Introduction

Workplace Safety Statistics: Do you think your workplace is dangerous? If you work in high-risk areas like law enforcement, emergency services, or agriculture, you might. But accidents can happen in any job, from offices to construction sites. Falls cause injuries to millions of workers each year, whether they’re in retail, admin, or on a construction site. Workplace accidents are a problem for everyone.

They lead to medical and insurance costs, lost productivity, and lost wages. Plus, they can lower morale and engagement among employees. To tackle these issues, it’s important to understand Workplace Safety Statistics. Let’s look at some interesting numbers.

In 2023, *** accidents occurred in the construction sector in Malaysia. This was higher compared to the number of construction accidents reported in the previous year. Nevertheless, Malaysia has seen fewer accidents in the past four years after a record number of *** in 2019. Workplace safety needs improvement Safety in the workplace is essential and regulated by the 1994 Malaysian Occupational Safety and Health Act. Construction site workers are especially at risk because they often have to work on high surfaces, carry heavy tools, and deal with loud noises. The Malaysian Department of Occupational Safety and Health (DOSH) said that employers might overlook common workplace hazards that can cause injuries or even death. In 2023, ** of these The value of construction work increased to around ***** billion Malaysian ringgit in 2024, and it is expected to increase again this year. With more than *** million

The graph illustrates the annual fatalities among construction workers in the United States from 2018 to 2023. The x-axis displays the years, labeled with abbreviated two-digit numbers from '18 to '23, while the y-axis represents the total number of deaths recorded each year. Over this five-year span, the fatalities range from a low of 951 in 2021 to a high of 1,066 in 2019. The data shows fluctuations in annual deaths, with a decrease in fatalities in 2020 and 2021 followed by an increase in 2022. The graph provides a visual representation of the trends in construction worker fatalities during this period.

In 2022, the highest number of fatal industrial accidents occurred in the construction industry with *** cases, followed by the tertiary industry with *** casualties. That year, the total number of fatalities caused by work accidents amounted to *** cases.

In 2023, the workplace fatal injury rate of the construction sector in Singapore was 3.4 fatal injuries per 100,000 employed persons. The rate has gone up as fewer workers in construction were employed in 2021.

Construction Safety Monitoring Systems Market Outlook

The global construction safety monitoring systems market size was valued at approximately USD 3.2 billion in 2023, and it is projected to reach USD 7.8 billion by 2032, growing at a compound annual growth rate (CAGR) of 10.5% during the forecast period. The market is witnessing robust growth driven by increasing awareness about occupational safety, stringent regulatory requirements, and technological advancements in safety monitoring solutions.

One of the primary growth factors for the construction safety monitoring systems market is the rising awareness and emphasis on workplace safety. Construction sites are inherently hazardous environments with numerous risks, including falls, machinery accidents, and exposure to harmful substances. Governments and regulatory bodies across the globe are enforcing stringent safety regulations to mitigate these risks, thereby driving the demand for advanced safety monitoring systems. In addition to regulatory scrutiny, the increasing cost of workplace injuries and the subsequent financial losses are compelling construction companies to invest in reliable safety monitoring solutions.

Technological advancements are another crucial growth factor for the construction safety monitoring systems market. Innovations such as the Internet of Things (IoT), artificial intelligence (AI), and big data analytics are being integrated into safety monitoring systems, enhancing their efficiency and effectiveness. IoT-enabled sensors and wearable devices can continuously monitor workers' health and safety parameters, providing real-time alerts for any deviations from safe conditions. AI and machine learning algorithms can analyze data from these devices to predict potential hazards and prevent accidents before they occur. The integration of these advanced technologies is significantly improving the overall safety standards on construction sites.

The growing trend of smart cities and infrastructure development projects worldwide is also contributing to the market's growth. Governments and private sector entities are investing heavily in the construction of smart cities, which require the implementation of advanced safety monitoring systems to ensure the safety of workers and the public. The increasing number of infrastructure projects, such as highways, bridges, and tunnels, further fuels the demand for robust safety monitoring solutions. These projects involve complex and hazardous construction processes that necessitate the use of advanced safety systems to prevent accidents and ensure smooth operations.

