KR102655252B1 - HSE management system and method for systemic operating and managing wind farms - Google Patents

Abstract

The present invention relates to an HSE management system and method for systematic operation and management of a wind power farm. It is a system for managing the health, safety, and environment of a wind power farm, including an operation management department, a work risk assessment department, and work risk and status. It includes a monitoring department and a safety management training department, and the operation management department stores and manages information on pre-work safety training for workers involved in maintenance work on wind power plants, history of accidents that have occurred, and emergency response plans in the event of an accident. A management module, a health management module in which information on workers' information, health, education, and personal protective equipment is stored and managed, and information on firefighting means, chemicals, waste operations and maritime activities provided at the wind farm. An environmental management module that stores and manages information on work tools and equipment used by workers, projects, work procedures, and work permits, and a work management module that stores and manages information on health, safety and environment laws and turbines. It includes a general management module, and the work risk assessment department selects risk factors that may occur during wind power generator maintenance work from JSA (Job Safety Analysis), What-if, and BTA (bowtie method). Analyzing with one or more models, the analysis data is stored and transmitted to the wind farm operator server, and the work risk and status monitoring unit provides the evaluation result data of the work risk assessment unit to the work manager terminal and worker terminal. , work site situation and worker's physical activity information is collected by the work monitoring device and worker monitoring device and transmitted to the work manager terminal, and the safety management education department provides use and inspection of personal protective equipment, safety education by work type, and emergency situations. and information on on-site measures and emergency response procedures by accident type, wherein the work monitoring device includes CCTV installed at the work site and a sensor attached to work equipment or equipment to detect movement of workers or operation of the equipment; , the worker monitoring device includes one or more selected from an action cam that is portable on the worker's body or personal equipment, a smart watch, a smart wearable device including a heart rate measurement band, a blood pressure measurement band, or GPS, , the safety management module provides safety training information to the worker terminal, requests confirmation in the form of a check risk whether safety training has been completed after a preset time has elapsed, and if no reply is received from the worker terminal about whether safety training has been completed, the result is By transmitting information to the work manager terminal and health management module, the HSE of the wind power farm can be systematically managed while ensuring the safety of workers.

Description

HSE management system and method for systematic operating and managing wind farms}

The present invention relates to an HSE management system and method, and more specifically, to an HSE management system and method that enables systematic operation and management of a wind power farm.

Recently, investment in new and renewable energy has been increasing to solve environmental problems such as depletion of fossil energy, climate change, and increase in greenhouse gas emissions. In particular, the renewable energy supply mandate (Renewable Portfolio Standard (RPS)) system and government The domestic new and renewable energy market is growing rapidly due to the renewable energy expansion policy centered on solar and wind power according to the renewable energy implementation plan.

Wind power generation is a representative technology of new and renewable energy and is emerging as a technology that can reduce greenhouse gases. Accordingly, as of 2016, the cumulative installed amount of wind power generation facilities worldwide reached 486.7GW, and the amount is increasing every year. Wind power generates power by rotating a turbine with wind power, and is divided into large, medium, and small depending on the amount of power generation, or into onshore wind power and offshore wind power depending on the installation location. Such wind power generation is trending towards larger scale, and due to the nature of installation, wind power generation complexes or facilities are installed and operated separately.

Meanwhile, offshore wind power generation has stable wind speeds and generates energy using wind on the sea, so it is not significantly affected by weather conditions compared to onshore wind power generation, so the number of offshore wind power plants is gradually increasing. However, due to the nature of the installation, offshore wind power farms are not easy to manage because they are located far away from permits or use large-sized generators. Considering their scale, if an accident such as failure or damage to the generator occurs, a major accident is bound to occur. This is reality.

In addition, because offshore wind turbines are installed on the sea, they are more difficult to access compared to land-based wind turbines, and workers for maintenance must use transportation such as ships to move to the work site, and sudden winds, waves, and storms The disadvantage is that the working environment is unstable due to bad weather.

Accordingly, although wind power industry sites operate a Health, Safety and Environment (HSE) operating system, most HSE-related content is operated individually in some systems or managed as individual documents or files. As HSE-related documents and files use the HSE operation support method through manual-oriented materials provided by the manufacturer, difficulties arise in updating, lack of compatibility, and integration of documents.

