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"ABSTRAKKonsep bangunan pintar adalah salah satu bentuk pengaplikasian teknologi yang telah dikembangkan pada industri konstruksi di dunia, namun masih belum diterapkan di Indonesia karena persepsi tingkat kebutuhan biayanya yang lebih besar daripada bangunan konvensional.Penelitian ini bertujuan untuk mengembangkan desain konseptual bangunan gedung dengan konsep bangunan pintar menggunakan pendekatan rekayasa nilai dalam rangka mendapatkan nilai tambah dari segi kualitas, efisiensi dan inovasi dengan mempertimbangkan nilai ekonominya. Survei kuesioner, studi rekayasa nilai, dan analisa life cycle cost dilakukan untuk mencapai tujuan penelitian.Hasil penelitian menunjukkan bahwa melalui inovasi teknologi, fungsi ? fungsi pada bangunan gedung dapat ditingkatkan menjadi bangunan pintar sehingga memberikan nilai tambah serta efisiensi biaya siklup hidup bangunan sebesar 38% dari gedung konvensional.

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ABSTRACT

Smart building concept is an implementation of technology developed in construction industry throughout the world, but yet to be implemented in Indonesia due to perception about the higher initial cost than the conventional one.

The objective of this research is to develop the conceptual design of building with intelligent building concept using value engineering approach in order to obtain added value in terms of quality, efficiency, and innovation regarding to its economic value. Questionnaire, value engineering study, and life cycle cost analysis are done to achieve that objective.

The result of this research shows that functions in building can be improved being intelligent through the technology innovation, hence it is able to add value and efficiency to its life cycle costing at about 38% compared to conventional building."

"Skripsi ini menyelidiki ide desain adaptive reuse pada arsitektur Renaisans. Proyek ini menekankan pada adopsi tipe bangunan Renaisans menjadi kompleks industri yang dirancang untuk smart farm dalam ruangan yang terletak di Emerald Agricultural College. Melalui eksplorasi arketipe dan adaptasi preseden tipologis, studi ini berupaya merumuskan kerangka arsitektur kohesif yang secara efektif memenuhi kebutuhan program tertentu. Proyek ini berlangsung dalam dua fase berbeda: Fase 1 melibatkan analisis studi kasus yang mendalam, sedangkan Fase 2 berpusat pada desain kompleks industri yang dioptimalkan untuk produksi tumbuhan obat. Tujuan utamanya adalah mengembangkan solusi desain yang mampu menghasilkan pendapatan kotor tahunan melebihi AU$ 20.000.000, sekaligus memastikan fleksibilitas untuk adaptasi di masa depan guna mengakomodasi beragam fungsi. Dengan mengintegrasikan prinsip-prinsip arsitektur sejarah dengan praktik pertanian kontemporer dan tujuan ekonomi, penelitian ini bertujuan untuk berkontribusi pada evolusi tipologi arsitektur dalam konteks pertanian industri modern.

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This undergraduate thesis delves into the idea of adaptive reuse design of a Renaissance architecture. The project emphasizes on adopting a Renaissance building type into an industrial complex tailored for an indoor smart farm situated at Emerald Agricultural College. Through an exploration of archetypes and the adaptation of typological precedents, the study seeks to formulate a cohesive architectural framework that effectively addresses specific programmatic requirements. The project unfolds in two distinct phases: Phase 1 involves an in-depth case study analysis, while Phase 2 centers on the design of an industrial complex optimized for herb production. A key objective is to develop a design solution capable of generating an annual gross income exceeding AU$ 20,000,000, while also ensuring flexibility for future adaptations to accommodate diverse functions. By integrating historical architectural principles with contemporary agricultural practices and economic goals, this research aims to contribute to the evolution of architectural typologies in the context of modern industrial agriculture."

