TY  - CHAP
AU  - Gašić, Miloš
AU  - Jurenić, Tatjana
AU  - Rakonjac, Ivana
PY  - 2018
UR  - https://raf.arh.bg.ac.rs/handle/123456789/1354
AB  - The process of adaptation of the buildings in architectural projects is codified by a set of energy efficiency regulations that are mandatory and which affect designers. To fulfil these requirements certain investments are necessary, which influence the economic performance of the project in construction phase, as well as in the long run over the building’s exploitation period. Therefore, an analysis of the economic effectiveness of the project is needed, which would also take into consideration the operation phase of the project, to include the whole life cycle. The methodology of the life cycle costs and savings analysis is presented in the following sections, which would be adjusted to the specific preconditions of the energy efficiency improvement projects, availability and possibility to gather relevant input data, as well as the perspective and understanding of architects as prospective analysis practitioners. The format of the proposed study is created to comprise several steps or phases, and their contents would be further elaborated. The methods that are applied include analytical procedure, comparisons, deduction and elaboration of the existing tools, and techniques and methods in the field of economic analyses in architecture and building construction. The resulting procedure allows for practical and theoretical implementation in actual projects. It is simple and straightforward to conduct, easy to understand, and open for expansion.
PB  - Delft : TU Delft Open
T2  - Energy Resources and Building Performance
T1  - Economic Evaluation of the Energy Efficiency Improvement Projects
SP  - 231
EP  - 248
UR  - https://hdl.handle.net/21.15107/rcub_raf_1354
ER  - 

@inbook{
author = "Gašić, Miloš and Jurenić, Tatjana and Rakonjac, Ivana",
year = "2018",
abstract = "The process of adaptation of the buildings in architectural projects is codified by a set of energy efficiency regulations that are mandatory and which affect designers. To fulfil these requirements certain investments are necessary, which influence the economic performance of the project in construction phase, as well as in the long run over the building’s exploitation period. Therefore, an analysis of the economic effectiveness of the project is needed, which would also take into consideration the operation phase of the project, to include the whole life cycle. The methodology of the life cycle costs and savings analysis is presented in the following sections, which would be adjusted to the specific preconditions of the energy efficiency improvement projects, availability and possibility to gather relevant input data, as well as the perspective and understanding of architects as prospective analysis practitioners. The format of the proposed study is created to comprise several steps or phases, and their contents would be further elaborated. The methods that are applied include analytical procedure, comparisons, deduction and elaboration of the existing tools, and techniques and methods in the field of economic analyses in architecture and building construction. The resulting procedure allows for practical and theoretical implementation in actual projects. It is simple and straightforward to conduct, easy to understand, and open for expansion.",
publisher = "Delft : TU Delft Open",
journal = "Energy Resources and Building Performance",
booktitle = "Economic Evaluation of the Energy Efficiency Improvement Projects",
pages = "231-248",
url = "https://hdl.handle.net/21.15107/rcub_raf_1354"
}

Gašić, M., Jurenić, T.,& Rakonjac, I.. (2018). Economic Evaluation of the Energy Efficiency Improvement Projects. in Energy Resources and Building Performance
Delft : TU Delft Open., 231-248.
https://hdl.handle.net/21.15107/rcub_raf_1354

Gašić M, Jurenić T, Rakonjac I. Economic Evaluation of the Energy Efficiency Improvement Projects. in Energy Resources and Building Performance. 2018;:231-248.
https://hdl.handle.net/21.15107/rcub_raf_1354 .

Gašić, Miloš, Jurenić, Tatjana, Rakonjac, Ivana, "Economic Evaluation of the Energy Efficiency Improvement Projects" in Energy Resources and Building Performance (2018):231-248,
https://hdl.handle.net/21.15107/rcub_raf_1354 .