The integration of Construction Safety Wearables is revolutionizing the way safety is managed on construction sites. These wearables, equipped with IoT-enabled sensors, are designed to monitor workers' health and environmental conditions in real-time. They can track vital signs such as heart rate, body temperature, and even detect falls or prolonged inactivity, providing immediate alerts to supervisors. This proactive approach not only enhances worker safety but also helps in reducing the response time during emergencies. By providing real-time data, construction safety wearables enable companies to make informed decisions, ensuring a safer working environment. As the adoption of these devices increases, they are becoming an integral part of the construction safety monitoring systems, contributing significantly to the market's growth.

Regionally, North America currently holds the largest market share in the construction safety monitoring systems market, primarily due to stringent safety regulations and the presence of major construction companies. The Asia Pacific region, however, is expected to witness the highest growth rate during the forecast period. Rapid industrialization, urbanization, and infrastructure development in countries like China and India are driving the demand for construction safety monitoring systems in this region. Additionally, increasing awareness about workplace safety and government initiatives to improve safety standards are further propelling the market growth in the Asia Pacific.

Component Analysis

The construction safety monitoring systems market can be segmented into three primary components: hardware, software, and services. Each of these components plays a crucial role in the overall functionality and effectiveness of safety monitoring systems, catering to different aspects of construction site safety management.<

In 2021, there were ** work-related deaths less in the construction industry of the United States than in the previous year. The number of fatal injuries in construction increased significantly during the last decade and peaked in 2020. While *** people died in this industry in 2011, by 2020 that number increased to *****.

This is an API that allows you to look up the daily status of major accidents in the construction industry. It provides work type, cause, accident type, accident overview, and risk reduction measures. ※ callApiId = 1010 (Required as a fixed value) ※ This data analyzes fatal accidents that occurred in the construction industry between 2017 and 2021, and derives high-risk work, accident occurrence situations, and major causal factors that can cause serious injuries or more. ※ Since the work environment of each workplace may be different, please refer to this data to identify high-risk work and accident-causing factors considering the environment and work characteristics. ※ Since the work environment of each workplace may be different, please refer to the data to identify high-risk work and accident-causing factors considering the workplace environment and work characteristics.

The Occupational Safety and Health Administration (OSHA) collected work-related injury and illness data from employers within specific industry and employment size specifications from 2002 through 2011. This data collection is called the OSHA Data Initiative or ODI. The data provided is used by OSHA to calculate establishment specific injury and illness incidence rates. This searchable database contains a table with the name, address, industry, and associated Total Case Rate (TCR), Days Away, Restricted, and Transfer (DART) case rate, and the Days Away From Work (DAFWII) case rate for the establishments that provided OSHA with valid data for calendar years 2002 through 2011. This data has been sampled down from its original size to 4%. In addition, the original dataset only has data from a small portion of all private sector establishments in the United States (80,000 out of 7.5 million total establishments). Therefore, these data are not representative of all businesses and general conclusions pertaining to all US business should not be overdrawn. Data quality: While OSHA takes multiple steps to ensure the data collected is accurate, problems and errors invariably exist for a small percentage of establishments. OSHA does not believe the data for the establishments with the highest rates on this file are accurate in absolute terms. Efforts were made during the collection cycle to correct submission errors, however some remain unresolved. It would be a mistake to say establishments with the highest rates on this file are the ‘most dangerous’ or ‘worst’ establishments in the Nation. Rate Calculation: An incidence rate of injuries and illnesses is computed from the following formula: (Number of injuries and illnesses X 200,000) / Employee hours worked = Incidence rate. The Total Case Rate includes all cases recorded on the OSHA Form 300 (Column G + Column H + Column I + Column J). The Days Away/Restriced/Transfer includes cases recorded in Column H + Column I. The Days Away includes cases recorded in Column H. For further information on injury and illness incidence rates, please visit the Bureau of Labor Statistics’ webpage at http://www.bls.gov/iif/osheval.htm State Participation: Not all state plan states participate in the ODI. The following states did not participate in the 2010 ODI (collection of CY 2009 data), establishment data is not available for these states: Alaska; Oregon; Puerto Rico; South Carolina; Washington; Wyoming.