"Fasad merupakan salah satu elemen penting yang berfungsi untuk mengatur aliran energi pada bangunan. Fasad adaptif diperlukan karena kemampuannya untuk menyediakan fleksibilitas dalam aspek aliran energi dan mampu merespon kondisi eksternal yang dinamis untuk mencapai kenyamanan termal bangunan sehingga mampu mengatur penggunaan energi dalam bangunan. Fasad adaptif dapat dicapai dengan beberapa strategi, salah satunya adalah penggunaan smart material yaitu material yang mampu merespon terhadap perubahan pada medan energi tertentu dengan cara mengubah properti materialnya. Skripsi ini bertujuan untuk melihat potensi smart material pada fasad bangunan dan aplikasinya dalam membentuk fasad adaptif untuk mengidentifikasi dampak pada konsumsi energi, terutama pada aspek space cooling. Untuk mengidentifikasi dampak pada konsumsi energi, simulasi energi dilakukan dengan output nilai Energy Use Intensity (EUI) pada bangunan dengan fasad eksisting dan pengubahan fasad berbahan smart material PV dan PCM. Hasil EUI antar fasad kemudian dibandingkan untuk menilai dampak fasad berbahan smart material pada konsumsi energi. Selain itu nilai EUI yang diperoleh juga dibandingkan dengan standar untuk menilai kategori penggunaan energi yang dapat dicapai oleh bangunan. Dari hasil simulasi diperoleh bahwa tidak terdapat pengurangan konsumsi energi pada pengubahan fasad berbahan smart material apabila dibandingkan dengan penggunaan fasad eksisting. Sebaliknya, beberapa variasi fasad berbahan smart material PV dan PCM menunjukan peningkatan pada solar heat gain dan konsumsi energi bangunan terutama pada aspek space cooling. Meski begitu, bangunan dengan variasi fasad smart material masih dapat dikategorikan sebagai bangunan energi efisien menurut standar penggunaan energi di Indonesia.

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Facade is an important element that regulates the flow of energy in buildings. Adaptive facades are needed for their ability to provide flexibility in terms of energy flow and for their responses to dynamic external conditions thus help achieve thermal comfort in buildings leading to the impact on energy use. Adaptive facades can be achieved with several strategies, one of which is the use of smart materials, namely materials that are able to respond to changes of certain energy fields by changing their properties. This thesis aims to assess the potential of smart materials for building facades and their applications in forming adaptive facades to identify their impact on energy consumption, especially for space cooling. To do so, energy simulations are carried out with the output of Energy Use Intensity (EUI) value on buildings. This simulation is conducted on a chosen building with existing facades and with variations of facades modification using smart materials; PV and PCM. EUI results between facades are then compared to assess the impact of each facades on energy consumption. In addition, the obtained EUI values are also compared with standards to assess the categories of energy use that can be achieved by the building. The simulation results show that there is no reduction in energy consumption in the modification of facades made of smart materials when compared to the use of the existing facade. In contrast, several variations of façades made of PV and PCM smart materials show an increase in indoor solar heat gain and building energy consumption, especially for space cooling purposes. Even so, buildings with smart material facade variations can still be categorized as energy efficient buildings according to energy use standards in Indonesia."

"Smart Material Systems: Model Development describes several novel applications currently under investigation that exploit the unique actuator and sensor capabilities of smart material compounds. In addition to present and projected applications, this book provides comprehensive coverage of both linear and nonlinear modeling techniques necessary to characterize materials in a manner that facilitates transducer design and control development. The author focuses on ferroelectric, magnetic, and shape memory compounds and also addresses applications exploiting amorphous and ionic polymers, magnetorheological compounds, and fiber optic sensors. Three classes of nonlinear models are discussed, all of which provide unified characterization frameworks for the broad class of combined compounds. An extensive discussion of structural models based on linear and nonlinear constitutive models is included, as is a chapter on numerical techniques for approximating solutions to the structural systems. The author also provides a synergistic treatment of material characterization, including significant discussion of the physics underlying nonlinear behavior, the development of nonlinear constitutive relations, the development of system models based on these constitutive relations, and the formulation of numerical techniques for approximating solutions to the resulting system models. To aid the understanding of both mathematical and physical terminology, an extensive glossary of terms is provided in an appendix. Furthermore, MATLAB software for representative models is provided at an accompanying website."