels by consecutive hole drilling to 4 cumulative drilling depths: 0, 1,900, 5,700, and 7,600 cm. Z-axis handle vibration increased significantly (p<0.05) from 4.8 to 5.1 m/s 2 (ISO weighted) and from 42.7-47.6 m/s 2 (unweighted) when comparing a new bit to a bit worn to 1,900 cm of cumulative drilling depth. Handle vibration did not increase further with bits worn more than 1900 cm of cumulative drilling depth. Neither x- nor y-axis handle vibration was effected by bit wear. The time to drill a hole increased by 58% for the bit with 5,700 cm of cumulative drilling depth compared to a new bit. Bit wear led to a small but significant increase in both ISO weighted and unweighted z-axis handle vibration. Perhaps more important, bit wear had a large effect on productivity. The effect on productivity will influence a worker's allowable daily drilling time if exposure to drill handle vibration is near the ACGIH Threshold Limit Value. [1] Construction contractors should implement a bit replacement program based on these findings.

Published

2017

24. The Effects of Bit Wear on Respirable Silica Dust, Noise and Productivity: A Hammer Drill Bench Study.

Author

Carty P, Cooper MR, Barr A, Neitzel RL, Balmes J, and Rempel D

Subjects

Efficiency, Humans, Pilot Projects, Air Pollutants, Occupational analysis, Construction Industry instrumentation, Dust analysis, Inhalation Exposure analysis, Noise, Occupational adverse effects, Occupational Exposure analysis, Silicon Dioxide analysis, Work Performance standards

Abstract

Objectives: Hammer drills are used extensively in commercial construction for drilling into concrete for tasks including rebar installation for structural upgrades and anchor bolt installation. This drilling task can expose workers to respirable silica dust and noise. The aim of this pilot study was to evaluate the effects of bit wear on respirable silica dust, noise, and drilling productivity., Method: Test bits were worn to three states by drilling consecutive holes to different cumulative drilling depths: 0, 780, and 1560 cm. Each state of bit wear was evaluated by three trials (nine trials total). For each trial, an automated laboratory test bench system drilled 41 holes 1.3 cm diameter, and 10 cm deep into concrete block at a rate of one hole per minute using a commercially available hammer drill and masonry bits. During each trial, dust was continuously captured by two respirable and one inhalable sampling trains and noise was sampled with a noise dosimeter. The room was thoroughly cleaned between trials., Results: When comparing results for the sharp (0 cm) versus dull bit (1560 cm), the mean respirable silica increased from 0.41 to 0.74 mg m-3 in sampler 1 (P = 0.012) and from 0.41 to 0.89 mg m-3 in sampler 2 (P = 0.024); levels above the NIOSH recommended exposure limit of 0.05 mg m-3. Likewise, mean noise levels increased from 112.8 to 114.4 dBA (P < 0.00001). Drilling productivity declined with increasing wear from 10.16 to 7.76 mm s-1 (P < 0.00001)., Discussion: Increasing bit wear was associated with increasing respirable silica dust and noise and reduced drilling productivity. The levels of dust and noise produced by these experimental conditions would require dust capture, hearing protection, and possibly respiratory protection. The findings support the adoption of a bit replacement program by construction contractors., (© The Author 2017. Published by Oxford University Press on behalf of the British Occupational Hygiene Society.)

Published

2017

25. A patent landscape on application of microorganisms in construction industry.

Author

Dapurkar D and Telang M

Subjects

Biotechnology, Construction Industry methods, History, 20th Century, History, 21st Century, Construction Industry instrumentation, Construction Materials microbiology, Patents as Topic history

Abstract

Construction biotechnology includes research and development of construction materials and processes that make use of various microbes. The present technology landscape gives a perspective on how microbes have been used in construction industry as cement and concrete additives by analyzing patents filed in this technology arena. All patents related to the technology of interest published globally to date have been reviewed. The earliest patent filing in this technology domain was recorded in the year 1958 and the patenting activity reached its peak around mid to late 1990s. The early technology was mainly focused on microbial polysaccharides and other metabolic products as additives. Year 2002 onwards, biomineralization has taken precedence over the other technologies with consistent patent filings indicating a shift in innovation focus. Japan has been the global leader with highest number of patents filed on application of microbes in construction industry. Southeast University, China has topped the patent assignee list with maximum number of filings followed by Kajima Corp. and Shin-Etsu Chemical Co., Ltd. Most patent applications have claimed microbe based bio-products. Construction-related microbial technologies are mainly based on activity of different microorganisms such as urease-producing, acidogenic, halophilic, alkaliphilic, nitrate and iron-reducing bacteria. Sporosarcina pasteurii has been the most widely used microbe for biomineralization.

