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"This book introduces a holistic approach to ship design and its optimisation for life-cycle operation. It deals with the scientific background of the adopted approach and the associated synthesis model, which follows modern computer aided engineering (CAE) procedures. It integrates techno-economic databases, calculation and multi-objective optimisation modules and s/w tools with a well-established Computer-Aided Design (CAD) platform, along with a Virtual Vessel Framework (VVF), which will allow virtual testing before the building phase of a new vessel. The resulting graphic user interface (GUI) and information exchange systems enable the exploration of the huge design space to a much larger extent and in less time than is currently possible, thus leading to new insights and promising new design alternatives. The book not only covers the various stages of the design of the main ship system, but also addresses relevant major onboard systems/components in terms of life-cycle performance to offer readers a better understanding of suitable outfitting details, which is a key aspect when it comes the outfitting-intensive products of international shipyards. The book disseminates results of the EU funded Horizon 2020 project HOLISHIP (www.holiship.eu).;"

"This book summarizes results of longstanding research and scientific contributions from many projects and relevant working groups. It collects and evaluates wind and wave climate projections under changing climate having design needs and marine safety in focus. Potential impact of projected climate change in met-ocean conditions on ships and offshore structures is discussed and illustrated by an example of the expected wave climate change on tanker design."

"ABSTRAKMajunya bagian sektor matirim Indonesia tidak lepas dari bertumbuhnya industri galangan. Dalam men-design kapal baru lebih dari 50 % total waktu man-hours dihabiskan untuk mementukan pipe routing. Lamanya waktu yang dibutuhkan dalam mendesain pipe routing terjadi karena tingkat kompleksitas dari tiap kapal yang baru didesign berbeda-beda dan tiap kapal baru membutuhkan design Ship Pipe Route Design (SPRD)nya sendiri-sendiri. Maka dari itu, perlu ada suatu cara untuk mempercepat/mendesign Ship Pipe Route Design. Optimasi pada Ship Pipe Route Design adalah salah satu cara yang digunakan untuk mendapatkan hasil pipe routing yang maksimal. Pipe routing dikatakan optimal bila memenuhi antara lain: banyak space yang masih tersedia setelah pipa dipasang, cost dari material yang digunakan sedikit, terdapat akses yang baik, dan nyaman ketika dilakukan perbaikan. Penelitian ini bertujuan untuk mengoptimalkan pipe routing. Caranya dengan menggunakan algoritma dalam bidang komputer. Algoritma yang digunakan adalah Algoritma Dijkstra. Algoritma Dijkstra merupakan algoritma yang berfokus dalam mencari jalur terdekat atau hasil terpendek (start point dan end point)

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ABSTRACTThe advancement of Indonesias Matirim sector cannot be separated from the growth of the shipyard industry. In designing new ships, more than 50% of the total working hour time is spent determining pipe routing. The length of time required to design the routing pipe occurs because the level of complexity of each newly designed ship is different, and each new ship requires its own Ship Pipe Route Design (SPRD). Therefore, there needs to be a way to accelerate/design the Ship Pipe Route Design. Optimization of the Ship Pipe Route Design is one of the methods used to get the maximum pipe routing results. Pipe routing is said to be optimal if it fulfils, among others: much space is still available after the pipe is installed, the cost of the material used is small, there is good access, and convenient when repairs are made. This study aims to optimize pipe routing. You do this by using algorithms in the computer field. The algorithm used is the Dijkstra algorithm. Dijkstras algorithm is an algorithm that focuses on finding the nearest path or shortest result (start point and endpoint)."

"Ship optimization design is critical to the preliminary design of a ship. With the rapid development of computer technology, the simulation-based design (SBD) technique has been introduced into the field of ship design. Typical SBD consists of three parts: geometric reconstruction; CFD numerical simulation; and optimization. In the context of ship design, these are used to alter the shape of the ship, evaluate the objective function and to assess the hull form space respectively. As such, the SBD technique opens up new opportunities and paves the way for a new method for optimal ship design.This book discusses the problem of optimizing ship’s hulls, highlighting the key technologies of ship optimization design and presenting a series of hull-form optimization platforms. It includes several improved approaches and novel ideas with significant potential in this field"

"Jakarta‟s problems such as flood and traffic inspired a PRASTI (Public Railway andStormwater Infrastructure) infrastructure design, which is a multifunctional tunnel whose one of itsfunction is to drain Western Canal Flood (BKB) overflow. The feasibility study of this project initiatedthe development of PRASTI Water Treatment Plant (WTP) which aimed to increase the addedfunctions of this infrastructure design. Before the construction of WTP, project feasibility study wasrequired to see investment feasibility so that investors could join in developing this infrastructure. Thisstudy aimed to analyze the feasibility of the infrastructure using Life Cycle Cost (LCC) method byconsidering cost of development, operational, and maintenance costs as well as revenue componentsin 2014-2045 period. Cost analysis was obtained from benchmarking to several countries andapplications of different technologies. Based on the study it‟s discovered that investment feasibility of aWTP project was strongly influenced by field condition (electricity and chemical needs) which will beused. Difference of operational and maintenance cost schemes in Life Cycle Cost analysis in PRASTIWTP project indicated that the project is financially feasible with IRR amounting to 23% (optimistic)and IRR value of 8% (pessimistic)."