In addition, there is no safety management system for wind power O&M safety work and management, and there is no established system for HSE operation management and safety management system that meets various domestic health, safety, and environmental regulations and standards, so systematic management and information The provision is insufficient.

The present invention was devised to solve the above-described problems, and its purpose is to provide an HSE management system and method that enables systematic HSE operation management of wind power plants and safety management of workers.

As a means to solve the aforementioned technical challenges,

The present invention is a system for managing the health, safety, and environment of a wind power farm, and includes an operation management department, a work risk assessment department, a work risk and status monitoring department, and a safety management education department, and the operation management department is responsible for managing the wind power generation farm. A safety management module that stores and manages information on pre-work safety training for workers involved in maintenance work, history of accidents that have occurred, and emergency response plans in the event of an accident, and information on workers' information, health, education, and personal protective equipment. A health management module that stores and manages; an environmental management module that stores and manages information on the operation of firefighting means, chemicals, and wastes equipped in wind power plants; and marine activities; and work tools and equipment used by workers, It includes a work management module in which information on projects, work procedures, and work permits is stored and managed, and a general management module in which information on health, safety and environment laws and turbines is stored and managed, and the work risk assessment department is responsible for maintenance and management of wind power generators. Risk factors that may arise from work are analyzed using one or more models selected from JSA (Job Safety Analysis), What-if, and BTA (Bowtie Method), and the analysis data is stored while generating wind power generation. It is transmitted to the operator's server, and the work risk and status monitoring unit provides the evaluation result data of the work risk assessment unit to the work manager terminal and worker terminal, and monitors the work site situation and the worker's body by the work monitoring device and the worker monitoring device. Activity information is collected and transmitted to the work manager terminal, and the safety management training department includes information on the use and inspection of personal protective equipment, safety education by work type, on-site measures and emergency response procedures by emergency situation and accident type, and the above work. Monitoring devices include CCTV installed at work sites and sensors attached to work equipment or equipment to detect movement of workers or operation of equipment. The worker monitoring device is a device that is portable and installed on the worker's body or personal equipment. It includes one or more selected from an action cam, a smart watch, a smart wearable device including a heart rate measurement band, a blood pressure measurement band, or GPS, and the safety management module provides safety education information to the worker terminal and ensures the safety of the worker. A wind power system characterized in that it requests confirmation in the form of a checklist whether training has been completed, and if no reply is received from the worker terminal about whether safety training has been completed after a preset time has elapsed, the resulting information is transmitted to the work manager terminal and health management module. Provides an HSE management system for systematic operation and management of power generation complexes.

In this case, the health management module can provide update information to the task manager terminal and worker terminal when the training content is updated.

In this case, the work risk and status monitoring unit receives temperature information in real time from a temperature sensor installed at the work site, and if the temperature exceeds the preset temperature, it determines that a fire has occurred and operates the automatic fire extinguishing equipment and voice alarm device. You can request evacuation using the task manager terminal and worker terminal.

In this case, the work risk and status monitoring unit compares the worker's physical activity information collected from the worker monitoring device with the physical activity information previously stored in the health management module, and if the difference is outside a preset range, the work manager You can request to stop work through the terminal or the worker terminal.

In addition, the present invention is an HSE management method for systematically operating and managing a wind power farm using the HSE management system, which (a) provides workers with information on safety training, environment, and equipment required for maintenance work on the wind power farm; Provided to, but excluding the worker from work if it is confirmed that the worker has not completed or incompletely completed safety training; (b) evaluating the risk of accident occurrence based on the period, workers, tools, equipment, and procedures required for the maintenance work in step (a), and providing the results to the work manager and workers; (c) collecting work site conditions and worker's physical information in real time during the work process, and requesting the work manager to stop the worker's work if an abnormality is detected from the collected information; and (d) providing the wind power farm operator with the status of work carried out through steps (a) to (c) above, and information on accidents occurring during the work process and their response, to the wind power farm operator. Systematic operation of the wind power farm including. Provides HSE management methods for management.