Published

2017

26. Toolmarks made by lathe chuck jaws.

Author

Finkelstein N, Aronson A, and Tsach T

Subjects

Crime, Humans, Manufacturing and Industrial Facilities, Microscopy, Construction Industry instrumentation, Forensic Ballistics methods, Metals, Weapons

Abstract

This paper presents a forensic method to evidentially tie a workpiece with a specific lathe. Examining using this method can prove or exclude a connection between the two. The importance of this method is mostly due to the growing trend among lawbreakers of manufacturing improvised firearm parts using machining processes. This method is based on comparing jaw impressions made by the chuck on a workpiece., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

27. Self-Inflicted Nailgun-Induced Penetrating Penile Injury: Case Report and Discussion.

Author

Hernandez JM, Hamilton D, and Upadhye S

Subjects

Emergency Service, Hospital, Emergency Treatment methods, Follow-Up Studies, Humans, Injury Severity Score, Male, Middle Aged, Occupational Injuries diagnosis, Risk Assessment, Treatment Outcome, Wounds, Penetrating etiology, Wounds, Penetrating physiopathology, Construction Industry instrumentation, Device Removal, Nerve Block methods, Occupational Injuries surgery, Wounds, Penetrating surgery

Abstract

Penetrating penile injuries occur mostly in industrial/work accidents, automobile accidents, or as a result of sexual curiosity and attempts at self-expression/mutilation. In this case report, the authors describe an accidental nailgun injury to the penis of a 46-year-old man. We discuss the management of such injuries in the emergency department, including the utility of a dorsal penile block for regional anesthesia. Although exceptionally rare, familiarity with penetrating lower urinary tract injuries may reduce their long-term repercussions on genitourinary and sexual health.

Published

2017

28. Analytical characterization of movements of the spinal column and risk assessment due to repeated movements of the upper limbs of building painters.

Author

Antonucci A, Forcella L, Bonfiglioli R, Boscolo P, and Violante FS

Subjects

Cumulative Trauma Disorders epidemiology, Humans, Lifting, Musculoskeletal Diseases epidemiology, Posture, Risk Assessment, Video Recording, Construction Industry instrumentation, Construction Industry methods, Movement, Spine physiopathology, Upper Extremity physiopathology

Abstract

Manual activities of construction workers may induce musculoskeletal disorders. This study on a group of painters aimed to analytically characterize movements of the spinal column by both lumbar motion monitor and television cameras and to determine, using the Occupational Repetitive Actions (OCRA) Index method, the risk exerted by repeated movements of the upper limbs. The main results are: painting with a roller generally exposes workers to a lesser risk for upper limbs than painting with a brush; a roller-stick fixed at the wrong length can lead to stretching of the back at lumbar and cervical levels; to remain within the range of 'acceptable risk' (OCRA Index evaluation), a worker should not paint a vertical wall for over 3 h if using a roller and 2.5 h if painting with a brush; and, on average, a painter who paints for 5 h in a day lifts the bucket about 120,140 times.

Published

2016

29. Does drywall installers' innovative idea reduce the ergonomic exposures of ceiling installation: A field case study.

Author

Dasgupta PS, Punnett L, Moir S, Kuhn S, and Buchholz B

Subjects

Adult, Biomechanical Phenomena, Construction Industry methods, Construction Materials, Focus Groups, Humans, Male, Middle Aged, Musculoskeletal Diseases etiology, Musculoskeletal Diseases prevention & control, Occupational Diseases etiology, Occupational Diseases prevention & control, Young Adult, Construction Industry instrumentation, Ergonomics, Occupational Exposure prevention & control

Abstract

Objective: The study was conducted to assess an intervention suggested by the workers to reduce the physical or ergonomic exposures of the drywall installation task., Methods: The drywall installers were asked to brainstorm on innovative ideas that could reduce their ergonomic exposures during the drywall installation work. The workers proposed the idea of using a 'deadman' (narrow panel piece) to hold the panels to the ceiling while installing them. The researcher collected quantitative exposure data (PATH, 3DSSPP) at the baseline and intervention phases and compared the phases to find out any change in the exposure while using the 'deadman'., Results: Results showed that ergonomic exposures (such as overhead arm and awkward trunk postures and heavy load handling) were reduced at the intervention phase while using the 'deadman' with an electrically operated lift., Conclusion: The concept of the 'deadman', which was shown to help reduce musculoskeletal exposures during ceiling installation, can be used to fabricate a permanent ergonomic tool to support the ceiling drywall panel., (Copyright © 2016 Elsevier Ltd and The Ergonomics Society. All rights reserved.)

Published

2016

30. Object Detection for Agricultural and Construction Environments Using an Ultrasonic Sensor.

Author

Dvorak JS, Stone ML, and Self KP

Subjects

Agriculture instrumentation, Animals, Construction Industry instrumentation, Dogs, Humans, Agriculture methods, Construction Industry methods, Ultrasonics

Abstract

This study tested an ultrasonic sensor's ability to detect several objects commonly encountered in outdoor agricultural or construction environments: a water jug, a sheet of oriented strand board (OSB), a metalfence post, a human model, a wooden fence post, a Dracaena plant, a juniper plant, and a dog model. Tests were performed with each target object at distances from 0.01 to 3 m. Five tests were performed with each object at each location, and the sensor's ability to detect the object during each test was categorized as "undetected," "intermittent," "incorrect distance," or "good." Rigid objects that presented a larger surface area to the sensor, such as the water jug and OSB, were better detected than objects with a softer surface texture, which were occasionally not detected as the distance approached 3 m. Objects with extremely soft surface texture, such as the dog model, could be undetected at almost any distance from the sensor. The results of this testing should help designers offuture systems for outdoor environments, as the target objects tested can be found in nearly any agricultural or construction environment.