Data Dictionary

Key	List of...	Comment	Example Value
year	Integer	$MISSING_FIELD	2002
address.city	String	$MISSING_FIELD	"Cherry Hill"
address.state	String	$MISSING_FIELD	"NJ"
address.street	String	$MISSING_FIELD	"100 Dobbs Ln Ste 102"
address.zip	Integer	$MISSING_FIELD	8034
business.name	String	$MISSING_FIELD	"United States Cold Storage"
business.second name	String	$MISSING_FIELD	"US Cold"
industry.division	String	$MISSING_FIELD	"Transportation, Communications, Electric, Gas, And Sanitary Services"
industry.id	Integer	$MISSING_FIELD	4222
industry.label	String	$MISSING_FIELD	"Refrigerated Warehousing and Storage"
industry.major_group	String	$MISSING_FIELD	"Motor Freight Transportation And Warehousing"
statistics.days away	Float	$MISSING_FIELD	0.0
statistics.days away/restricted/transfer	Float	$MISSING_FIELD	0.0
statistics.total case rate	Float	$MISSING_FIELD	0.0

Acknowlegement

Original Data

CORGIS Dataset Project

Foto von National Cancer Institute auf Unsplash

Find information and data about fatal work injuries in Massachusetts.

The Construction Site Safety Services market is experiencing robust growth, driven by increasing regulatory scrutiny, heightened awareness of worker safety, and the rising complexity of construction projects. The market size, while not explicitly stated, can be reasonably estimated based on industry trends. Considering the involvement of major players like Turner Construction, Bechtel, and AECOM, and the substantial capital expenditure in the construction sector globally, a conservative estimate for the 2025 market size would be around $50 billion USD. A Compound Annual Growth Rate (CAGR) of 5-7% is plausible over the forecast period (2025-2033), reflecting continued demand for advanced safety technologies and services. Key drivers include mandatory safety training requirements, increasing insurance costs associated with workplace accidents, and a growing focus on improving worker productivity through injury prevention. Emerging trends point toward the adoption of innovative technologies such as wearable sensors, drones for site surveillance, and sophisticated risk assessment software. These advancements are enabling proactive safety management and data-driven decision-making, significantly reducing workplace incidents and boosting overall efficiency. However, challenges remain, including high initial investment costs for new technologies, the need for skilled personnel to implement and maintain these systems, and varying levels of adoption across different regions and project types. Despite these restraints, the long-term outlook for the Construction Site Safety Services market remains positive. The increasing emphasis on corporate social responsibility, coupled with a competitive landscape pushing for improved safety records, ensures consistent demand. Market segmentation reflects specialization in different safety areas, such as fall protection, hazard identification, and emergency response. The substantial number of established construction companies listed indicates a mature market with diverse service offerings. The regional distribution is likely to reflect the global distribution of construction activity, with North America, Europe, and Asia-Pacific dominating the market share, although the precise breakdown requires more granular data. The market’s future hinges on ongoing technological innovation, effective regulatory enforcement, and a sustained commitment to creating safer and more productive work environments within the construction industry.

The numbers reflect incidents that were reported to and tracked by the Ministry of Labour. They exclude death from natural causes, death of non- workers at a workplace, suicides, death as a result of a criminal act or traffic accident (unless the OHSA is also implicated) and death from occupational exposures that occurred in the past.

Data from the Ministry of Labour reflects Occupational Health and Safety (OHS) and Employment Standards (ES) information at a point in time and/or for specific reporting purposes. As a result, the information above may not align with other data sources.