According to the present invention, the HSE operation management department of the wind power generation complex is composed of a safety management module, a health management module, an environmental management module, a work management module, and a general management module, and is operated and managed in an integrated manner to prevent direct or indirect occurrences in the wind power generation complex. Possible negative social and environmental impacts can be minimized.

In addition, it is possible to prevent unexpected accidents by evaluating the risk of work carried out at a wind power farm and monitoring the work status in real time, as well as reducing wind power farm O&M costs (facility repairs) through periodic feedback on the risk assessment results. and replacement, worker treatment and compensation, environmental damage compensation, etc.) and increase short-term competitiveness of power generation.

1 is a configuration diagram illustrating the overall operation of the HSE management system for systematic operation and management of a wind power farm according to a preferred embodiment of the present invention;
Figure 2 is a block diagram showing the configuration of an HSE management system for systematic operation and management of a wind power farm according to a preferred embodiment of the present invention;
Figure 3 is a block diagram showing the configuration of the work risk assessment unit shown in Figure 2.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts unrelated to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Figure 1 is a configuration diagram for explaining the overall operation of the HSE management system for systematic operation and management of a wind power farm according to a preferred embodiment of the present invention, and Figure 2 is a schematic diagram of the systematic operation of a wind power farm according to a preferred embodiment of the present invention. It is a block diagram showing the configuration of the HSE management system for operation management, and FIG. 3 is a block diagram showing the configuration of the work risk assessment unit shown in FIG. 2.

Referring to Figures 1 to 3, an HSE (Health, Safety and Environment) management system 100 (hereinafter referred to as 'HSE management system 100') for systematic operation and management of a wind power farm according to a preferred embodiment of the present invention. ) operates wind power farms systematically to ensure human and material safety by minimizing all risk factors that may occur in wind power farms, and conducts work risk assessment and work tasks between wind power farm operators, work managers, and workers. As the purpose is to ultimately ensure the safety of workers' work by allowing information on status monitoring and safety training to be shared, confirmed, and supplemented in real time, the technical configuration that makes such a system possible will first be described below.

The work monitoring device 10 is installed at the work site to monitor the overall situation at the work site, including whether workers are wearing protective equipment, work processes, CCTV that collects images of the work site and its surroundings, and various facilities or equipment. It may include sensors that are attached to detect the movement of workers or operation of equipment, as well as various means to obtain various information existing at the work site. This work monitoring device 10 provides information collected at the work site in real time to the HSE management system 100, and more specifically, to the work risk and status monitoring unit 130.

The worker monitoring device 20 is portablely installed on the worker's body or personal equipment to monitor the individual worker's condition. The worker monitoring device 20 includes an action cam that collects information about the worker's work environment, the worker's physical activity (pulse, oxygen It may include various smart wearable devices such as a smart watch that collects information on (saturation, etc.), a heart rate measurement band, a blood pressure measurement band, and a GPS device that can determine the worker's location. This worker monitoring device 20 The information collected through this is provided to the work risk and status monitoring unit 130 in real time or periodically.

The work manager terminal 30 is equipment such as a smartphone, tablet PC, laptop, etc. carried by the manager at the work site, and information collected from the work monitoring device 10 and the worker monitoring device 20 from the HSE management system 100 or, conversely, information input from the task manager can be transmitted to the HSE management system 100, and it is also possible to transmit and receive information directly with another task manager terminal or worker terminal 40 through communication.

The worker terminal 40 is carried by the worker deployed to the work site and can be implemented in the same way as the work manager terminal 30. In this case, it is possible for the worker monitoring device 20 or its functions described above to be mounted together on the worker terminal 40.

It is natural that a plurality of task manager terminals 30 and worker terminals 40 may be configured depending on the number of task managers or workers.

The operator server 50 is a server of the operator that operates the wind power farm, and can periodically receive the operation and safety management status of the wind power farm from the HSE management system 100.

In the present invention, communication between the work monitoring device 10, the worker monitoring device 20, the work manager terminal 30, the worker terminal 40, the operator server 50, and the HSE management system 100 is 5G LoRa ( By using Long Range (Long Range)-based technology, the stability of the network and the reliability of operational data can be secured by omitting the CDMA wireless repeater and securing a communication range of up to 11 kilometers.