TY  - CHAP
AU  - Radivojević, Ana
AU  - Đukanović, Ljiljana
PY  - 2018
UR  - https://raf.arh.bg.ac.rs/handle/123456789/824
AB  - Modern design and construction strives to establish an appropriate relationship between
three characteristic poles: man – the user, the building, and the environment. This chapter
seeks to highlight this problem by considering the relevant characteristics of the building’s
thermal envelope, i.e. the impact that the choice of materials has on the behaviour of the
building as a whole. Today, we are intrigued by the behaviour of a building as a system,
mostly through the prism of the amount of energy it consumes during its existence.
On the one hand, this leads us to the need for adequate knowledge of the basic principles
of building physics, and on the other, to the awareness of the relevant properties of
the materials that we use in the construction process, in order to meet the comfort
requirements of the user. Although this chapter emphasises the problem of meeting the
thermal comfort requirements, in the example of the review and analysis of characteristic
types of residential buildings in the Belgrade area, the scope of meeting the overall comfort
requirements has been considered, as well as the interdependence that exists between
different types of comfort (thermal, indoor air, sound, and light).
PB  - Delft : TU Delft Open
T2  - Energy: resources and building performance
T1  - Material Aspect of Energy Performance and Thermal Comfort in Buildings
SP  - 61
EP  - 86
UR  - https://hdl.handle.net/21.15107/rcub_raf_824
ER  - 

@inbook{
author = "Radivojević, Ana and Đukanović, Ljiljana",
year = "2018",
abstract = "Modern design and construction strives to establish an appropriate relationship between
three characteristic poles: man – the user, the building, and the environment. This chapter
seeks to highlight this problem by considering the relevant characteristics of the building’s
thermal envelope, i.e. the impact that the choice of materials has on the behaviour of the
building as a whole. Today, we are intrigued by the behaviour of a building as a system,
mostly through the prism of the amount of energy it consumes during its existence.
On the one hand, this leads us to the need for adequate knowledge of the basic principles
of building physics, and on the other, to the awareness of the relevant properties of
the materials that we use in the construction process, in order to meet the comfort
requirements of the user. Although this chapter emphasises the problem of meeting the
thermal comfort requirements, in the example of the review and analysis of characteristic
types of residential buildings in the Belgrade area, the scope of meeting the overall comfort
requirements has been considered, as well as the interdependence that exists between
different types of comfort (thermal, indoor air, sound, and light).",
publisher = "Delft : TU Delft Open",
journal = "Energy: resources and building performance",
booktitle = "Material Aspect of Energy Performance and Thermal Comfort in Buildings",
pages = "61-86",
url = "https://hdl.handle.net/21.15107/rcub_raf_824"
}

Radivojević, A.,& Đukanović, L.. (2018). Material Aspect of Energy Performance and Thermal Comfort in Buildings. in Energy: resources and building performance
Delft : TU Delft Open., 61-86.
https://hdl.handle.net/21.15107/rcub_raf_824

Radivojević A, Đukanović L. Material Aspect of Energy Performance and Thermal Comfort in Buildings. in Energy: resources and building performance. 2018;:61-86.
https://hdl.handle.net/21.15107/rcub_raf_824 .

Radivojević, Ana, Đukanović, Ljiljana, "Material Aspect of Energy Performance and Thermal Comfort in Buildings" in Energy: resources and building performance (2018):61-86,
https://hdl.handle.net/21.15107/rcub_raf_824 .

TY  - CHAP
AU  - Kosanović, Saja
AU  - Folić, Branislav
AU  - Radivojević, Ana
PY  - 2018
UR  - https://raf.arh.bg.ac.rs/handle/123456789/825
AB  - Abstract	The occurrence of frequent shifts in weather conditions and extreme weather and climate
events brings numerous direct and indirect consequences for the built environment,
increases the possibility for disaster occurrence, and accordingly sets new challenges
for contemporary architecture. The design focus on climate change mitigation, i.e.
on sustainable and, above all, energy efficient buildings, therefore needs to be expanded
to strengthen the capacity of such buildings to withstand climate change manifestations
while remaining functional. To design for optimal climate change-related performance
of buildings, now and in the future, a resilience scenario is needed. This work analyses
climate change complexity and dynamics as key factors that articulate the design strategy
for climate-resilient buildings. Based on the relevance of reviewed risks, variability,
and uncertainty regarding climate change, this work maps a generic design framework,
explains the meaning of ‘transposed regionalism’, and discusses the relationship between
resilience and the adaptation of buildings in (un)predictable climate futures.
PB  - Delft : TU Delft Open
T2  - Sustainable and Resilient Building Design: Approaches, Methods and Tools
T1  - Approach to Design for Resilience to Climate Change
SP  - 37
EP  - 48
UR  - https://hdl.handle.net/21.15107/rcub_raf_825
ER  - 