Published

2016

31. Control of standing balance while using constructions stilts: comparison of expert and novice users.

Author

Noble JW, Singer JC, and Prentice SD

Subjects

Adult, Biomechanical Phenomena, Healthy Volunteers, Humans, Professional Competence, Construction Industry instrumentation, Orthotic Devices, Postural Balance physiology, Posture physiology

Abstract

This study examined the control of standing balance while wearing construction stilts. Motion capture data were collected from nine expert stilt users and nine novices. Three standing conditions were analysed: ground, 60 cm stilts and an elevated platform. Each task was also performed with the head extended as a vestibular perturbation. Both expert and novice groups exhibited lower displacement of the whole body centre of mass and centre of pressure on construction stilts. Differences between the groups were only noted in the elevated condition with no stilts, where the expert group had lower levels of medial-lateral displacement of the centre of pressure. The postural manipulation revealed that the expert group had superior balance to the novice group. Conditions where stilts were worn showed lower levels of correspondence to the inverted pendulum model. Under normal conditions, both expert and novice groups were able to control their balance while wearing construction stilts., Practitioner Summary: This work investigated the effects of experience on the control of balance while using construction stilts. Under normal conditions, expert and novice stilt users were able to control their balance while wearing construction stilts. Differences between the expert and novice users were revealed when the balance task was made more difficult, with the experts showing superior balance in these situations.

Published

2016

32. Nail gun injuries treated in U.S emergency departments, 2006-2011: not just a worker safety issue.

Author

Lipscomb HJ and Schoenfisch AL

Subjects

Construction Materials, Consumer Product Safety, Equipment Design, Equipment Failure Analysis, Humans, Occupational Injuries etiology, United States, Wounds, Penetrating etiology, Accidents, Home statistics & numerical data, Construction Industry instrumentation, Construction Industry statistics & numerical data, Emergency Service, Hospital statistics & numerical data, Occupational Injuries epidemiology, Wounds, Penetrating epidemiology

Abstract

Background: Nail guns increase productivity in residential building but with a corresponding increase in worker injuries. They are also easily accessible, at low cost, to consumers., Methods: Data from the occupational supplement to the National Electronic Injury Surveillance System (NEISS-Work) were used to calculate national estimates of work-related injuries from nail guns between 2006 and 2011. These were compared to estimates of consumer injuries obtained through online access to the Consumer Product Safety Commission's (CPSC) NEISS data., Results: Approximately 25,000 ED-treated work-related and consumer nail gun injuries were estimated each year. During the construction economy collapse, injuries among workers declined markedly, closely following patterns of reduced residential employment. Reduction in consumer injuries was much more modest., Conclusions: Current nail gun injury patterns suggest marked blurring of work and home exposures. A united effort of CPSC, NIOSH, and OSHA is warranted to address these preventable injuries., (© 2015 Wiley Periodicals, Inc.)

Published

2015

33. Laboratory and workplace assessments of rivet bucking bar vibration emissions.

Author

McDowell TW, Warren C, Xu XS, Welcome DE, and Dong RG

Subjects

Aircraft, Construction Industry instrumentation, Hand, Hand-Arm Vibration Syndrome prevention & control, Humans, Occupational Diseases, Occupational Exposure adverse effects, Risk Assessment, Laboratories, Occupational Exposure analysis, Vibration adverse effects, Workplace

Abstract

Sheet metal workers operating rivet bucking bars are at risk of developing hand and wrist musculoskeletal disorders associated with exposures to hand-transmitted vibrations and forceful exertions required to operate these hand tools. New bucking bar technologies have been introduced in efforts to reduce workplace vibration exposures to these workers. However, the efficacy of these new bucking bar designs has not been well documented. While there are standardized laboratory-based methodologies for assessing the vibration emissions of many types of powered hand tools, no such standard exists for rivet bucking bars. Therefore, this study included the development of a laboratory-based method for assessing bucking bar vibrations which utilizes a simulated riveting task. With this method, this study evaluated three traditional steel bucking bars, three similarly shaped tungsten alloy bars, and three bars featuring spring-dampeners. For comparison the bucking bar vibrations were also assessed during three typical riveting tasks at a large aircraft maintenance facility. The bucking bars were rank-ordered in terms of unweighted and frequency-weighted acceleration measured at the hand-tool interface. The results suggest that the developed laboratory method is a reasonable technique for ranking bucking bar vibration emissions; the lab-based riveting simulations produced similar rankings to the workplace rankings. However, the laboratory-based acceleration averages were considerably lower than the workplace measurements. These observations suggest that the laboratory test results are acceptable for comparing and screening bucking bars, but the laboratory measurements should not be directly used for assessing the risk of workplace bucking bar vibration exposures. The newer bucking bar technologies exhibited significantly reduced vibrations compared to the traditional steel bars. The results of this study, together with other information such as rivet quality, productivity, tool weight, comfort, worker acceptance, and initial cost can be used to make informed bucking bar selections., (Published by Oxford University Press on behalf of the British Occupational Hygiene Society 2014.)