In addition, 3g module, Wi-Fi module, WiGig module, Wireless LAN (WLAN), DLNA (Digital Living Network Alliance), Wibro (Wireless Broadband: Wibro), WiMAX (World Interoperability for Microwave Access) : Wimax), HSDPA (High Speed Downlink Packet Access), HSUPA (High Speed Uplink Packet Access), IEEE 802.16, Long Term Evolution (LTE), LTE-A (Long Term EvolutionAdvanced), broadband wireless mobile communication service It is also possible to use a remote network interface such as (Wireless Mobile Broadband Service: WMBS).

Based on the above-described content, the HSE management system 100 will be described in detail below.

As shown in Figure 2, the HSE management system 100 includes an operation management department 110, a work risk assessment department 120, a work risk and status monitoring department 130, and a safety management training department 140. .

The operation management department (110) is for the systematic operation and management of the wind power farm, and includes the safety management module (111), health management module (112), environment management module (113), work management module (114), and general Includes a management module (115).

The safety management module 111 manages safety training before work, including risk factors that may occur to workers before maintenance work on a wind power plant, inspection and use of safety equipment, and response to emergency situations, and accidents that occur during wind power plant maintenance work. Information on accident management, including occurrence status, and emergency response plan management, including emergency response plans for safety accidents during wind power generation maintenance work, is provided to the worker terminal 40 to provide safety-related information before workers are put into work. Be sure to check and understand the details in advance.

Specifically, pre-work safety education management includes matters related to how to conduct risk assessment of work according to maintenance of various wind power generators, how to inspect safety equipment, safety accident cases, how to use equipment safely, and how to wear personal protective equipment.

In this case, the safety management module 111 may provide the above-described safety training information to the worker terminal 40 and request confirmation in the form of a checklist whether the worker has completed safety training, and after a certain period of time, from the worker terminal 40 If a reply is not received as to whether safety training has been completed or a reply is made that some safety training has not been completed, the results are transmitted to the work manager terminal 30 and the health management module 112.

Therefore, the work manager can immediately exclude workers who have not completed all or part of safety training from work or put them into work after completing safety training. The worker's history of failure to complete or delayed completion of safety training can be checked in the health management module (112). It is stored and managed as employee information.

Accident management includes safety accident data that occurred during maintenance work on wind turbines.

Emergency response plan management may include response plans for safety accidents that have already been data or may occur for each project in the future, as well as an emergency contact network of related organizations, medical institutions, wind power farm operating companies, etc. that can be contacted in the event of an accident. .

The health management module 112 includes management of employee information such as the career and qualifications of wind power farm maintenance workers, employee health management of workers' physical information and health status, and education management including information on the status of workers' required training completion. Information on personal protective equipment management, including the status and inspection history of personal protective equipment issued to individual workers, such as workers' helmets, harnesses, lanyards, and safety shoes, is provided to the work manager terminal 30 so that the work manager can control the work. Depending on the type or level of difficulty, appropriate workers are selected, assigned, managed, and supervised.

Employee information management includes information such as the career, qualifications, and completion of safety training of workers performing wind turbine maintenance, skill level based on equipment and tool use history, number of project participation according to maintenance performance, and project details being performed. can do.

Employee health management provides physical information including workers' heart rate, blood pressure, movement, oxygen level, alcohol level, electric shock, etc.

Training management may include information such as completion status and refresher training schedule for major training that workers must complete. In this regard, the health management module 112 can be linked with servers of related organizations and government agencies to notify the relevant information to the task manager terminal 30 and the worker terminal 40 when changing statutory mandatory training occurs.

Personal protective equipment management includes detailed specifications of personal protective equipment including helmets, harnesses, lanyards, safety shoes, work clothes, etc. provided to workers, as well as information such as their condition, number of uses, period of use, and replacement cycle.

