이 연구는 해상풍력발전 단지의 안전관리 제도의 현황과 구조적 한계를 분 석하고 이를 보완하기 위한 실효적 개선방안을 제시하는 것을 목적으로 한다. 기후변화 대응과 탄소중립 실현을 위한 핵심 전략으로 해상풍력발전이 급부상하고 있으나 해상이라는 고위험·고비용 환경에서 운영되는 특성상 안정적인 운 영을 위한 법제 기반은 미비한 실정이다. 현행 해상풍력발전 안전관리 제도는 전기사업법, 산업안전보건법, 해사안전기본법 등 다수의 법령과 부처에 의해 분산되어 있어 전 생애주기에 걸친 일관된 안전관리 체계 구축에 한계가 있으 며 운영·유지보수 단계의 실질적 대응 역량도 부족한 상황이다. 특히 해상풍력 발전 단지의 대형화·집적화, 기상이변 심화로 인한 고위험 상황에서 사고 예방 과 신속 대응을 위한 예방 중심의 법제화가 시급하다. 따라서 이 연구는 해상풍력법의 안전관리 조항 구체화, 주무부처 명확화, 하 위 법령 제정을 통한 이행력 확보, 해역 단위 누적영향평가 의무화, 국제표준 과의 정합성 확보 등을 중심으로 개선방안을 제시하였다. 또한 해상작업자의 자격 요건, 비상대응 매뉴얼, 자가 소방 및 응급의료체계 구비 등 해상특화 안 전관리 기준의 법제화를 통해 산업 현장에 실효적으로 적용될 수 있도록 제도 개선이 필요함을 강조하였다. 본 연구의 결과는 해상풍력발전 사업의 지속가능 한 확대와 국민 안전 확보를 위한 법제도 정비 및 정책 설계에 기여할 수 있을 것으로 기대된다.

기후위기 대응과 탄소중립 실현을 위한 전략으로 해상풍력발전이 주목받고 있 으며, 한국 정부도 이를 국가 에너지 정책의 핵심 축으로 삼아 대규모 확대를 추진 중이다. 그러나 해상풍력은 어업, 환경, 지역사회 등 다양한 해양 이용 주 체들과의 이해 충돌 속에서 추진되고 있으며 이로 인한 갈등은 사업 지연 또는 무산으로 이어지는 사례가 늘고 있다. 본 연구는 해상풍력 발전과 관련된 법 적·사회적 갈등 중에서도 어업손실 보상제도에 초점을 맞추어 현행 제도의 문제점을 분석하고 제도 개선 방향을 제시하였다. 연구 결과 현재의 어업손실 보상제도는 법적 근거가 미흡하고 보상 대상 범위 가 제한적이며, 손실 산정 기준 역시 현실과 괴리가 크다는 문제가 확인되었다. 특히 민간사업자의 경우 법적 보상 협의 의무가 명확하지 않아 사업자와 어민 간 갈등이 장기화되고 있다. 해외 주요국 사례(영국, 대만, 덴마크)를 분석한 결 과 이들 국가는 제도화된 협의 절차, 어민 참여형 평가 시스템, 정교한 피해 산정 기준을 통해 갈등을 최소화하고 있었다. 이에 본 논문은 해상풍력 어업손실 보상제도의 법제화, 현실적 산정 기준 마련, 어업 증빙을 위한 정보화 기반 구축을 핵심 과제로 제안한다. 이는 단순한 보 상을 넘어 지역사회와의 상생과 지속가능한 해상풍력 확산을 위한 제도적 기 반이 될 수 있다.

As global greenhouse gas reduction regulations are strengthened and the demand for eco-friendly energy increases, renewable energies, including offshore wind power, are growing rapidly. Unlike onshore wind power generation, offshore wind power is located in the ocean. As a result, the offshore wind power substructure is exposed to low temperatures, corrosion, and continuous fatigue loads. Therefore, selecting appropriate materials and welding techniques is crucial for durability. In this study, FCAW welding was performed on S355ML steel (EN10025) for offshore wind power applications. After the welding process, the mechanical properties of the welded joint were evaluated through tensile, low-temperature impact, and hardness tests to assess the welding condition. The study revealed that the tensile and yield strength of the welded joint were superior to those of the base material. Additionally, the impact strength at low temperatures was confirmed to exceed the standard.

In response to the global transition towards carbon neutrality, there's an increasing emphasis on sustainable energy solutions, with offshore wind power playing a crucial role, especially in South Korea. This study presents an AI-based safety management system specifically designed for offshore wind operators. At the heart of this system is a machine learning algorithm that processes sensor data to automatically recognize human behavior and improve the accuracy of predicting worker actions and conditions. Such predictive analytics not only refines the analysis of behavioral patterns, but also increases the effectiveness of accident prevention. The results of this research are expected to significantly improve safety measures in offshore wind facilities and further sustainable energy initiatives.