Published

2015

34. Musculoskeletal concerns do not justify failure to use safer sequential trigger to prevent acute nail gun injuries.

Author

Lipscomb HJ, Nolan J, and Patterson D

Subjects

Construction Industry statistics & numerical data, Equipment Design adverse effects, Humans, Midwestern United States epidemiology, Musculoskeletal Diseases etiology, Occupational Health, Occupational Injuries prevention & control, Risk Factors, Surveys and Questionnaires, Wounds, Penetrating prevention & control, Construction Industry instrumentation, Musculoskeletal Diseases epidemiology, Occupational Injuries epidemiology, Population Surveillance, Wounds, Penetrating epidemiology

Abstract

Background: Acute nail gun injuries can be controlled significantly by using tools with sequential triggers and training. Concern has been raised that sequential triggers, which require that the nose piece of the gun be depressed prior to pulling the trigger, could increase risk of musculoskeletal problems., Methods: We conducted active injury surveillance among union carpenter apprentices to monitor acute injuries and musculoskeletal disorders between 2010 and 2013., Results: Acute injury risk was 70% higher with contact trip rather than sequential triggers. Musculoskeletal risk was comparable (contact trip 0.09/10,000 hr (95% CI, 0.02-0.26); sequential 0.08/ 10,000 hr (95% CI 0.02-0.23))., Conclusions: Concern about excess risk of musculoskeletal problems from nail guns with sequential triggers is unwarranted. Both actuation systems carry comparable musculoskeletal risk which is far less than the risk of acute injury; there is clearly no justification for failure to prevent acute injuries through use of the safer sequential trigger., (© 2015 Wiley Periodicals, Inc.)

Published

2015

35. Reducing the risk of injury from table saw use: the potential benefits and costs of automatic protection.

Author

Graham JD and Chang J

Subjects

Accidents, Home economics, Accidents, Occupational economics, Amputation, Traumatic economics, Amputation, Traumatic epidemiology, Amputation, Traumatic prevention & control, Automation economics, Construction Industry instrumentation, Cost-Benefit Analysis, Finger Injuries economics, Finger Injuries epidemiology, Finger Injuries prevention & control, Health Care Costs, Humans, Protective Devices statistics & numerical data, United States epidemiology, Accidents, Home prevention & control, Accidents, Occupational prevention & control, Risk Reduction Behavior, Wood

Abstract

The use of table saws in the United States is associated with approximately 28,000 emergency department (ED) visits and 2,000 cases of finger amputation per year. This article provides a quantitative estimate of the economic benefits of automatic protection systems that could be designed into new table saw products. Benefits are defined as reduced health-care costs, enhanced production at work, and diminished pain and suffering. The present value of the benefits of automatic protection over the life of the table saw are interpreted as the switch-point cost value, the maximum investment in automatic protection that can be justified by benefit-cost comparison. Using two alternative methods for monetizing pain and suffering, the study finds switch-point cost values of $753 and $561 per saw. These point estimates are sensitive to the values of inputs, especially the average cost of injury. The various switch-point cost values are substantially higher than rough estimates of the incremental cost of automatic protection systems. Uncertainties and future research needs are discussed., (© 2014 Society for Risk Analysis.)

Published

2015

36. Prevention of falls to a lower level: evaluation of an occupational health and safety intervention via subsidies for the replacement of scaffolding.

Author

Rubio-Romero JC, Carrillo-Castrillo JA, and Gibb A

Subjects

Accidents, Occupational trends, Case-Control Studies, Financing, Government, Humans, Occupational Health, Spain, Accidental Falls prevention & control, Accidents, Occupational prevention & control, Construction Industry instrumentation, Protective Devices economics, Safety Management methods

Abstract

The objective of this study is to evaluate the impact of a subsidy policy for construction companies in Andalusia (Spain), which enables them to acquire new scaffolds. The rate of falls from scaffolds within the Andalusian construction sector in the period 2009-2011 was analysed. A randomised controlled trial was not possible as the subsidy was granted according to a public and competitive call. A quasi-experimental design based on an intervention group (subsidised companies) and a control group was chosen. Companies in the control group were selected from the social security census of companies in order to avoid selection bias. The subsidy policy has led to an overall 71% decrease in the rate of accident involving falls to a lower level in the companies that received grants in the period 2009-2011. The confidence interval for the comparison for the before-after difference in rates between the intervention group and the control group is found significant (confidence 95%, p = 0.05). The improvement of scaffolds was effective in reducing rates of accident with falls to a lower level. This intervention should be a priority in public policies. The process of standardisation of equipment with high accident risk should be developed further.

Published

2015

37. Analysis of labour accidents in tunnel construction and introduction of prevention measures.

Author

Kikkawa N, Itoh K, Hori T, Toyosawa Y, and Orense RP

Subjects

Accidents, Occupational trends, Construction Industry instrumentation, Humans, Japan, Occupational Health, Accidents, Occupational prevention & control, Accidents, Occupational statistics & numerical data, Construction Industry methods, Safety Management methods

Abstract

At present, almost all mountain tunnels in Japan are excavated and constructed utilizing the New Austrian Tunneling Method (NATM), which was advocated by Prof. Rabcewicz of Austria in 1964. In Japan, this method has been applied to tunnel construction since around 1978, after which there has been a subsequent decrease in the number of casualties during tunnel construction. However, there is still a relatively high incidence of labour accidents during tunnel construction when compared to incidence rates in the construction industry in general. During tunnel construction, rock fall events at the cutting face are a particularly characteristic of the type of accident that occurs. In this study, we analysed labour accidents that possess the characteristics of a rock fall event at a work site. We also introduced accident prevention measures against rock fall events.