@inbook{
author = "Kosanović, Saja and Folić, Branislav and Radivojević, Ana",
year = "2018",
abstract = "Abstract	The occurrence of frequent shifts in weather conditions and extreme weather and climate
events brings numerous direct and indirect consequences for the built environment,
increases the possibility for disaster occurrence, and accordingly sets new challenges
for contemporary architecture. The design focus on climate change mitigation, i.e.
on sustainable and, above all, energy efficient buildings, therefore needs to be expanded
to strengthen the capacity of such buildings to withstand climate change manifestations
while remaining functional. To design for optimal climate change-related performance
of buildings, now and in the future, a resilience scenario is needed. This work analyses
climate change complexity and dynamics as key factors that articulate the design strategy
for climate-resilient buildings. Based on the relevance of reviewed risks, variability,
and uncertainty regarding climate change, this work maps a generic design framework,
explains the meaning of ‘transposed regionalism’, and discusses the relationship between
resilience and the adaptation of buildings in (un)predictable climate futures.",
publisher = "Delft : TU Delft Open",
journal = "Sustainable and Resilient Building Design: Approaches, Methods and Tools",
booktitle = "Approach to Design for Resilience to Climate Change",
pages = "37-48",
url = "https://hdl.handle.net/21.15107/rcub_raf_825"
}

Kosanović, S., Folić, B.,& Radivojević, A.. (2018). Approach to Design for Resilience to Climate Change. in Sustainable and Resilient Building Design: Approaches, Methods and Tools
Delft : TU Delft Open., 37-48.
https://hdl.handle.net/21.15107/rcub_raf_825

Kosanović S, Folić B, Radivojević A. Approach to Design for Resilience to Climate Change. in Sustainable and Resilient Building Design: Approaches, Methods and Tools. 2018;:37-48.
https://hdl.handle.net/21.15107/rcub_raf_825 .

Kosanović, Saja, Folić, Branislav, Radivojević, Ana, "Approach to Design for Resilience to Climate Change" in Sustainable and Resilient Building Design: Approaches, Methods and Tools (2018):37-48,
https://hdl.handle.net/21.15107/rcub_raf_825 .

TY  - BOOK
PY  - 2018
UR  - https://raf.arh.bg.ac.rs/handle/123456789/799
AB  - Today, humankind is completely dependent on energy. Energy is indispensable for growth and life on Earth, and it is also of key importance for living comfortably – for heating, lighting, cooling, ventilation, operation of machines and appliances, for transport, etc. The major energy-generating source is the sun, sending the energy to Earth and making life on our planet possible. This energy is free of charge and without negative effects. However, we only know how to use and convert a small part of the solar energy reaching the Earth into other forms of energy necessary to improve the conditions for life and the human comfort. 

The production of energy that drives our civilisation still depends heavily on the use of non-renewable fossil reserves. The dependence on coal, oil, and natural gas is a major problem faced by the humankind. Buildings need energy throughout their life cycle, which consists of six stages – extraction of raw materials, production of materials and components, transport sale, construction, operation and, finally, demolition. Measures aimed at reducing the dependence of a building on energy throughout its life cycle may be implemented on at least two levels. The first important decision is to locate a building in the environment in a manner such that it will help improve the living conditions in the building by making use of the natural features of the site: 

by proper orientation of the building to facilitate heating and lighting by means of solar energy; 
by using the wind to facilitate natural ventilation; 
by including vegetation in the external and internal environment to improve the quality of air; and 
by observing the relevant distance from the adjacent buildings to prevent the shading effect. 
The second important decision in the building design process refers to the selection of materials and building technology. Every stage of the building’s lifecycle calls for a choice that will contribute to the lower energy consumption of the building: 

