Re-defining the Architectural Design Process Through Building a Decision Support Framework for Design with Reused Building Materials and Components

Ali, Ahmed Kamal

07 December 2012

Waste from construction and demolition-building activities is increasing every day. Landfills have almost reached their capacity. When thinking about the negative impact of demolishing activities on the environment it becomes very necessary to think about reusing and recycling building materials in new construction or perhaps better recycling our thoughts on how to make use of waste materials. In Kevin Lynch's book, Wasting Away, he wrote: "Architects must begin to think about holes in the ground and about flows of materials." Studies show that construction and demolition activities are the primary source of solid waste worldwide. For example construction and demolition wastes constitute about 40% of the total solid waste stream in the United States. The growing interest in materials and resource conservation in the United States is inherent in the growth of green building practices. The USGBC identifies six categories in the Materials and Resources (MR) section of LEED. One of these six categories is Resource Reuse (RR). Interestingly enough, a recent study about the cost of green buildings indicated that RR was the category credits least often achieved in most LEED certified projects. Literature suggests that there are a number of constraints and barriers to resource reuse primarily due to the complexity of buildings but perhaps the most important barrier, according to many architects, is the lack of easily accessible information to the design team on resource reuse. Therefore, as we promote the idea of building material reuse to a wider audience of designers and architects, we mus not forget that in the Architecture, Engineering and Construction (AEC) industry, both Reuse and Recycle terms are used interchangeably without yet a clear distinction between them. The use of arbitrary descriptions to distinguish reuse from recycle has caused nothing but more confusion to the public. This study argues that the real distinction between reuse and recycle exists in Knowledge and Information. This suggests that design with reuse requires a paradigm shift in the required knowledgebase and the way information flows within the design process. Unfortunately, the structure of this paradigm shift is not known and has not been well defined. Since knowledge forms the core of building a Decision Support Systems (DSS) for a design team in order to consider reuse, it is necessary to capture the required knowledge and information from the industry experts through a Knowledge Acquisition (KA) process. This knowledge can then be used to 1) identify the building material reuse criteria and 2) to build a prescriptive decision model and 3) to map the process design of the current traditional architectural design workflow and the proposed one. The overarching goal of this study is to use the building material reuse knowledgebase for 1) building a Unified Virtual Repository database to be connected to all available physical repositories and share a unified standard of information. 2) When the unified virtual repository is integrated with the Building Information Modeling (BIM) database, the DSS can work as a feedback and feed forward support for architects and designers as they consider building material reuse in new designs and constructions. / Ph. D.

Reuse

Building Materials

Design Process

Salvage

Recycle

Waste

Building Life Cycle

Process Design

Dynamic Knowledge Base

Time, Cost, and Environmental Impact Analysis for Sustainable Design at Multiple Building Levels

Inyim, Peeraya

23 March 2015

Construction projects are complex endeavors that require the involvement of different professional disciplines in order to meet various project objectives that are often conflicting. The level of complexity and the multi-objective nature of construction projects lend themselves to collaborative design and construction such as integrated project delivery (IPD), in which relevant disciplines work together during project conception, design and construction. Traditionally, the main objectives of construction projects have been to build in the least amount of time with the lowest cost possible, thus the inherent and well-established relationship between cost and time has been the focus of many studies. The importance of being able to effectively model relationships among multiple objectives in building construction has been emphasized in a wide range of research. In general, the trade-off relationship between time and cost is well understood and there is ample research on the subject. However, despite sustainable building designs, relationships between time and environmental impact, as well as cost and environmental impact, have not been fully investigated. The objectives of this research were mainly to analyze and identify relationships of time, cost, and environmental impact, in terms of CO2 emissions, at different levels of a building: material level, component level, and building level, at the pre-use phase, including manufacturing and construction, and the relationships of life cycle cost and life cycle CO2 emissions at the usage phase. Additionally, this research aimed to develop a robust simulation-based multi-objective decision-support tool, called SimulEICon, which took construction data uncertainty into account, and was capable of incorporating life cycle assessment information to the decision-making process. The findings of this research supported the trade-off relationship between time and cost at different building levels. Moreover, the time and CO2 emissions relationship presented trade-off behavior at the pre-use phase. The results of the relationship between cost and CO2 emissions were interestingly proportional at the pre-use phase. The same pattern continually presented after the construction to the usage phase. Understanding the relationships between those objectives is a key in successfully planning and designing environmentally sustainable construction projects.

