Integration of Natural and Artificial Light on Energy Efficiency of  the Mega Bank Makassar Tower Building

One of the largest energy consumers in the world is buildings. The energy consumption comes from the lighting system. Energy use in buildings is generally 25% for lighting systems. The strategy used in building design is to reduce energy consumption while maintaining the best comfort in a building. The application of energy-saving concepts from the building sector is optimizing the lighting system by integrating natural and artificial lighting systems. This study aims to determine the light intensity in the integrated lighting system of natural and artificial manually and also to find out how much energy can be saved with the integrated lighting system manually. The research location is at the Mega Bank Makassar Tower Building. The research sample was selected by purposive sampling and the sixth floor was chosen as the research location. In this study, simulations were carried out using the DIAlux 4.13 program to integrate natural and artificial light and to calculate the amount of energy efficiency in the workspace. To obtain optimal light intensity and energy savings, a simulation was carried out by turning off half the light points in the workspace, especially the light points around the building openings. The simulation results show that the average integrated lighting quality meets the minimum lighting requirements and can save energy usage by up to 50%. Keywords: energy efficiency; integration lighting; workspace

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ENERGY RETROFITS FOR IMPROVING ENERGY EFFICIENCY IN BUILDINGS: A REVIEW OF HVAC AND LIGHTING SYSTEMS

10.31705/wcs.2021.25 ◽

2021 ◽

Author(s):

M.R. Amjath ◽

◽

H. Chandanie ◽

S.D.I.A. Amarasinghe ◽

◽

...

Keyword(s):

Energy Efficiency ◽

Energy Consumption ◽

Energy Use ◽

Implementation Process ◽

Energy Performance ◽

Existing Buildings ◽

Energy Auditing ◽

Lighting Systems ◽

Effective Decision Making ◽

And Performance

It has been observed that inefficient buildings consume three to five times more energy than efficient buildings. Subsequently, improving the Energy Efficiency (EE) of existing buildings, which account for a significant portion of the energy consumption of the building sector, has become a top priority. Also, Heating, Ventilation, and Air Conditioning (HVAC) and lighting systems typically account for three-quarters of a building's energy consumption. Hence, focus on the energy efficiency improvements associated with these subsystems is entailed to optimise the energy use of buildings in comparison to other energy consumers. Energy Retrofit (ER) is defined as the main approach in improving the energy efficiency of buildings to achieve energy reduction goals. Nevertheless, there is a general lack of awareness regarding ER. Thus, the purpose of this article is to bridge this research gap by critically reviewing the applicable literature on ER. The paper first analysed the role of retrofits in buildings concerning optimising energy performance. The paper also discusses the implementation process of ER, which includes five steps viz. pre-retrofit survey, energy auditing, and performance assessment, identification of suitable and feasible retrofit options, site implementation and commissioning, and validation and verification. Further, different types of ER applicable to HVAC and lighting systems are discussed. In their endeavor to enhance the EE of existing buildings, practitioners could apply the findings of this study, as a basis to understand the available ER types and as a measure to gauge the efficiency of existing buildings, which will facilitate effective decision-making.

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Long-Term Assessment Methodology of Building Stock Thermal Energy Consumption

10.7250/9789934226205 ◽

2021 ◽

Author(s):

◽

Aleksejs Prozuments

Keyword(s):

Energy Efficiency ◽

Energy Consumption ◽

Thermal Energy ◽

Energy Use ◽

Energy Savings ◽

Building Code ◽

Space Heating ◽

Industrial Building ◽

Building Stock

Energy efficiency in the building stock is a substantial contributor to infrastructure sustainability. In Latvia, buildings’ thermal energy use for space heating accounts for 80 % of total building energy use in the cold season. Therefore, reducing thermal energy consumption for space heating needs through the implementation of energy efficiency measures, enforcement of local building codes and regulations can ultimately lead to cost savings for building owners and stakeholders. The present PhD Thesis introduces a methodology for evaluation of thermal energy saving potential in the long run across residential, public, and industrial building stock under various thermal energy consumption compliance scenarios. These scenarios were developed based on three different building code protocols with a 10-year forecast analysis. Evaluation of the proposed building code implementation practices and their feasibility in Latvian building stock is discussed for these buildings with regards to their long-term thermal energy savings potential.