The environmental management module 113 provides fire management, including status information of fire extinguishers, automatic fire extinguishing equipment, and fire alarms managed at the wind power plant, MSDS for chemicals used in wind power generation maintenance, use history, etc. Chemical operation management including information, waste management including information on types and generation history of waste generated during wind turbine operation, and information on ships, workers, departure history, etc. related to offshore wind farm maintenance activities. By transmitting information on maritime activity management including to the work manager terminal 30 and worker terminal 40, work managers and workers can become familiar with environmental matters at the work site in advance to prevent safety accidents in advance, and quickly A response can be made.

Firefighting Fire management includes status information of fire extinguishers, automatic fire extinguishing equipment, and fire alarms provided in wind power plants.

Chemical substance operation management includes information on the export, import, and use status of substances hazardous to human health used during maintenance of wind power generators.

Waste management manages waste that is used and disposed of among human hazardous substances managed through chemical operation management. Specifically, waste management can manage the types of waste generated by classifying them into solid, liquid, and gas depending on the type of substances hazardous to the human body, chemicals used during maintenance work, or hazardous substances, and the date of waste generation and waste collection. It can provide information including protective equipment needed for work and waste management.

Offshore activity management includes information about ships participating in maintenance of offshore wind farms, sailing information, and workers participating in maintenance. In this case, maritime activity management may further include meteorological environment information to collect the maritime meteorological environment in real time and predict weather conditions because the ships participating in maintenance and departure information change depending on the influence of the meteorological environment. Meteorological environment information includes humidity, temperature, illuminance, wave height, sunrise, and sunset data. Based on this, the weather is predicted and the schedules of workers undergoing maintenance or scheduled for maintenance are adjusted to take into account the safe return and travel time of workers. A maintenance schedule can be established.

The work management module 114 includes work tool and equipment management that provides information on work tools and equipment, calibration status and usage history, project management that provides information on the performance period and input manpower for wind power generation projects, and wind power generator management. The work manager terminal 30 and the worker terminal provide information on work procedure management that provides procedure management information on maintenance work types and work contents, and work permit management that provides permission information of reviewers and approvers for work procedure management. (40) to ensure that the overall process of work proceeds smoothly.

Work tool and equipment management includes historical data including location of use, date of use, time of use, and work details of work tools and equipment used for wind turbine maintenance.

Project management includes information on the maintenance operator, project period, and manpower for each wind farm. Accordingly, the number of projects being carried out by each maintenance operating company, the ratio of the number of projects being carried out by each company to the total projects, the number of newly added projects, the total manpower invested in maintenance work, the newly added manpower, and the number of projects being carried out by each company. It can support the decision-making of maintenance companies and managers by providing information including the number of personnel involved.

Meanwhile, the maintenance work status according to the preset project period can be expressed as progress compared to the entire maintenance work period, daily progress, weekly progress, etc. For example, when the daily work quota according to the maintenance work procedure is 100% and maintenance work is performed with a daily progress of 50%, a safety accident may occur, or a problem may occur with at least one of worker safety, health, and the environment. It can be judged that it has been done. In addition, when the overall maintenance work procedure or period is set to 100%, the previous work status is 35%, and the daily maintenance work goal is 40%, a safety accident occurs if the daily maintenance work status is 35 to 39%. Alternatively, it may be determined that a problem has occurred in at least one of the worker's safety, health, and environment.

In other words, when the worker inputs the progress of the work into the worker terminal 40, the information is transmitted to the work management module 114 and collected, and the work management module 114 collects the work progress in advance according to the collected work progress and the amount of work or schedule. The set target work progress is compared, and if the actual work progress is less than the target work progress, confirmation is requested from the work manager terminal 30 so that the work manager can check for accidents or abnormalities of the worker.

Work procedure management includes information on wind turbine maintenance procedures and equipment and tools required for maintenance work based on project information, including the weather environment at the location where the wind turbine is installed, information on workers assigned to the project, By analyzing the equipment history in use, maintenance work procedures and equipment can be provided.

Work permit management includes information on workers, tools, equipment, work procedures, work review matters, etc. participating in maintenance by company or project.