Sustainable Design

Building Life Cycle

Multiple Objectives

Energy Simulation

Genetic Algorithms

Monte Carlo Simulation

Civil Engineering

Construction Engineering and Management

Náklady životního cyklu budovy / Building Life Cycle Costs

Bohadlová, Darina

January 2012

This diploma thesis deals with the life-cycle cost of the building for teaching and research. The theoretical part deals with the introduction of life-cycle cost method. A description ofdetermining life-cycle cost and procedure of processing. In the practical part of the budgetis prepared surveyed the building, which is divided into functional parts and the fixed costs of repair and reconstruction over the lifetime of the building. At the end of life are roughlydetermined the cost of demolition and waste removal. This whole process is summarized in the table, which sets the cost of operating the building throughout its life.

Evaluation of Changes between the Material and Resource Category of LEED v4.0 and v3.0 as it Pertains to New Construction and Major Renovations

Pai, Vibha

January 2017

No description available.

Civil Engineering

LEED

Whole building life cycle assessment

Eco labels

Material and resource

GreenScreen benchmark

Multi attribute optimization

Funkční díly v ocenění stavebního objektu / Functional parts valuation of the building

Ševčík, Jaroslav

January 2016

Diploma thesis deals with comparing of current awards by Classification of building structures and works and awards by Functional parts. It is possible to calculate Building life cycle costs by Functional parts. This is definately the advantage of the system because the calculation cannot be done by Classification of building structures and works. A new law on public procurement deals with Building life cycle costs as an evaluation criterion. So it is recommended to use Functional parts awards. The other goal of the thesis is to find bridges between Functional parts and the issue of BIM. BIM is a trend of global construction industry.

Quantifying the environmental dimension of sustainability for the built environment : with a focus on low-cost housing in South Africa