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A comparative meta-analysis of residential green building policies and their impact on overall energy consumption patterns

10.47890/jadct/2020/njabbour/10123453 ◽

2020 ◽

Vol 1 (1) ◽

Author(s):

Naim Jabbour

Keyword(s):

Energy Efficiency ◽

Energy Consumption ◽

Energy Use ◽

Energy Savings ◽

Residential Building ◽

Green Building ◽

Energy Performance ◽

Residential Energy ◽

Residential Energy Consumption ◽

The Eu

Data shows residential energy consumption constituting a significant portion of the overall energy end use in the European Union (EU), ranging between 15% and 30%. Furthermore, the EU’s dependency on foreign fossil fuel-based energy imports has been steadily increasing since 1993, constituting approximately 60% of its primary energy. This paper provides an analytical re-view of diverse residential building/energy policies in targeted EU countries, to shed insight on the impact of such policies and measures on energy use and efficiency trends. Accordingly, the adoption of robust residential green and energy efficient building policies in the EU has increased in the past decade. Moreover, data from EU energy efficiency and consumption databases attributes 44% of total energy savings since 2000 to energy upgrades and improvements within the residential sector. Consequently, many EU countries and organizations are continuously evaluating residential building energy consumption patterns to increase the sec-tor’s overall energy performance. To that end, energy efficiency gains in EU households were measured at 1% in 2000 compared to 27.8% in 2016, a 2600% increase. Accordingly, 36 policies have been implemented successfully since 1991 across the EU targeting improvements in residential energy efficiency and reductions in energy use. Moreover, the adoption of National Energy Efficiency Actions Plans (NEEACP) across the EU have been a major driver of energy savings and energy efficiency. Most energy efficiency plans have followed a holistic multi-dimensional approach targeting the following areas, legislative actions, financial incentives, fiscal tax exemptions, and public education and awareness programs and campaigns. These measures and policy instruments have cumulatively generated significant energy savings and measurable improvements in energy performance across the EU since their inception. As a result, EU residential energy consumption trends show a consistent decrease over the past decade. The purpose of this analysis is to explore, examine, and compare the various green building and energy-related policies in the EU, highlighting some of the more robust and progressive aspects of such policies. The paper will also analyze the multiple policies and guidelines across targeted European nations. Lastly, the study will assess the status of green residential building policies in Lebanon, drawing from the comprehensive European measures, in order to recommend a comprehensive set of guidelines to advance energy policies and building practices in the country. Keywords: Building Policies; Residential Energy Patterns; Residential Energy Consumption; Energy Savings

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Improving Energy Efficiency on SDN Control-Plane Using Multi-Core Controllers

Energies ◽

10.3390/en14113161 ◽

2021 ◽

Vol 14 (11) ◽

pp. 3161

Author(s):

Tadeu F. Oliveira ◽

Samuel Xavier-de-Souza ◽

Luiz F. Silveira

Keyword(s):

Energy Efficiency ◽

Energy Consumption ◽

Energy Use ◽

Data Centers ◽

Parallel Implementation ◽

Multicore Processors ◽

Control Plane ◽

Processing Power ◽

Save Energy ◽

The Many

Software-defined networks have become more common in data centers. The programmability of these networks is a great feature that allows innovation to be deployed fast, following the increasing number of new applications. This growth comes with a cost of more processing power and energy consumption. Many researchers have tackled this issue using existing routing techniques to dynamically adjust the network forwarding plane to save energy. On the control-plane, researchers have found algorithms for positioning the controller in a way to reduce the number of used links, thus reducing energy. These strategies reduce energy consumption at the expense of processing power of the controllers. This paper proposes a novel approach to energy efficiency focused on the network’s control-plane, which is complementary to the many already existing data-plane solutions. It takes advantage of the parallel processing capabilities of modern off-the-shelf multicore processors to split the many tasks of the controller among the cores. By dividing the tasks among homogeneous cores, one can lower the frequency of operations, lowering the overall energy consumption while keeping the same quality of service level. We show that a multicore controller can use an off-the-shelf multicore processor to save energy while keeping the level of service. We performed experiments based on standard network measures, namely latency and throughput, and standard energy efficiency metrics for data centers such as the Communication Network Energy Efficiency (CNEE) metric. Higher energy efficiency is achieved by a parallel implementation of the controller and lowering each core’s frequency of operation. In our experiments, we achieved a drop of 28% on processor energy use for a constant throughput scenario when comparing with the single-core approach.