Published

2015

38. Emergency navigation without an infrastructure.

Author

Gelenbe E and Bi H

Subjects

Algorithms, Construction Industry instrumentation, Electric Power Supplies, Emergencies, Humans, Reproducibility of Results, Time Factors, Computer Communication Networks instrumentation, Wireless Technology instrumentation

Abstract

Emergency navigation systems for buildings and other built environments, such as sport arenas or shopping centres, typically rely on simple sensor networks to detect emergencies and, then, provide automatic signs to direct the evacuees. The major drawbacks of such static wireless sensor network (WSN)-based emergency navigation systems are the very limited computing capacity, which makes adaptivity very difficult, and the restricted battery power, due to the low cost of sensor nodes for unattended operation. If static wireless sensor networks and cloud-computing can be integrated, then intensive computations that are needed to determine optimal evacuation routes in the presence of time-varying hazards can be offloaded to the cloud, but the disadvantages of limited battery life-time at the client side, as well as the high likelihood of system malfunction during an emergency still remain. By making use of the powerful sensing ability of smart phones, which are increasingly ubiquitous, this paper presents a cloud-enabled indoor emergency navigation framework to direct evacuees in a coordinated fashion and to improve the reliability and resilience for both communication and localization. By combining social potential fields (SPF) and a cognitive packet network (CPN)-based algorithm, evacuees are guided to exits in dynamic loose clusters. Rather than relying on a conventional telecommunications infrastructure, we suggest an ad hoc cognitive packet network (AHCPN)-based protocol to adaptively search optimal communication routes between portable devices and the network egress nodes that provide access to cloud servers, in a manner that spares the remaining battery power of smart phones and minimizes the time latency. Experimental results through detailed simulations indicate that smart human motion and smart network management can increase the survival rate of evacuees and reduce the number of drained smart phones in an evacuation process.

Published

2014

39. A real-time recording model of key indicators for energy consumption and carbon emissions of sustainable buildings.

Author

Wu W, Yang H, Chew D, Hou Y, and Li Q

Subjects

China, Computer Simulation, Computer Systems, Construction Industry instrumentation, Environmental Monitoring instrumentation, Renewable Energy, Carbon Footprint, Construction Industry methods, Ecosystem, Energy Metabolism, Energy-Generating Resources, Environmental Monitoring methods, Models, Theoretical

Abstract

Buildings' sustainability is one of the crucial parts for achieving urban sustainability. Applied to buildings, life-cycle assessment encompasses the analysis and assessment of the environmental effects of building materials, components and assemblies throughout the entire life of the building construction, use and demolition. Estimate of carbon emissions is essential and crucial for an accurate and reasonable life-cycle assessment. Addressing the need for more research into integrating analysis of real-time and automatic recording of key indicators for a more accurate calculation and comparison, this paper aims to design a real-time recording model of these crucial indicators concerning the calculation and estimation of energy use and carbon emissions of buildings based on a Radio Frequency Identification (RFID)-based system. The architecture of the RFID-based carbon emission recording/tracking system, which contains four functional layers including data record layer, data collection/update layer, data aggregation layer and data sharing/backup layer, is presented. Each of these layers is formed by RFID or network devices and sub-systems that operate at a specific level. In the end, a proof-of-concept system is developed to illustrate the implementation of the proposed architecture and demonstrate the feasibility of the design. This study would provide the technical solution for real-time recording system of building carbon emissions and thus is of great significance and importance to improve urban sustainability.

Published

2014

40. Development of hybrid braided composite rods for reinforcement and health monitoring of structures.

Author

Rana S, Zdraveva E, Pereira C, Fangueiro R, and Correia AG

Subjects

Carbon Fiber, Construction Industry instrumentation, Construction Industry methods, Weight-Bearing, Carbon, Construction Materials, Glass, Stress, Mechanical

Abstract

In the present study, core-reinforced braided composite rods (BCRs) were developed and characterized for strain sensing capability. A mixture of carbon and glass fibre was used in the core, which was surrounded by a braided cover of polyester fibres. Three compositions of core with different carbon fibre/glass fibre weight ratios (23/77, 47/53, and 100/0) were studied to find out the optimum composition for both strain sensitivity and mechanical performance. The influence of carbon fibre positioning in BCR cross-section on the strain sensing behaviour was also investigated. Strain sensing property of BCRs was characterized by measuring the change in electrical resistance with flexural strain. It was observed that BCRs exhibited increase (positive response) or decrease (negative response) in electrical resistance depending on carbon fibre positioning. The BCR with lowest amount of carbon fibre was found to give the best strain sensitivity as well as the highest tensile strength and breaking extension. The developed BCRs showed reversible strain sensing behaviour under cyclic flexural loading with a maximum gauge factor of 23.4 at very low strain level (0.55%). Concrete beams reinforced with the optimum BCR (23/77) also exhibited strain sensing under cyclic flexural strain, although the piezoresistive behaviour in this case was irreversible.