Brewis, Chandre

03 1900

Thesis (MScEng)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: Sustainability is difficult to achieve in a world where population and economic growth leads to increased production of greenhouse gases, resource depletion and waste generation. Today, the environmental dimension of sustainability, which is more commonly known as the natural environment, and the construction industry are two terms often mentioned together. In Europe, 12.4 % of greenhouse gas emissions are induced by the construction and manufacturing industry (Maydl, 2004). Also, 50 % of the resources extracted are used in the construction industry and more than 25 % of waste generated is construction and demolition waste. In South Africa, the building sector accounts for approximately 23 % of the total greenhouse gas emissions (Milford, 2009). Furthermore, 60 % of investment is made in the residential sector where 33 % of the building stock is the focus of the government’s Housing Programme. It is seen that the construction industry significantly impacts the natural environment and the aim should be to reduce this negative impact. Within the local residential sector, the low-cost housing sector presents potential when it comes to sustainable improvements. Each of the three spheres of sustainability, namely economy, natural environment and society, plays a crucial role in this sector. Various studies have been done on the economical and social fields, but little information exists on the impact low-cost houses have on the environment. A need arises to scientifically quantify the environmental impact hereof, therefore it is chosen as the focus of this study. Various methods in order to determine the environmental impact of the built environment exist globally, but they tend to be complex, are used in conjunction with difficult to understand databases and require expensive software. A need for a local quantification method with which to determine the environmental impact of the built environment, more specifically low-cost housing, has been identified. A simple and easy-to-use analysis-orientated quantification method is proposed in this study. The quantification method is compiled with indicators related to the local conditions; these include Emissions, Resource Depletion and Waste Generation. The end objective is to provide the user with an aggregated total value called the Environmental Impact Index to ease comparison of possible alternatives. The quantification method is developed as a mathematical tool in the form of a partial Life Cycle Assessment which can aid in objective decision making during the conception and design phase of a specific project. Note that only the Pre-Use Phase of the building life cycle is considered during the assessment, but can be extended to include the Use Phase and End-of-Life Phase. The proposed method has the capability of calculating and optimising the environmental impact of a building. Regarding low-cost housing, different housing unit designs can be compared in order to select the best alternative. The quantification method is implemented for two low-cost house design types in this study. Firstly, the conventional brick and mortar design is considered whereafter a Light Steel Frame Building is viewed as an alternative. The model implementation demonstrates that the model operates in its supposed manner. Also, Light Steel Frame Building housing units are shown to be worth investigating as an alternative to the conventional brick and mortar design but should be confirmed with a more accurate Life Cycle Assessment. / AFRIKAANSE OPSOMMING: In ’n wêreld waar toenemende ekonomiese en bevolkingsgroei veroorsaak dat al hoe meer kweekhuisgasse voortgebring word, hulpbronne uitgeput word en groter hoeveelhede rommel geproduseer word, is dit ’n bykans onbegonne taak om volhoubaarheid te probeer bereik. Volhoubaarheid rakende die natuurlike omgewing en konstruksie is twee terme wat vandag dikwels saam genoem word. Ongeveer 12.4 % van die kweekhuisgasse wat in Europa vrygestel word kom uit die konstruksie- en vervaardigingbedrywe (Maydl, 2004). Die konstruksiebedryf gebruik ook bykans die helfte van hulpbronne wat ontgin word en meer as 25 % van rommel word deur konstruksie of sloping produseer. Die Suid-Afrikaaanse boubedryf is verantwoordelik vir 23 % van die totale hoeveelheid kweekhuisgasse wat die land vrystel. Die behuisingsektor, waar die regering aan die hoof van 33 % van eenhede staan, ontvang 60 % van bestaande beleggings (Milford, 2009). Dit is dus duidelik dat die boubedryf ’n negatiewe impak op die natuurlike omgewing het en dat dit van groot belang is om dié situasie te verbeter. In die behuisingsektor het lae-koste-behuising groot potensiaal as dit kom by volhoubaarheid. Volhoubaarheid bestaan uit drie sfere: ekonomie, natuurlike omgewing en sosiaal, en al drie speel ’n betekenisvolle rol in lae-koste-behuising. Daar is reeds verskeie studies aangepak om die ekonomiese en sosiale sfere te beskryf, maar daar is steeds min inligting beskikbaar oor die omgewingsimpak van ’n lae-koste-huis. Dit laat die behoefte ontstaan om hierdie impak te kwantifiseer. Bestaande metodes wat wêreldwyd gebruik word om ʼn omgewingsimpak te bepaal is dikwels besonder kompleks en benodig duur sagteware tesame met ingewikkelde databasisse om dit te implementeer. ’n Behoefte aan ’n plaaslike kwantifiseringsmetode is geïdentifiseer. Hierdie studie stel ’n eenvoudige, gebruikersvriendelike kwantifiseringsmetode bekend. Dit word saamgestel uit faktore wat verband hou met die plaaslike omgewing: Uitlaatgasse, Hulpbronuitputting en Rommelvervaardiging. Uiteindelik word ’n saamgestelde waarde, wat die Omgewingsimpak-indeks genoem word, bereken om vergelyking te vergemaklik. Hierdie kwantifiseringsmetode word aan die hand van ’n gedeeltelike lewenssiklus-analise as ’n wiskundige hulpmiddel ontwikkel. Slegs die eerste fase van ’n gebou se lewenssiklus word beskou tydens hierdie studie, maar dit is moontlik om die ander twee fases in te sluit. Die voorgestelde metode het die vermoë om die omgewingsimpak te bereken en ook te optimeer. Tydens die ontwerpsfase, wanneer belangrike besluite geneem moet word, kan so ’n hulpmiddel van enorme waarde wees om die beste opsie uit verskillende alternatiewe te help identifiseer. Die studie beskou twee tipes behuisingseenhede vir die doel van implementering van die kwantifiseringsmetode: die konvensionele baksteen en mortel metode en alternatiewelik ’n ligte staalraamwerk-gebou. Tydens implementering van die voorgestelde metode, demonstreer die model dat dit werk soos dit veronderstel is om te funksioneer. Verder is getoon dat ’n ligte staalraamwerk-gebou ’n waardevolle alternatief is om te ondersoek, maar dit moet liefs met ’n meer akkurate lewenssiklus-analise bevestig word.

Low-cost housing

Housing

Alternative building technologies (ABT)

Eco-building

Building life cycle

Waste generation

Light steel frame building housing units

Dissertations -- Civil engineering

Theses -- Civil engineering

Rozpočet stavebního díla sestavený ve variantních strukturách / The cost estimating of the construction works assembled in variant structures

Pecen, Martin

January 2019

This diploma thesis focuses mainly on designing projects using BIM technology, specifically on the field of budgeting. In the theoretical part the current 2D project documentation and the current price system is described. Furthermore, the thesis deals with information modeling and its implementation into common building practice. At the end, it is described how to use current pricing system for budgeting in the BIM environment.