Notes on critical injuries :

For the purposes of the data provided, a critical injury of a serious nature includes injuries that:

1. "Place life in jeopardy"
2. "Produce unconsciousness"
3. "Result in substantial loss of blood"
4. "Involve the fracture of a leg or arm but not a finger or toe"
5. "Involve the amputation of a leg, arm, hand or foot but not a finger or toe"
6. "Consist of burns to a major portion of the body"
7. "Cause the loss of sight

Only critical injury events reported to the ministry are included here. This represents data that was reported to the ministry and may not represent what actually occurred at the workplace. The critical injury numbers represent critical injuries reported to the ministry and not necessarily critical injuries as defined by the Occupational Health and Safety Act (OHSA). Non- workers who are critically injured may also be included in the ministry's data. Critical injuries data is presented by calendar year to be consistent with Workplace Safety and Insurance Board harmonized data;

Data is reported based on calendar year

Individual data for the Health Care program is available for Jan. 1 to Mar. 31, 2011 only. From April 2011 onwards Health Care data is included in the Industrial Health and Safety numbers.

Notes on Fatalities :

Only events reported to the ministry are included here. The ministry tracks and reports fatalities at workplaces covered by the OHSA. This excludes death from natural causes, death of non-workers at a workplace, suicides, death as a result of a criminal act or traffic accident (unless the OHSA is also implicated) and death from occupational exposures that occurred many years ago. Fatalities data is presented by calendar year to be consistent with Workplace Safety and Insurance Board harmonized data. Fatality data is reported by year of event.

*[OHSA]: Occupational Health and Safety Act *[Mar.]: March *[Jan.]: January

In 2023, there were almost ***** workplace injuries in the construction sector. The highest number of injuries was recorded in 2021.

Abstract Paper aims To study fall-accident cases in order to analyze the commonly missing or not adequately applied risk management measures (RMM) and its consequences depending on falling height. Originality First study to analyze failed RMM for preventing falls from height. Research method The study reviewed court cases published by the journal “Safety & Health Practitioner”. NIOSH recommendations were used to define RMM to apply to this study. Main findings Finally, in 98% of analyzed cases, the fall from height was a result of several non-adequate or missing RMM: in 81.6% procedures of work, 65.8% guardrails and edge protection, 60.5% risk assessment, and 60.5% platforms or scaffolds. It can be concluded that falls from height pose a significant risk for workers, which could be prevented by adequately apply RMM. Implications for theory and practice The focus in the prevention of falls should be given on most common RMM.

All permitted construction work are subject to inspection by authorized Building and Safety inspectors. The permit applicant notifies Building and Safety when the work is ready for inspection. Common items inspected include foundation excavations, concrete work, wood framing, ventilation equipment, plumbing, electrical, and so forth. Upon completion, there will be a final inspection and approval of the completed project.

The global construction site safety management market is experiencing robust growth, driven by increasing awareness of workplace safety regulations and the escalating costs associated with accidents. The market's expansion is further fueled by technological advancements, such as the implementation of IoT devices, wearable sensors, and advanced analytics for real-time risk assessment and monitoring. Stringent government regulations mandating safety protocols across construction projects are also significantly contributing to market growth. This includes enhanced reporting requirements and penalties for non-compliance, pushing companies to invest heavily in safety management systems. Furthermore, a rising focus on proactive safety measures, moving beyond reactive incident response, is driving demand for comprehensive safety management solutions. This shift involves comprehensive training programs, improved risk assessments, and the adoption of best practices across the industry. Key players are constantly innovating to offer integrated solutions that streamline safety processes and improve data analysis, leading to more efficient and safer work environments. The projected compound annual growth rate (CAGR) reflects this positive trajectory, suggesting consistent and sustained expansion throughout the forecast period. The competitive landscape is characterized by a mix of large multinational corporations and specialized safety management firms. These companies are engaged in strategic initiatives like mergers and acquisitions, partnerships, and the development of innovative technologies to maintain their market share. Geographic expansion is a significant strategy, with companies targeting emerging markets with rapid infrastructure development. However, challenges such as high initial investment costs for advanced safety technologies and a potential skills gap in the implementation and utilization of these technologies can act as restraints to the market’s growth. Nevertheless, the overall outlook for the construction site safety management market remains optimistic, driven by a combination of regulatory pressures, technological advancements, and a growing awareness of the importance of workplace safety. The market is expected to continue its upward trend, particularly as the industry increasingly adopts preventative measures and integrates smart safety solutions.