Published

2014

41. Case study on the maintenance of a construction monitoring using USN-based data acquisition.

Author

Kim S, Shin Y, and Kim GH

Subjects

Construction Industry instrumentation, Construction Industry methods, Wireless Technology instrumentation

Abstract

In recent years, there has been an increasing interest in the adoption of emerging ubiquitous sensor network (USN) technologies for instrumentation within a variety of sustainability systems. USN is emerging as a sensing paradigm that is being newly considered by the sustainability management field as an alternative to traditional tethered monitoring systems. Researchers have been discovering that USN is an exciting technology that should not be viewed simply as a substitute for traditional tethered monitoring systems. In this study, we investigate how a movement monitoring measurement system of a complex building is developed as a research environment for USN and related decision-supportive technologies. To address the apparent danger of building movement, agent-mediated communication concepts have been designed to autonomously manage large volumes of exchanged information. In this study, we additionally detail the design of the proposed system, including its principles, data processing algorithms, system architecture, and user interface specifics. Results of the test and case study demonstrate the effectiveness of the USN-based data acquisition system for real-time monitoring of movement operations.

Published

2014

42. Anaerobic baffled reactor coupled with chemical precipitation for treatment and toxicity reduction of industrial wastewater.

Author

Laohaprapanona S, Marquesa M, and Hogland W

Subjects

Cell Survival drug effects, Chemical Precipitation, Construction Industry instrumentation, Equipment Design, Equipment Failure Analysis, Oxygen metabolism, Wastewater chemistry, Water Pollutants, Chemical chemistry, Water Purification instrumentation, Bacteria, Anaerobic drug effects, Bacteria, Anaerobic metabolism, Bioreactors microbiology, Industrial Waste prevention & control, Waste Disposal, Fluid instrumentation, Wastewater toxicity, Water Pollutants, Chemical toxicity

Abstract

This study describes the reduction of soluble chemical oxygen demand (CODs) and the removal of dissolved organic carbon (DOC), formaldehyde (FA) and nitrogen from highly polluted wastewater generated during cleaning procedures in wood floor manufacturing using a laboratory-scale biological anaerobic baffled reactor followed by chemical precipitation using MgCI2 .6H20 + Na2HPO4. By increasing the hydraulic retention time from 2.5 to 3.7 and 5 days, the reduction rates of FA, DOC and CODs of nearly 100%, 90% and 83%, respectively, were achieved. When the Mg:N:P molar ratio in the chemical treatment was changed from 1:1:1 to 1.3:1:1.3 at pH 8, the NH4+ removal rate increased from 80% to 98%. Biologically and chemically treated wastewater had no toxic effects on Vibrio fischeri and Artemia salina whereas chemically treated wastewater inhibited germination of Lactuca sativa owing to a high salt content. Regardless of the high conductivity of the treated wastewater, combined biological and chemical treatment was found to be effective for the removal of the organic load and nitrogen, and to be simple to operate and to maintain. A combined process such as that investigated could be useful for on-site treatment of low volumes of highly polluted wastewater generated by the wood floor and wood furniture industries, for which there is no suitable on-site treatment option available today.

Published

2014

43. An evaluation of an aftermarket local exhaust ventilation device for suppressing respirable dust and respirable crystalline silica dust from powered saws.

Author

Garcia A, Jones E, Echt AS, and Hall RM

Subjects

Colorado, Construction Materials, Dust analysis, Environmental Monitoring methods, Equipment Design, Humans, United States, Air Pollutants, Occupational analysis, Construction Industry instrumentation, Dust prevention & control, Inhalation Exposure analysis, Occupational Exposure prevention & control, Silicon Dioxide analysis, Ventilation instrumentation

Abstract

The objective of this study was to quantify the respirable dust and respirable silica exposures of roofing workers using an electric-powered circular saw with an aftermarket local exhaust ventilation attachment to cut concrete roofing tiles. The study was conducted to determine whether the local exhaust ventilation attachment was able to control respirable dust and respirable silica exposure below occupational exposure limits (OELs). Time-integrated filter samples and direct reading respirable dust concentrations were evaluated. The local exhaust ventilation consisted of a shroud attached to the cutting plane of the saw; the shroud was then connected to a small electric axial fan, which is intended to collect dust at the point of generation. All sampling was conducted with the control in use. Roofers are defined as those individuals who only lay tiles. Cutters/roofers are defined as those workers who operate the powered saw to cut tiles and also lay tiles. Respirable dust from this evaluation ranged from 0.13 to 6.59 milligrams per cubic meter (mg/m(3)) with a geometric mean of 0.38 mg/m(3) for roofers and from 0.45 to 3.82 mg/m(3) with a geometric mean of 1.84 mg/m(3) for cutters/roofers. Cutters/roofers usually handle areas close to crevices, edges, or tips of the roof whereas roofers handle areas where complete tiles can be placed. The respirable dust exposures for all cutters/roofers indicated concentrations exceeding the Occupational Safety and Health Administration's (OSHA) permissible exposure limit (PEL) for respirable dust containing silica; it was also exceeded for some of the roofers. The respirable silica concentrations ranged from 0.04 to 0.15 mg/m(3) with a geometric mean of 0.09 mg/m(3) for roofers, and from 0.13 to 1.21 mg/m(3) with a geometric mean of 0.48 mg/m(3) for cutters/roofers. As with respirable dust, the respirable silica exposures for cutters/roofers were higher than the exposures for roofers.