extraction of raw materials – choice of raw materials (timber, stone, earth), as they are not energy-intensive; 
production of materials and components – choice of materials whose production requires little energy; 
sale of materials and components – choice of materials and components that are produced locally near the construction site and not subject to great transport distances; 
construction of the building – choice of building technologies that do not require much energy; 
use or operation of the building – the building should be designed in such a manner as to require little energy for heating, cooling, lighting, and ventilation;
demolition – the building should be designed in a manner that permits the structure to be disassembled into the basic elements that can be sorted by specific materials and, if possible, reused or recycled.
The use of energy in buildings is thus a complex problem, but it can be reduced and alleviated by making appropriate decisions. Therefore, architects face a major and responsible task of designing the built environment in such a way that its energy dependence will be reduced to a minimum, while at the same time being able to provide comfortable living conditions. Today, architects have many tools at their disposal, facilitating the design process and simultaneously ensuring proper assessment in the early stages of building design.

The purpose of this book is to present ongoing research from the universities involved in the project Creating the Network of Knowledge Labs for Sustainable and Resilient Environments (KLABS). This book attempts to highlight the problem of energy use in buildings and propose certain solutions. It consists of nine chapters, organised in three parts. The gathering of chapters into parts serves to identify the different themes that the designer needs to consider, namely energy resources, energy use and comfort, and energy efficiency. 

Part 1, entitled “Sustainable and Resilient Energy Resources,” sets off by informing the reader about the basic principles of energy sources, production, and use. The chapters give an overview of all forms of energies and energy cycle from resources to end users and evaluate the resilience of renewable energy systems. This information is essential to realise that the building, as an energy consumer, is part of a greater system and the decisions can be made at different levels.

Part 2, entitled “Energy and Comfort in the Built Environment”, explain the relationship between energy use and thermal comfort in buildings and how it is predicted. Buildings consume energy to meet the users’ needs and to provide comfort. The appropriate selection of materials has a direct impact on the thermal properties of a building. Moreover, comfort is affected by parameters such as temperature, humidity, air movement, air quality, lighting, and noise. Understanding and calculating those conditions are valuable skills for the designers. 

After the basics of energy use in buildings have been explained, Part 3, entitled “Energy Saving Strategies” aims to provide information and tools that enable an energy- and environmentally-conscious design. This part is the most extensive as it aims to cover different design aspects. Firstly, passive and active measures that the building design needs to include are explained. Those measures are seen from the perspective of heat flow and generation. The Passive House concept, which is explained in the second chapter of Part 3, is a design approach that successfully incorporates such measures, resulting in low energy use by the building. Other considerations that the following chapters cover are solar control, embodied energy and CO2 emissions, and finally economic evaluation. The energy saving strategies explained in this book, despite not being exhaustive, provide basic knowledge that the designer can use and build upon during the design of new buildings and existing building upgrades. 

In the context of sustainability and resilience of the built environment, the reduction of energy demand is crucial. This book aims to provide a basic understanding of the energy flows in buildings and the subsequent impact for the building’s operation and its occupants. Most importantly, it covers the principles that need to be taken into account in energy efficient building design and demonstrates their effectiveness. 

Designers are shaping the built environment and it is their task to make energy-conscious and informed decisions that result in comfortable and resilient buildings.
PB  - Delft : TU Delft Open
T1  - Energy : resources and building performance
UR  - https://hdl.handle.net/21.15107/rcub_raf_799
ER  - 

@book{
year = "2018",
abstract = "Today, humankind is completely dependent on energy. Energy is indispensable for growth and life on Earth, and it is also of key importance for living comfortably – for heating, lighting, cooling, ventilation, operation of machines and appliances, for transport, etc. The major energy-generating source is the sun, sending the energy to Earth and making life on our planet possible. This energy is free of charge and without negative effects. However, we only know how to use and convert a small part of the solar energy reaching the Earth into other forms of energy necessary to improve the conditions for life and the human comfort. 