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Revision of Smart Street Lighting LED

Ingeniería solidaria ◽

10.16925/2357-6014.2019.02.09 ◽

2019 ◽

Vol 15 (28) ◽

Author(s):

Diego Julián Rodríguez Patarroyo ◽

Iván Felipe Cely Garzón ◽

Cristhian Alexander Letrado Forero

Keyword(s):

Energy Efficiency ◽

Energy Use ◽

Light Emitting Diode ◽

Lighting System ◽

Street Lighting ◽

Light Emitting ◽

The World ◽

Current Context ◽

Lighting Systems ◽

And Performance

Introduction: This Literature Review article is the result of a research on the current situation of smart public lighting systems with light-emitting diode (LED) technology in cities around the world. Problem: How convenient is it to use smart public lighting system with LED luminaires? Objective: To review the context of smart public lighting with LED technology. Methodology: Within this project, a lit review was conducted with more than 50 academic articles found in different databases such as: IEEE Xplore, Scopus, ScienceDirect etc. The selection criteria of the information followed the revision of articles from 2006 to 2018, and also, took into account their installation and performance in different cities and places of the world. Furthermore, articles on polluting and inefficient technologies were excluded. Conclusion: Considering the current context in which LED smart public lighting is, it is more likely to be implemented in the future. Results: Smart LED street lighting systems are more efficient in energy use, leads to savings in costs in medium terms, and finally, present a lower environmental impact compared to conventional lighting systems. Limitations: The review focuses on energy efficiency and economic aspects, not on social aspects. Originality: Smart LED public lighting systems have been researched within the economic and energy efficiency context.

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Improving energy efficiency in Vietnamese tube houses

Smart and Sustainable Built Environment ◽

10.1108/sasbe-01-2018-0002 ◽

2019 ◽

Vol 8 (5) ◽

pp. 366-390 ◽

Cited By ~ 1

Author(s):

Phan Anh Nguyen ◽

Regina Bokel ◽

Andy van den Dobbelsteen

Keyword(s):

Energy Efficiency ◽

Energy Consumption ◽

Indoor Environment ◽

Energy Use ◽

Housing Stock ◽

Building Design ◽

Energy Performance ◽

Building Envelope ◽

Content Type ◽

Actual Energy Consumption

Purpose Refurbishing houses is considered a key measure to improve the energy efficiency of the built environment. However, little is known about the implementation and outcome of housing renovation for energy upgrades in the Vietnamese practice. The purpose of this paper is to investigate the energy performance of the current housing stock in Vietnam and the potential to reduce energy use in households. Design/methodology/approach The paper is based on a survey with 153 respondents in three major climatic regions of Vietnam. The survey focusses on building characteristics, environmental performance, energy performance and refurbishment activities. Data collected from the survey were statistically analysed to give insight into the current performance of the housing stock and its energy saving potential. Findings This paper concludes that building design and construction, particularly the building envelope, have a significant influence on the occupants’ comfort. However, the energy consumption in houses is not statistically associated with building design and indoor environment. It is suggested that financial status and occupants’ behaviour currently have a strong influence on the household energy use. The survey also showed that refurbishment improves the housing performance, especially if improving the indoor environment was one of the drivers. Originality/value There are very few studies on energy use in households in Vietnam, especially with regards to actual energy consumption. This paper brings insights into the actual energy consumption and reveals the “performance gap” in Vietnamese housing stock.

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A Multi-Period Approach for the Optimal Energy Retrofit Planning of Street Lighting Systems

Applied Sciences ◽

10.3390/app9051025 ◽

2019 ◽

Vol 9 (5) ◽

pp. 1025 ◽

Cited By ~ 2

Author(s):

Raffaele Carli ◽

Mariagrazia Dotoli ◽

Roberta Pellegrino

Keyword(s):

Decision Making ◽

Energy Efficiency ◽

Energy Savings ◽

Lighting System ◽

Financial Benefit ◽

Street Lighting ◽

Single Period ◽

Lighting Energy ◽

Lighting Systems ◽

The City

Investing in the optimal measures for improving the energy efficiency of urban street lighting systems has become strategic for the economic, technological and social development of cities. The decision-making process for the selection of the optimal set of interventions is not so straightforward. Several criticalities-such as difficulties getting access to credit for companies involved in street lighting systems refurbishment, budget constraints of municipalities, and unawareness of the actual energy and economic performance after a retrofitting intervention-require a decision-making approach that supports the city energy manager in selecting the optimal street lighting energy efficiency retrofitting solution while looking not only based on the available budget, but also based on the future savings in energy expenditures. In this context, the purpose of our research is to develop an effective decision-making model supporting the optimal multi-period planning of the street lighting energy efficiency retrofitting, which proves to be more effective and beneficial than the classical single-period approach and has never before been applied to the considered public lighting system context. The proposed methodology is applied to a real street lighting system in the city of Bari, Italy, showing the energy savings and financial benefit obtained through the proposed method. Numerical experiments are used to investigate and quantify the effects of using a multi-period planning approach instead of a single-period approach.