Published

2014

44. Structural monitoring of metro infrastructure during shield tunneling construction.

Author

Ran L, Ye XW, Ming G, and Dong XB

Subjects

Construction Industry instrumentation, Freezing, Soil chemistry, Construction Industry methods, Railroads standards

Abstract

Shield tunneling construction of metro infrastructure will continuously disturb the soils. The ground surface will be subjected to uplift or subsidence due to the deep excavation and the extrusion and consolidation of the soils. Implementation of the simultaneous monitoring with the shield tunnel construction will provide an effective reference in controlling the shield driving, while how to design and implement a safe, economic, and effective structural monitoring system for metro infrastructure is of great importance and necessity. This paper presents the general architecture of the shield construction of metro tunnels as well as the procedure of the artificial ground freezing construction of the metro-tunnel cross-passages. The design principles for metro infrastructure monitoring of the shield tunnel intervals in the Hangzhou Metro Line 1 are introduced. The detailed monitoring items and the specified alarming indices for construction monitoring of the shield tunneling are addressed, and the measured settlement variations at different monitoring locations are also presented.

Published

2014

45. Geometric nonlinear analysis of self-anchored cable-stayed suspension bridges.

Author

Hui-Li W, Yan-Bin T, Si-Feng Q, and Zhe Z

Subjects

Computer Simulation, Elastic Modulus, Equipment Design, Equipment Failure Analysis, Nonlinear Dynamics, Stress, Mechanical, Tensile Strength, Construction Industry instrumentation, Models, Theoretical, Transportation instrumentation

Abstract

Geometric nonlinearity of self-anchored cable-stayed suspension bridges is studied in this paper. The repercussion of shrinkage and creep of concrete, rise-to-span ratio, and girder camber on the system is discussed. A self-anchored cable-stayed suspension bridge with a main span of 800 m is analyzed with linear theory, second-order theory, and nonlinear theory, respectively. In the condition of various rise-to-span ratios and girder cambers, the moments and displacements of both the girder and the pylon under live load are acquired. Based on the results it is derived that the second-order theory can be adopted to analyze a self-anchored cable-stayed suspension bridge with a main span of 800 m, and the error is less than 6%. The shrinkage and creep of concrete impose a conspicuous impact on the structure. And it outmatches suspension bridges for system stiffness. As the rise-to-span ratio increases, the axial forces of the main cable and the girder decline. The system stiffness rises with the girder camber being employed.

Published

2013

46. Life comparative analysis of energy consumption and CO₂ emissions of different building structural frame types.

Author

Kim S, Moon JH, Shin Y, Kim GH, and Seo DS

Subjects

Carbon chemistry, Climate Change, Conservation of Energy Resources, Construction Industry economics, Environmental Monitoring methods, Gases, Greenhouse Effect, Materials Testing, Steel chemistry, Carbon Dioxide chemistry, Construction Industry instrumentation, Construction Materials

Abstract

The objective of this research is to quantitatively measure and compare the environmental load and construction cost of different structural frame types. Construction cost also accounts for the costs of CO₂ emissions of input materials. The choice of structural frame type is a major consideration in construction, as this element represents about 33% of total building construction costs. In this research, four constructed buildings were analyzed, with these having either reinforced concrete (RC) or steel (S) structures. An input-output framework analysis was used to measure energy consumption and CO₂ emissions of input materials for each structural frame type. In addition, the CO₂ emissions cost was measured using the trading price of CO₂ emissions on the International Commodity Exchange. This research revealed that both energy consumption and CO₂ emissions were, on average, 26% lower with the RC structure than with the S structure, and the construction costs (including the CO₂ emissions cost) of the RC structure were about 9.8% lower, compared to the S structure. This research provides insights through which the construction industry will be able to respond to the carbon market, which is expected to continue to grow in the future.

Published

2013

47. Dose-response relationship between hand-transmitted vibration and hand-arm vibration syndrome in a tropical environment.

Author

Su AT, Maeda S, Fukumoto J, Darus A, Hoe VC, Miyai N, Isahak M, Takemura S, Bulgiba A, Yoshimasu K, and Miyashita K

Subjects

Adult, Automobiles, Construction Industry instrumentation, Forestry instrumentation, Humans, Logistic Models, Malaysia epidemiology, Male, Middle Aged, Occupational Diseases etiology, Occupational Exposure analysis, Prevalence, Surveys and Questionnaires, Vibration, Hand-Arm Vibration Syndrome epidemiology, Occupational Diseases epidemiology, Occupational Exposure adverse effects, Tropical Climate

Abstract

Objectives: The dose-response relationship for hand-transmitted vibration has been investigated extensively in temperate environments. Since the clinical features of hand-arm vibration syndrome (HAVS) differ between the temperate and tropical environment, we conducted this study to investigate the dose-response relationship of HAVS in a tropical environment., Methods: A total of 173 male construction, forestry and automobile manufacturing plant workers in Malaysia were recruited into this study between August 2011 and 2012. The participants were interviewed for history of vibration exposure and HAVS symptoms, followed by hand functions evaluation and vibration measurement. Three types of vibration doses-lifetime vibration dose (LVD), total operating time (TOT) and cumulative exposure index (CEI)-were calculated and its log values were regressed against the symptoms of HAVS. The correlation between each vibration exposure dose and the hand function evaluation results was obtained., Results: The adjusted prevalence ratio for finger tingling and numbness was 3.34 (95% CI 1.27 to 8.98) for subjects with lnLVD≥20 ln m(2) s(-4) against those <16 ln m(2) s(-4). Similar dose-response pattern was found for CEI but not for TOT. No subject reported white finger. The prevalence of finger coldness did not increase with any of the vibration doses. Vibrotactile perception thresholds correlated moderately with lnLVD and lnCEI., Conclusions: The dose-response relationship of HAVS in a tropical environment is valid for finger tingling and numbness. The LVD and CEI are more useful than TOT when evaluating the dose-response pattern of a heterogeneous group of vibratory tools workers.