The production of energy that drives our civilisation still depends heavily on the use of non-renewable fossil reserves. The dependence on coal, oil, and natural gas is a major problem faced by the humankind. Buildings need energy throughout their life cycle, which consists of six stages – extraction of raw materials, production of materials and components, transport sale, construction, operation and, finally, demolition. Measures aimed at reducing the dependence of a building on energy throughout its life cycle may be implemented on at least two levels. The first important decision is to locate a building in the environment in a manner such that it will help improve the living conditions in the building by making use of the natural features of the site: 

by proper orientation of the building to facilitate heating and lighting by means of solar energy; 
by using the wind to facilitate natural ventilation; 
by including vegetation in the external and internal environment to improve the quality of air; and 
by observing the relevant distance from the adjacent buildings to prevent the shading effect. 
The second important decision in the building design process refers to the selection of materials and building technology. Every stage of the building’s lifecycle calls for a choice that will contribute to the lower energy consumption of the building: 

extraction of raw materials – choice of raw materials (timber, stone, earth), as they are not energy-intensive; 
production of materials and components – choice of materials whose production requires little energy; 
sale of materials and components – choice of materials and components that are produced locally near the construction site and not subject to great transport distances; 
construction of the building – choice of building technologies that do not require much energy; 
use or operation of the building – the building should be designed in such a manner as to require little energy for heating, cooling, lighting, and ventilation;
demolition – the building should be designed in a manner that permits the structure to be disassembled into the basic elements that can be sorted by specific materials and, if possible, reused or recycled.
The use of energy in buildings is thus a complex problem, but it can be reduced and alleviated by making appropriate decisions. Therefore, architects face a major and responsible task of designing the built environment in such a way that its energy dependence will be reduced to a minimum, while at the same time being able to provide comfortable living conditions. Today, architects have many tools at their disposal, facilitating the design process and simultaneously ensuring proper assessment in the early stages of building design.

The purpose of this book is to present ongoing research from the universities involved in the project Creating the Network of Knowledge Labs for Sustainable and Resilient Environments (KLABS). This book attempts to highlight the problem of energy use in buildings and propose certain solutions. It consists of nine chapters, organised in three parts. The gathering of chapters into parts serves to identify the different themes that the designer needs to consider, namely energy resources, energy use and comfort, and energy efficiency. 

Part 1, entitled “Sustainable and Resilient Energy Resources,” sets off by informing the reader about the basic principles of energy sources, production, and use. The chapters give an overview of all forms of energies and energy cycle from resources to end users and evaluate the resilience of renewable energy systems. This information is essential to realise that the building, as an energy consumer, is part of a greater system and the decisions can be made at different levels.

Part 2, entitled “Energy and Comfort in the Built Environment”, explain the relationship between energy use and thermal comfort in buildings and how it is predicted. Buildings consume energy to meet the users’ needs and to provide comfort. The appropriate selection of materials has a direct impact on the thermal properties of a building. Moreover, comfort is affected by parameters such as temperature, humidity, air movement, air quality, lighting, and noise. Understanding and calculating those conditions are valuable skills for the designers. 

After the basics of energy use in buildings have been explained, Part 3, entitled “Energy Saving Strategies” aims to provide information and tools that enable an energy- and environmentally-conscious design. This part is the most extensive as it aims to cover different design aspects. Firstly, passive and active measures that the building design needs to include are explained. Those measures are seen from the perspective of heat flow and generation. The Passive House concept, which is explained in the second chapter of Part 3, is a design approach that successfully incorporates such measures, resulting in low energy use by the building. Other considerations that the following chapters cover are solar control, embodied energy and CO2 emissions, and finally economic evaluation. The energy saving strategies explained in this book, despite not being exhaustive, provide basic knowledge that the designer can use and build upon during the design of new buildings and existing building upgrades. 

In the context of sustainability and resilience of the built environment, the reduction of energy demand is crucial. This book aims to provide a basic understanding of the energy flows in buildings and the subsequent impact for the building’s operation and its occupants. Most importantly, it covers the principles that need to be taken into account in energy efficient building design and demonstrates their effectiveness. 

Designers are shaping the built environment and it is their task to make energy-conscious and informed decisions that result in comfortable and resilient buildings.",
publisher = "Delft : TU Delft Open",
title = "Energy : resources and building performance",
url = "https://hdl.handle.net/21.15107/rcub_raf_799"
}

(2018). Energy : resources and building performance. 
Delft : TU Delft Open..
https://hdl.handle.net/21.15107/rcub_raf_799

Energy : resources and building performance. 2018;.
https://hdl.handle.net/21.15107/rcub_raf_799 .

"Energy : resources and building performance" (2018),
https://hdl.handle.net/21.15107/rcub_raf_799 .