The general management module (115) includes the safety management system established by the wind power farm operator, the health and safety environment management policy that provides safety education plan information, the domestic Occupational Safety and Health Act, the Act on Fire Prevention, Installation and Maintenance of Firefighting Facilities, and Safety Management, Health, safety and environment law management that provides various information for the safety of wind turbine maintenance workers by providing ISO certification and international guidelines such as the Hazardous Materials Safety Management Act, and information on specifications and maintenance of wind turbines installed in various wind power generation complexes. Includes information on turbine information management that provides company information.

Health, safety and environment law management is governed by domestic industrial safety laws and regulations, including domestic occupational health laws, fire prevention, installation and maintenance of firefighting facilities, safety management laws, hazardous materials safety management laws and waste safety management laws, and international laws and regulations including ISO certification and international guidelines. By providing industrial safety regulations, the safety of wind turbine maintenance workers can be ensured.

Turbine information management includes information on the specifications of wind power generators installed in multiple wind power farms and information on the operating company that maintains them.

Meanwhile, the information included in each of the above-mentioned modules is collected from the work monitoring device 10, the worker monitoring device 20, or other modules, or is directly input and stored by the worker, work manager, or person in charge of each module through a personal terminal. It is managed by

The operation management department 110 has been described above. Below, the work risk assessment unit 120 will be described.

The work risk assessment unit 120 is designed to evaluate the risk of risk factors that may occur during maintenance work on wind power generators, and includes risk assessment, risk assessment DB, and safety inspection.

Risk assessment is a risk assessment that includes maintenance work procedures according to the project, major risk factors and potential risk factors according to the use of necessary equipment, and analyzes risk reduction measures and methods to evaluate the risk of maintenance work. data can be provided.

Risk assessment of work can be done by one or more of the three models: JSA (121), What-if (122), and BTA (123) (see Figure 3).

The JSA (Job Safety Analysis) model (121) provides risk results (frequency to provide.

The what-if model (122) is a module that classifies the risk level of accidents, results, and safety measures into five levels through accident prediction questions, and provides information on possible accidents, results, and safety measures through accident prevention questions. It provides information about the results, a risk rating ranging from 1 to 5, and recommendations for improvement.

The BTA (Bowtie Method) model (123) provides a module that can graphically represent the causes and consequences of accidents with a high accident frequency and large risk scale, and provides a schematic representation of the risk assessment results for work procedures. provided in a way.

The risk assessment DB can improve the accuracy and reliability of risk assessment management by converting and storing information including data analyzed using the above-mentioned risk assessment model, existing safety accident cases, and the experience of maintenance workers. For example, damage to equipment and tools caused by workers during maintenance work, occurrence of new hazards not included in safety training in equipment and tools used in maintenance procedures, and safety experienced by workers when performing specific maintenance projects. Information such as accident risks can be converted into data.

The safety inspection includes information transmitted from the HSE management system 100 to the maintenance operator server 50 and status checks at the wind turbine maintenance site. In other words, the reliability of the data can be improved by comparing the data collected from the wind power farm's HSE management system (100) with the status inspected at the maintenance site, and the safety of workers participating in maintenance work can be secured. Data including supplementary information, etc. can be provided.

In this case, among the information included in the risk assessment DB and safety inspection, various data generated at the maintenance site are the information entered by the work manager and workers into the work manager terminal 30 and the worker terminal 40 by the work risk assessment unit ( 120) and collected in a manner that is transmitted and stored.

The work risk and status monitoring department (130) reflects the evaluation results of the work risk assessment department (120) for maintenance work on wind power generators and reports the work risk status for the work to the work manager terminal (30) and the worker terminal (40). ), and is intended to check and inspect the worker's status in real time, including work risk monitoring and work status monitoring.

Work risk monitoring provides the risk level for the work by classifying each work into three levels: 'safety', 'caution', and 'warning' according to the risk assessment results of the work risk assessment department (120). The work manager can select workers by receiving information about the work risk through the work manager terminal 30. For example, if the work risk level is 'dangerous', the selection can focus on workers with long experience or skilled workers with a lot of experience in using the equipment used in the work.

