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점점 더 엄격해지는 매연 배출 표준과 규제로 인해 선박 성능의 모든 측면에서 개선이 필요하게 되었습니다. 성능 목표를 성공적으로 달성하기 위해서는 혁신적인 설계를 짧은 기간 안에 효율적으로 제공할 수 있어야 합니다. Siemens 솔루션을 사용하면 선박 설계의 모든 측면을 실험하고 필요한 설계 표준을 충족하거나 그 이상의 만족도를 제공할 수 있습니다.

Enter the short summary here - no longer than 75 words. This is the version of the summary that will appear when this Solution is used in a promotion format.

Ship construction is a complex and lengthy process that demands careful planning and timely decision-making. Plan, optimize and validate ship construction processes before building. Use a broad range of tools to streamline your process planning workflows, automate non-value-added planning tasks and validate the best shipbuilding plan. These tools facilitate process design and sequencing, production BOM and BOP management, time management, 3D shipyard layout and ergonomic analysis. Control ship and production lifecycles from process planning and detailed engineering to full production by connecting the entire value chain to realize the best production strategy.

HVAC systems are critical for ensuring the safety and comfort of crew members and passengers. Getting HVAC systems right can improve both energy requirements and internal space utilization. Reduce design time and energy consumption, improve production quality, and maximize available internal space with our next-generation software for designing HVAC equipment and systems for ships and offshore structures.

The demand for sustainable ships is growing significantly. By ensuring that future classes of ships and the shipyards that design and build them are fully compliant with both current and future environmental requirements in all stages of a ship lifecycle, this solution will support your eco-design initiatives and help you minimize the risks and costs associated with noncompliance.

유체 역학 성능 엔지니어링은 선박을 최적으로 설계하는 데 매우 중요합니다. Siemens 솔루션을 사용하면 전체적으로 현실적인 작동 조건에서 선박의 유체 역학을 해석할 수 있습니다. 가상 예인 탱크를 사용하여 선체 저항, 자동 추진, 조종, 선박 가속 또는 부속물 형상 및 배치 등의 모든 흐름 또는 성능 측면을 실험하십시오.

연료 효율을 개선하기 위해서는 엔진 및 파워트레인 설계에 대한 종합적인 접근방식이 필요합니다. 테스트와 고급 시뮬레이션이 결합된 Siemens 포트폴리오를 사용하면 엔진 설계와 통합의 모든 측면을 상세하게 해석할 수 있습니다.

Sound structural integrity is critical for viable operation, crew and passengers’ safety and comfort, as well as minimal environmental impact. Our simulation and testing solutions can predict fatigue life and hotspots while optimizing a product for durability.

Propeller performance is the key for efficient conversion of generated power into thrust force. We provide all the necessary tools to analyze propulsion system performance, from the propeller in isolation to sub-systems and full system performance for complete power management.  Predict propeller performance, cavitation, and erosion using our hydrodynamics simulation capabilities, then analyze noise and dynamic response, vibration and structural integrity with our powerful 3D tools.

선박의 공기 역학적 성능을 최적화하는 것은 승객의 쾌적성은 물론 안전하고 효율적인 작업을 위해 필수적입니다. Siemens 솔루션을 사용하여 상부 구조물의 항력과 풍하중을 예측하고 공기 역학적 효율을 개선하십시오. Siemens의 다중 물리학 시뮬레이션 도구를 사용하여 매연 배출과 헬리패드 안전성을 분석함으로써 설계 프로세스 초기에 심각한 상황을 평가하십시오.

Ensuring efficient vessel performance requires integration and optimization of multiple complex systems. Our solutions allow designers to check system architecture impacts on the complete vessel performance before any physical development takes place. Simulate and validate components early in the design cycle, and accurately predict system performance.

Today’s marine market demands greener, smarter, and more high-tech vessels. To remain competitive, shipbuilders must deliver those vessels on time, on budget, and on quality. Our Integrated Ship Design and Engineering solution enables marine companies to remain in control of the design spiral. By bringing all their multidisciplinary design data, processes, and tools in one centralized environment, they can break down information and collaboration silos, boost innovation, and improve enterprise productivity.

As the demand for high value-added vessels increases, so does the need to identify and mitigate the risks associated with more complex design and manufacturing processes. This need is compounded by the current climate of unpredictability and increased competition in the shipbuilding market. To remain competitive, a shipyard must deliver bids that are both attractive and accurate. To this end, having a fully planned, resourced, and budgeted end-to-end project management solution has become critical.

To meet today’s regulations and market demands, ships need to be greener, safer, smarter, more cost-effective, more connected, and more adaptable than ever before. As complexity increases, more parties need to be involved in the vessel design, manufacturing, and maintenance processes. With ship service lives reaching up to 40 years for a commercial vessel and 50 years for a naval one, it becomes apparent that robust ship lifecycle management is not optional; it is critical.

As the economic slowdown continues to impact the already overcrowded shipping market, ship owners and operators are looking to maximize profit margins by lowering operational costs and improving vessel availability. At the same time, the rise of information and communication technology is opening new horizons for shipping companies and shipbuilders alike. So how can the marine industry capitalize on the sea of newly available data to improve the current ship service and maintenance model?