Published

2013

48. Optimal control for a parallel hybrid hydraulic excavator using particle swarm optimization.

Author

Wang DY and Guan C

Subjects

Computer Simulation, Equipment Design, Equipment Failure Analysis, Algorithms, Construction Industry instrumentation, Feedback, Models, Theoretical, Motor Vehicles

Abstract

Optimal control using particle swarm optimization (PSO) is put forward in a parallel hybrid hydraulic excavator (PHHE). A power-train mathematical model of PHHE is illustrated along with the analysis of components' parameters. Then, the optimal control problem is addressed, and PSO algorithm is introduced to deal with this nonlinear optimal problem which contains lots of inequality/equality constraints. Then, the comparisons between the optimal control and rule-based one are made, and the results show that hybrids with the optimal control would increase fuel economy. Although PSO algorithm is off-line optimization, still it would bring performance benchmark for PHHE and also help have a deep insight into hybrid excavators.

Published

2013

49. Anthropometric procedures for protective equipment sizing and design.

Author

Hsiao H

Subjects

Accidental Falls prevention & control, Adolescent, Adult, Aged, Agriculture instrumentation, Agriculture standards, Construction Industry instrumentation, Construction Industry standards, Equipment Design standards, Ergonomics standards, Female, Firefighters, Humans, Male, Middle Aged, Motor Vehicles standards, National Institute for Occupational Safety and Health, U.S. standards, Respiratory Protective Devices standards, United States, Workforce, Young Adult, Anthropometry, Equipment Design methods, Ergonomics methods, Protective Devices standards

Abstract

Objectives: This article presented four anthropometric theories (univariate, bivariate/probability distribution, multivariate, and shape-based methods) for protective equipment design decisions., Background: While the significance of anthropometric information for product design is well recognized, designers continue to face challenges in selecting efficient anthropometric data processing methods and translating the acquired information into effective product designs., Methods: For this study, 100 farm tractor operators, 3,718 respirator users, 951 firefighters, and 816 civilian workers participated in four studies on the design of tractor roll-over protective structures (ROPS), respirator test panels, fire truck cabs, and fall-arrest harnesses, respectively. Their anthropometry and participant-equipment interfaces were evaluated., Results: Study I showed a need to extend the 90-cm vertical clearance for tractor ROPS in the current industrial standards to 98.3 to 101.3 cm. Study 2 indicated that current respirator test panel would have excluded 10% of the male firefighter population; a systematic adjustment to the boundaries of test panel cells was suggested. Study 3 provided 24 principal component analysis-based firefighter body models to facilitate fire truck cab design. Study 4 developed an improved gender-based fall-arrest harness sizing scheme to supplant the current unisex system., Conclusions: This article presented four anthropometric approaches and a six-step design paradigm for ROPS, respirator test panel, fire truck cab, and fall-arrest harness applications, which demonstrated anthropometric theories and practices for defining protective equipment fit and sizing schemes., Applications: The study provided a basis for equipment designers, standards writers, and industry manufacturers to advance anthropometric applications for product design and improve product efficacy.

Published

2013

50. Laboratory and field measurements and evaluations of vibration at the handles of riveting hammers.

Author

McDowell TW, Warren C, Welcome DE, and Dong RG

Subjects

Hand-Arm Vibration Syndrome pathology, Humans, Occupational Diseases diagnosis, Occupational Diseases etiology, Occupational Exposure adverse effects, Construction Industry instrumentation, Hand-Arm Vibration Syndrome prevention & control, Occupational Exposure analysis, Risk Assessment, Vibration adverse effects

Abstract

The use of riveting hammers can expose workers to harmful levels of hand-transmitted vibration (HTV). As a part of efforts to reduce HTV exposures through tool selection, the primary objective of this study was to evaluate the applicability of a standardized laboratory-based riveting hammer assessment protocol for screening riveting hammers. The second objective was to characterize the vibration emissions of reduced vibration riveting hammers and to make approximations of the HTV exposures of workers operating these tools in actual work tasks. Eight pneumatic riveting hammers were selected for the study. They were first assessed in a laboratory using the standardized method for measuring vibration emissions at the tool handle. The tools were then further assessed under actual working conditions during three aircraft sheet metal riveting tasks. Although the average vibration magnitudes of the riveting hammers measured in the laboratory test were considerably different from those measured in the field study, the rank orders of the tools determined via these tests were fairly consistent, especially for the lower vibration tools. This study identified four tools that consistently exhibited lower frequency-weighted and unweighted accelerations in both the laboratory and workplace evaluations. These observations suggest that the standardized riveting hammer test is acceptable for identifying tools that could be expected to exhibit lower vibrations in workplace environments. However, the large differences between the accelerations measured in the laboratory and field suggest that the standardized laboratory-based tool assessment is not suitable for estimating workplace riveting hammer HTV exposures. Based on the frequency-weighted accelerations measured at the tool handles during the three work tasks, the sheet metal mechanics assigned to these tasks at the studied workplace are unlikely to exceed the daily vibration exposure action value (2.5 m s(-2)) using any of the evaluated riveting hammers.

Published

2012