PURPOSES : Safety Evaluation of Wind Loads of Renewable Energy and Photovoltaic Power Structures. METHODS : Structural safety evaluation was conducted on the wind load of 3kW Photovoltaic Power Structures using ABAQUS. Wind speed was reviewed for 36m/s and 60m/s. Effective Mass and Mass Contribution of Photovoltaic Power Structures was utilized up to 90%. 7 steps were set and applied to structural analysis. RESULTS : As a result of the structural analysis, it was confirmed that the long-term blowing load was affected rather than the size of the wind load. Weak areas were identified at the point of the horizontal beam rather than the modules of the Photovoltaic Power Structures. In particular, it was confirmed that stress exceeding the allowable stress was generated at the junction. In order to secure the safety of Photovoltaic Power Structures, it is judged that reinforcement of the branch is necessary. CONCLUSIONS : The safety of Photovoltaic Power Structures structures for wind load is influenced by persistence rather than the size of the wind load. Therefore, in order to prevent this, it is judged that reinforcement of the branch is necessary.

Offshore wind power development has been promoted in countries around the world to cope with global warming. Despite its many advantages, offshore wind power affects the marine environment during construction and operation. As a result, the reduction of fishing areas, changes in the habitat of marine animals, damage to fishing gear, and impeding the safety of fishing activities are occurring. If the offshore wind power generation project is carried out, a fishing damage investigation is nescssary. There are only four fishing damage investigations related to offshore wind power, which are being conducted similarly to the existing fishing damage investigation related to offshore construction. Therefore, this study reviewed and analyzed the report on fisheries damage investigation related to offshore wind power conducted in Korea and suggested problems and improvement measures accordingly.

This study is to propose ways to improve the system for rational procedures for offshore wind power generation projects. The results of this study are summarized as follows. In order to quickly distribute and develop offshore wind power projects, the permitting period should be shortened through special laws, the government actively intervenes to support the formation and operation of privat-public councils to ensure residents' acceptance. In this way, it can be competitive in the future energy market. Above all, a special law (proposal) related to offshore wind power currently pending in the National Assembly should be passed as soon as possible. Finally, the government and local governments that manage public waters should provide active administrative support based on system improvement measures in consideration of these permits, and the project’s main body should minimize damage to the marine environment and ecosystem. Through these subject-specific roles, offshore wind power generation will be able to reduce carbon emissions and help establish a sustainable energy production system.

This paper is to study the technology of inspection and history management systems for wind power that are continuously increasing around the world. In the past, inspections and analysis of major devices in renewable energy system have been operated in an analog way that identifies problems through photography and passive method. To improve this problem, we conduct a study on VR-based inspection history management system using 3D texturing technique of drone image. The paper describes the current status and prospects of wind power, research and development of wind power blade inspection and history management systems, experiments and reviews in the field, and expected effects and future utilization of this technology. It is expected that the latest technology for inspection and management of renewable system will be secured and introduced to the site through the development research of this system to reduce maintenance costs and power generation costs.

타워형 집광태양열발전의 핵심요소인 헬리오스타트는 경량화를 통한 설비비 저감이 매우 중요한다. 반사판 면적 16m2의 기 존 헬리오스타트 대비 샌드위치 패널을 사용하여 무게를 50% 경량화한 헬리오스타트의 풍하중 평가를 수행하였다. 반사판이 수직, 45 도 경사인 경우에 대해 전산유체역학 해석을 하여 반사판에 작용하는 풍압을 산정하고 구조해석을 수행하여 최대응력의 발생부위 및 반사판의 변위에 의한 반사각도의 이격을 계산하였다. 45도 경사진 반사판이 바람이 불어오는 반대편으로 향한 경우가 바람을 마주보 는 배치보다 최대 풍하중이 더 크게 나타났으며, 반사판 풍하측으로의 유동박리에 의한 후류의 발달도 반사판의 배치에 따라 매우 상 이한 형태를 보였다. 경량화 모델의 경우 반사판 구동을 위한 기어의 배치를 변경하여 핵심 지지체인 기둥의 강성을 확보할 필요가 있 음을 확인하였다.

This study was conducted to investigate the effects of underwater noise caused by pile driving during marine construction on fish. In this study, the three gray rockfish were released about 1 km away from the construction site of wind power generation on July 18, 2018 and traced using two acoustic telemetry techniques. The behavior of the fish was analyzed by calculating the moving distance, swimming speed and direction of the gray rockfish. In the results of the acoustic tracking using the ship, the rockfish moved about 2.11 km for about two hours at a speed of 0.28 ± 0.14 m/s (0.94 TL/s). The bottom depth of the trajectory of the rockfish was 1.0 ± 0.6 m on average. There was a significant directionality in swimming direction of the gray rockfish, and there was no significant correlation between the swimming direction and tidal current direction. Moving distance during 5 minutes (5MD) during pile driving and finishing operations between rock surface and bedrock were 0.94-0.96 times (76.0-77.0 m) and 1.81-2.73 times (146.0-219.5 m), respectively, compared with no pile driving. This study is expected to be used as a basic data of fish behavior research on underwater noise.

In this study, the yaw misalignment value of wind turbine was measured using Lidar and it was analyzed the effect of vibration reduction and power performance improvement when applied to turbine. It was confirmed that the vibration of the main bearing and the gear box of the wind turbine was partially reduced. Also it was found that the output performance was improved when the wind speed was over 8m/s. As a result, it was also found that the annual energy production(AEP) was improved when the average annual wind speed of the wind farm was over 6m/s. Converted to AEP, the AEP improved about 1% and 4%, when the annual wind speed was 6m/s and 11m/s respectively, which resulted in an improvement of about 1~4% through the yaw misalignment correction of the wind turbine.