Embodied carbon and waste generation of building refurbishment : Case studies of office fit out in Sweden / Inbyggd kol och avfallsgenerering vid renovering av byggnader : Fallstudier av hyresgästanpassning i kontorsbyggnader i Sverige

Budiyani, Ansheila Gabriela

January 2023

Buildings contribute to various environmental impacts. Office fit out, as a type of refurbishment in the building life cycle, tends to recur often and is resource-intensive. Still few studies have researched the topic. Through four fit out case studies in offices in Sweden, this study investigates the impacts of office fit out by calculating the waste generation and embodied carbon of fit out. The results show that the waste generation and embodied carbon for each case study projects was 31-38 kg/m2 refurbished GFA and 93-96 kg CO2e/m2 refurbished GFA. Over time, the accumulated recurring embodied carbon of fit out can surpass the initial embodied carbon of the building when no improvement for embodied carbon reductions is made. Scenarios modelling explores how prolonging fit out recurrency and incorporating circular methods to the practice could reduce the accumulation of embodied carbon of fit out. According to the results, recommendations for the actors involved are proposed and methodological reflections are presented. This study provides an overview and initial understanding of the impacts of fit out from real-life cases to help identify what can be done to reduce environmental impacts. / Byggnader bidrar till olika typer av miljöpåverkan. Hyresgästanpassning i kontorsbyggnader är en typ av renovering under en byggnads livscykel som tenderar att upprepas många gånger och är resurskrävande. Trots det är det få studier som än så länge har undersökt ämnet. Genom fyra fallstudier av hyresgästanpassningsprojekt i kontorsbyggnader i Sverige studeras effekterna av hyresgästanpassning genom att beräkna generering av avfall och inbyggd klimatpåverkan (eng. embodied carbon). Resultaten visar att för de fyra fallstudierna genereras avfall i omfattningen 31-38 kg/m2 renoverad BTA och inbyggd klimatpåverkan i omfattningen 93-96 kg CO2e/m2 renoverad BTA. Över tid kan den ackumulerade inbyggda klimatpåverkan av återkommande hyresgästanpassningsprojekt överskrida byggnadens initiala inbyggda klimatpåverkan när inga strategier för att minska inbyggd klimatpåverkan tillämpas i projekten. Modellering av ett antal scenarier undersökte hur en lägre frekvens av återkommande hyresgästanpassningsprojekt och införlivning av cirkulära strategier kan minska ackumuleringen av inbyggd klimatpåverkan över byggnadens livscykel. Baserat på studiens resultat föreslås rekommendationer till berörda aktörer och reflektioner som rör beräkningsmetoden presenteras. Den här studien ger en översiktlig förståelse av klimatpåverkan av hyresgästanpassning i kontorsbyggnader från verkliga fallstudier, vilket kan bidra med att identifiera vad som kan göras för att minska miljöpåverkan.

Fit out

office

refurbishment

waste generation

embodied carbon

building life cycle

hyresgästanpassning

kontorsbyggnader

renovering

avfallsgenerering

inbyggd klimatpåverkan

byggnadens livscykel

Engineering and Technology

Teknik och teknologier

Analýza nákladů stavebního objektu / Cost Analysis of a building

Polanský, Dan

January 2018

The diploma thesis purpose is to choose optimal structure of the modernisation of slab block flat roof, according to building life cycle coast minimalisation. Based on the theoretical knowledge, the design of the stack was made in different phases and based on the building life cycle cost, considering the decreasing value of money over time. The selection of the optimal solution followed, taking account the specific conditions of the given scope of realization and the specific object. The choice is justified by the related analysis of key items.

Pokročilé uplatnění BIM při návrhu stavebních objektů / Advanced use of BIM in building design

Nováček, Michal

January 2019

This thesis deals with a Building Information Model (BIM) and its advanced use in construction practice. It focuses on the usage of BIM model in the determination of pressure drop in ventilation pipelines. An application able to calculate the pressure drop in a pipeline branch based on the geometrical parameters of the BIMs of structures was created within the work.