Work status monitoring is performed by the work monitoring device 10 and the worker monitoring device 20. In other words, the work site situation information collected through CCTV and sensors installed at the work site, and the worker's physical activity information collected through action cams, smart wearable devices, GPS devices, etc. are sent to the work risk and status monitoring department (130). It is transmitted and monitored in real time or periodically, and at the same time, the work risk and status monitoring unit 130 transmits the relevant information to the work manager terminal 40, so that the work manager can accurately monitor the overall work status as well as the individual worker's status. become able to understand.

For example, when the work risk and status monitoring unit 130 receives temperature information in real time from a temperature sensor (work monitoring device 10) installed on a wind power generator, if the temperature exceeds the set temperature, it determines that a fire has occurred and automatically Fire extinguishing equipment and voice alarm devices can be activated, and at the same time, rapid evacuation of workers, etc. can be requested through the work manager terminal (30) and worker terminal (40).

In addition, the work risk and status monitoring unit 130 compares the worker's physical activity information collected from the worker monitoring device 20, such as heart rate, with the worker's average heart rate pre-stored in the health management module 112 to determine the worker's physical activity information. If the difference is outside the preset range, the safety of the worker can be secured by requesting work stoppage from the task manager terminal 30 or the worker terminal 40 of the worker.

The safety management education department (140) is for safety education of workers, and provides safety education information such as use and inspection of personal protective equipment, safety education by work type, on-site measures and emergency response procedures by emergency situation and accident type, etc. to worker terminals periodically or whenever updated. (40) is provided.

Safety education on personal protective equipment includes how to properly wear personal protective equipment such as harnesses, lanyards, helmets, and gloves used at wind power generation sites, and safety education video and audio guidance on inspection items before use.

Safety training for each type of work provides information on risk factors and potential accidents that may occur depending on the work process and type of work at the wind farm site, and includes video and audio guidance on safety training for risk factors for each work.

Safety training on on-site measures and emergency response procedures for each type of emergency situation and accident includes video and audio guidance on on-site measures and emergency response procedures for accident risks that may occur by type of work.

The HSE management system 100 has been described above. Hereinafter, an HSE management method using the HSE management system 100 will be described.

First, when a wind turbine requiring maintenance occurs at a wind power farm, workers to be deployed to the site are selected, taking into account the experience, proficiency, and technology of the workers required depending on the content, difficulty, and scale of the work.

Afterwards, the selected workers are provided with safety training information, environment-related information, and work equipment or tool-related information required for the relevant work. At this time, in the case of safety training, after checking whether the worker has completed the safety training, workers who have not completed or only partially completed the safety training are excluded from work or are required to complete the safety training completely.

Afterwards, the risk of accidents occurring according to the period, workers, tools, equipment, and procedures required for wind turbine maintenance is evaluated, and the results are provided to work managers and workers.

Continuously, when a worker enters the work site, physical information such as breathing, pulse, and complexion of the worker is collected in real time along with information such as video footage of the workplace and its surroundings and temperature changes, and any abnormalities or changes are detected from that information. If so, ask the task manager or the relevant worker to stop the task. In addition, when the temperature at the work site rises rapidly, a fire is announced through speakers, etc., and alerts work managers and workers to ensure rapid evacuation.

Lastly, the status of work carried out in the above-described manner, accidents occurring in the process, and responses thereto are periodically provided to the operator of the wind power farm so that the operator can establish a project operation management plan when carrying out the same or similar project in the future. It can be reflected in

Above, preferred embodiments of the present invention have been described in detail with reference to the drawings. The description of the present invention is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing its technical idea or essential features. Accordingly, the scope of the present invention is indicated by the claims below rather than the detailed description above, and all changes or modifications derived from the meaning, scope, and equivalent concepts of the claims are interpreted to be included in the scope of the present invention. It has to be.