Information provided pertains to all incidents under which a worker performing construction work suffered a work-related fatal injury. This data is collected by the NYSDOL per NY Lab L section 44 (https://law.justia.com/codes/new-york/2021/lab/article-2/44/).

The Motor Vehicle Collisions crash table contains details on the crash event. Each row represents a crash event. The Motor Vehicle Collisions data tables contain information from all police reported motor vehicle collisions in NYC. The police report (MV104-AN) is required to be filled out for collisions where someone is injured or killed, or where there is at least $1000 worth of damage (https://www.nhtsa.gov/sites/nhtsa.dot.gov/files/documents/ny_overlay_mv-104an_rev05_2004.pdf). It should be noted that the data is preliminary and subject to change when the MV-104AN forms are amended based on revised crash details.For the most accurate, up to date statistics on traffic fatalities, please refer to the NYPD Motor Vehicle Collisions page (updated weekly) or Vision Zero View (updated monthly).

Due to success of the CompStat program, NYPD began to ask how to apply the CompStat principles to other problems. Other than homicides, the fatal incidents with which police have the most contact with the public are fatal traffic collisions. Therefore in April 1998, the Department implemented TrafficStat, which uses the CompStat model to work towards improving traffic safety. Police officers complete form MV-104AN for all vehicle collisions. The MV-104AN is a New York State form that has all of the details of a traffic collision. Before implementing Trafficstat, there was no uniform traffic safety data collection procedure for all of the NYPD precincts. Therefore, the Police Department implemented the Traffic Accident Management System (TAMS) in July 1999 in order to collect traffic data in a uniform method across the City. TAMS required the precincts manually enter a few selected MV-104AN fields to collect very basic intersection traffic crash statistics which included the number of accidents, injuries and fatalities. As the years progressed, there grew a need for additional traffic data so that more detailed analyses could be conducted. The Citywide traffic safety initiative, Vision Zero started in the year 2014. Vision Zero further emphasized the need for the collection of more traffic data in order to work towards the Vision Zero goal, which is to eliminate traffic fatalities. Therefore, the Department in March 2016 replaced the TAMS with the new Finest Online Records Management System (FORMS). FORMS enables the police officers to electronically, using a Department cellphone or computer, enter all of the MV-104AN data fields and stores all of the MV-104AN data fields in the Department’s crime data warehouse. Since all of the MV-104AN data fields are now stored for each traffic collision, detailed traffic safety analyses can be conducted as applicable.

This is construction site safety signal light data provided by the Korea Occupational Safety and Health Agency. You can check the latest technical guidance results of construction sites (medium and small construction sites) subject to technical guidance by construction accident prevention specialized guidance institutions. ※ callApiId = 1020 (Required as a fixed value) ※ Only workplaces where accident prevention technical guidance is in progress are displayed ※ Usage reference: Korea Occupational Safety and Health Agency website (www.kosha.or.kr) > Daily Construction Safety Management Situation Board > Construction Site Safety Signal Lights (Inspection results can be distinguished by color and used) ※ Related: Article 73 of the Occupational Safety and Health Act (Industrial Accident Prevention Guidance for Construction Work) ① A construction project orderer or construction contractor (excluding a contractor who first received a construction project from a construction project orderer) of a construction project prescribed by Presidential Decree shall, when commencing the construction project, enter into a guidance contract for the prevention of construction industrial accidents with a specialized institution designated pursuant to Article 74 (hereinafter referred to as “construction accident prevention specialized guidance institution”). ② The construction disaster prevention specialized guidance institution shall provide guidance to construction contractors for the prevention of industrial accidents, and the construction contractors shall take appropriate measures in accordance with the guidance. ③ The contents of the guidance work of the construction disaster prevention specialized guidance institution, the areas subject to guidance, the method of conducting guidance, and other necessary matters shall be prescribed by Presidential Decree.

We provided the information of the 571 construction accident cases. We didn't provide each of the accident reports, because they were expatiated in Chinese. We just provided the names (in Chinese), area distribution, types, and severity levels of them in Excel tables.