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ANALYSIS OF RESULTS OF MEASURES PERFORMED TO INCREASE ENERGY EFFICIENCY IN VASIL KARAGIOZOV HIGH SCHOOL OF YAMBOL, BULGARIA

Applied Researches in Technics Technologies and Education ◽

10.15547/artte.2018.04.004 ◽

2018 ◽

Vol 6 (4) ◽

pp. 306-310 ◽

Cited By ~ 1

Author(s):

Ivan Binev

Keyword(s):

High School ◽

Energy Efficiency ◽

Energy Consumption ◽

Energy Saving ◽

Energy Use ◽

Energy Savings ◽

Climatic Conditions ◽

Improve Energy Efficiency ◽

Before And After ◽

The Impact

The report analyzes the results of the implemented measures to improve energy efficiency in Vasil Karagiozov High school of Yambol, Bulgaria. Energy savings are determined by measuring and/or calculating energy consumption with previously adopted baseline levels, implementing a measure or program to improve energy efficiency by providing normalized corrections corresponding to the impact of specific climatic conditions on energy use. A reference heating energy consumption of 38.62 kWh/m2 was determined after the renovation of the building. Comparing the reference energy costs for heating before and after the implementation of the energy saving measures show a real decrease of the energy consumption for heating by 53.44%. Compared to the reference energy consumption for heating before and after the energy saving measures show an actual reduction of energy consumption for heating by 47.86%.

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Feasibility Study and Impact of Daylight on Illumination Control for Energy-Saving Lighting Systems

Sustainability ◽

10.3390/su10114075 ◽

2018 ◽

Vol 10 (11) ◽

pp. 4075 ◽

Cited By ~ 4

Author(s):

Sulee Bunjongjit ◽

Atthapol Ngaopitakkul

Keyword(s):

Energy Efficiency ◽

Energy Consumption ◽

Energy Saving ◽

Control Unit ◽

Experimental Result ◽

Lighting System ◽

Standard Case ◽

Lighting Control ◽

Lecture Room ◽

Lighting Systems

The main goal of energy conservation should be reducing the consumption of energy resources. Due to energy and environmental concerns in recent years, to reduce energy consumption in a lighting system, which has been one of the prime targets of energy saving, daylighting has been investigated and has become one of the energy-efficiency techniques widely applied in buildings. This paper presents an analysis of T5 fluorescent luminaire lighting control using daylight in a building. The study is conducted in two parts; simulation of a lecture room using the daylighting function of the DIALux program is performed to estimate the effect of daylighting on a task area (workplane). Another part is an experimental setup to evaluate the performance of a lighting control unit that is installed for a T5 fluorescent luminaire with a dimmable electronic ballast. The efficiency of the lighting control in term of illumination on the task area and energy consumption are also evaluated and compared with the standard case. The simulation results show that daylighting increases illuminance on a task area, especially on the window side, so the lighting system can significantly reduce its power consumption compared with a standard case (without lighting control). The experimental result shows that upon installing the lighting control with daylighting, both the average illuminance and the energy consumption in each time period are decreased compared with in the standard case. Lighting control with daylighting tries to set the average illuminance on a task area to less than 500 lux, corresponding to the amount of daylight passing through window shutters. The obtained results are useful for the design of a T5 fluorescent luminaire with lighting control using daylighting in a building lighting system for energy efficiency and reducing energy consumption, including the average illuminance on the task area, according to a relevant standard.

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Energy use in Canada: environmental impacts and opportunities in relationship to infrastructure systems

Canadian Journal of Civil Engineering ◽

10.1139/l04-100 ◽

2005 ◽

Vol 32 (1) ◽

pp. 1-15 ◽

Cited By ~ 51

Author(s):

John Cuddihy ◽

Christopher Kennedy ◽

Philip Byer

Keyword(s):

Waste Water ◽

Energy Consumption ◽

Environmental Impacts ◽

Urban Form ◽

Alternative Energy ◽

Energy Use ◽

Energy Savings ◽

Building Design ◽

Petroleum Products ◽

Per Capita

Canada exhibits high per capita energy consumption. This paper examines energy use in Canada by region and sector, focusing on four sectors most relevant to civil engineering activities: residential, commercial–institutional, construction, and transportation. Environmental impacts associated with major energy sources including coal, petroleum products, natural gas and electricity are reviewed. The relationships between energy consumption and infrastructure design are analysed. Opportunities for reductions are identified in building design, water and waste-water systems, urban form, and transportation. Large improvements in commercial and residential energy efficiency can be achieved through the implementation of existing technologies in building upgrades, retrofits, and rebuilds. Increasing surface albedos and more extensive use of vegetative shading and consideration of the geometric properties of urban canyons and their microclimatic effects also allow for considerable energy savings. The incorporation of mixed-modal transit, walking and cycling paths, and community-scale design as elements of long-term transportation planning and the development of alternative transportation technologies have the potential to considerably reduce per capita energy use. The development and implementation of alternative energy supply technologies include energy recovery from waste-water treatment.Key words: energy, infrastructure, urban, sustainability, sustainable development.

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