10: Work monitoring device 20: Worker monitoring device
30: Task manager terminal 40: Worker terminal
50: Wind farm operator server 100: HSE management system
110: Operation management department 111: Safety management module
112: Health management module 113: Environmental management module
114: Work management module 115: General management module
120: Work Risk Assessment Department 121: JSA Model
122: What-if model 123: BTA model
130: Work Risk and Status Monitoring Department 140: Safety Management Education Department

Claims (5)

It is a system that manages the health, safety, and environment of wind power plants, and includes an operation management department, work risk assessment department, work risk and status monitoring department, and safety management education department,
The operation management unit includes a safety management module that stores and manages information on pre-work safety training for workers engaged in maintenance work at a wind power plant, history of accidents that have occurred, and emergency response plans in the event of an accident, and a safety management module that stores and manages information on workers' information, health, A health management module in which information on education and personal protective equipment is stored and managed, an environmental management module in which information on firefighting equipment, chemicals, waste operations and marine activities provided at wind power plants is stored and managed, and workers. It includes a work management module in which information on work tools and equipment used, projects, work procedures, and work permits are stored and managed, and a general management module in which information on health, safety and environment laws and turbines is stored and managed,
The work risk assessment department analyzes risk factors that may arise during maintenance work on wind turbines using one or more models selected from JSA (Job Safety Analysis), What-if, and BTA (Bowtie Method). , the analysis data is stored and transmitted to the wind farm operator server at the same time,
The work risk and status monitoring unit provides the evaluation result data of the work risk assessment unit to the work manager terminal and the worker terminal, and collects work site situation and worker's physical activity information through the work monitoring device and the worker monitoring device to the work manager terminal. and send it to
The safety management education department includes information on the use and inspection of personal protective equipment, safety education by work type, on-site measures and emergency response procedures by emergency situation and accident type,
The work monitoring device includes CCTV installed at the work site and a sensor attached to work equipment or equipment to detect the movement of the worker or operation of the equipment, and the worker monitoring device is portable on the worker's body or personal equipment. It includes one or more selected from an action cam, a smart watch, a smart wearable device including a heart rate measurement band, a blood pressure measurement band, or GPS,
The safety management module provides safety training information to the worker terminal and requests confirmation in the form of a check risk whether the worker has completed safety training. If a reply is not received from the worker terminal about whether safety training has been completed after a preset time has elapsed, the result is obtained. Information is transmitted to the task manager terminal and health management module,
The work management module collects information about the progress of work from the worker terminal, compares the collected work progress with the target work progress set in advance according to the workload or schedule, and performs a task if the actual work progress is less than the target work progress. An HSE management system for systematic operation and management of wind power plants, characterized in that it allows the work manager to check for accidents or abnormalities of workers by requesting confirmation through the manager terminal. According to paragraph 1,
The health management module is an HSE management system for systematic operation and management of a wind power farm, characterized in that it provides update information to the task manager terminal and worker terminal when the training content is updated. According to paragraph 1,
The work risk and status monitoring unit receives temperature information in real time from a temperature sensor installed at the work site, determines that a fire has occurred when the temperature exceeds a preset temperature, and activates automatic fire extinguishing equipment and a voice alarm device while simultaneously connecting the work manager terminal. HSE management system for systematic operation and management of wind power plants, characterized by requesting evacuation through worker terminals. According to paragraph 1,
The work risk and status monitoring unit compares the worker's physical activity information collected from the worker monitoring device with the physical activity information previously stored in the health management module, and if the difference is outside a preset range, the work manager terminal or the HSE management system for systematic operation and management of wind power plants, characterized by requesting work stoppage through worker terminal. As an HSE management method for systematically operating and managing a wind power farm using the HSE management system according to any one of paragraphs 1 to 4,
(a) providing workers with information on safety training, environment, and equipment required for maintenance work at a wind power farm, but excluding workers from work if it is confirmed that the workers have not completed or incompletely completed safety training;
(b) evaluating the risk of accident occurrence based on the period, workers, tools, equipment, and procedures required for the maintenance work in step (a), and providing the results to the work manager and workers;
(c) collecting work site conditions and worker's physical information in real time during the work process, and requesting the work manager to stop the worker's work if an abnormality is detected from the collected information; and
(d) providing the wind power farm operator with the status of work carried out through steps (a) to (c) above, and information on accidents occurring during the work process and their response;
Including,
By comparing the worker's work progress with the target work progress set in advance according to the workload or schedule, if the actual work progress is less than the target work progress, confirmation is requested from the work manager so that the work manager can check for any accidents or abnormalities of the worker. HSE management method for systematic operation and management of a wind power farm, characterized in that it allows.