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Investigating the role of narcissism in the tendency to doping in bodybuilding athletes

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In this paper, a new propagation model based on UTD for multiple diffraction paths in cellular mobile radio communications in urban environments is proposed. Moreover, the most rigorous novel UTD-based expressions for multiple diffractions by buildings and excess path losses are d - rived and analyzed. For this purpose, building rows are supposed to have rectangular cross-sections with the same heights and spacings. In addition, in this analysis actual electrical roperties of buildings are regarded. Previous studies have been concentrated on the simplified models that approximated building rows as absorbing half-screens or perfectly conducting half screens (knife-edges) or 90 degrees wedges. In this work, buildings are assumed flat-roofed parallel rows of dielectric blocks and their actual relative permittivity and conductivity are applied.

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Urbanization and population growth in metropolitan areas, on the one hand, and the growth of large-scale industrial activities, on the other hand, have led to changes in the climate of urban areas.This research is based on the classification of types of research in the category of descriptive and explanatory studies. Based on the results in the category of applied studies. It is based on qualitative and quantitative research processes. The research method is a combination of descriptive-analytical methods and software simulation with software Envi-Met software. Data is quantitative and qualitative related to the quality of space. Implementing it includes conceptual and theoretical modeling, software modeling, change in the type and amount of variables and testing the software model to find optimal answers. For this purpose, a basic model based on common urban forms in Tehran is selected and in which indicators such as the location of building blocks, orientation, the distance between blocks, the height of blocks in Envi-Met software are modeled and based on the index of thermal comfort and degree. PMV temperature was evaluated. According to the software outputs, it can be concluded that the location, distance, orientation and height have a positive effect on reducing thermal islands and providing thermal comfort conditions

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Problem statement: Due to the increase in population and lack of land to provide services to city dwellers, high-rise architecture became popular, but most of these high-rise buildings were built without regard to citizens' perceptions, which created problems in this regard.
Aim: The purpose of this study is assess the impact of tall buildings on residents' perceptions in the central context Tabriz from a physical-semantic perspective.                                                                   Methods: The present study is descriptive-analytical survey. The statistical population included the population of the central part of Tabriz equal to 29384 people and the sample size was obtained through Cochran's formula equal to 379 people. Structural equation method through Smart PLS and Amos software was used to analyze the data.                                                                                                                                                 Results: The results showed that among the components of the impact of tall buildings on the perception of residents of the central part of Tabriz, the component of desirability of using high-rise buildings for residential use with a factor load of 0.951 has the greatest impact on residents' perception (physical-semantic) It has the central texture Tabriz and its lowest is related to the component of feeling happy in the face of high-rise buildings with a factor load of 0.615.                                                                                                Conclusion: The design of tall buildings should be designed with full knowledge of the needs and desires of the residents of the central part Tabriz, because they are real consumers and their understanding of their living environment and facilities provided a very important role in their satisfaction and comfort. It has a living environment.
 

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Presently, energy suppliment is considered as a pivotal economic and political characteristic in government; so that, an increasing trend in energy price appears in countries namely Iran due to energy resources limitation and increasing costs in extraction and exploitation. Therefore, parallel to efforts made to tackle the energy upgrading costs and lackness, improving energy efficiency and conservation in buildings are considered as main solutions to address the problem. Addition to applying thermal insulation in buildings, it is extremely significant to emplement energy-efficient strategies and approaches to decrease energy transfer rate in construction sector. Undoubtedly, following approaches positively influence buildings energy balance over a year. Directly influenced by climatic condition, building elements specifically, roofs, play an important role in heat transfer rate in a structure There are thermal exchange between roof and ambient temperature including: 1) Heating ignorence 2) Heating absorption 3) and finally solar reflectance). Furthermore, roof coverings compose a large area of buildings envelope; accordingly, it has a major impact on energy consumption and thermal comfort even considering construction roofs area in urban scale. Regarding to previous research experiences, there is a large scope of data on buildings envelope details to level down energy consumption; however, less studies are devoted to building elements shape to formally analyze energy consuming. The following paper develops the studies on roofs shape thermal behavior based on building heating load; while it uses a computerized simulation methodology as an alternative to field-based research. The simulation weather date is based on Isfahan city, in Iran. Modeled and analysed four roof covering types (flat roof, domed roof, pitched roof (30°-60°), pitched roof 45°), the final result shows that however the flat shape roof appears in an appropriate thermal performance, (30°-60°) pitched covering (mostly faced to the south in terms of surface) is regarded as the most energy-effecient form in Isfahan hot and dry climate area while domed shape roof appears in mostly inefficient sample to apply as covering in the area owing to most surface area. Moreover, the graphs show that applying thermal insulation as a layer in different roof shapes, remarkably decreases heating load over a montly simulation.

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Background: Today the facade of newly constructed buildings is an important issue in the urban context, particularly the historic context, which determines the presence of building within the urban landscape of a district as the last step of construction operations of each building. Existing criteria and instructions for facade design of new buildings in urban-historic districts have been developed based on a variety of components, e.g. historic patterns and vernacular materials, as a guideline and framework for owners and designers; so that the facades can be appropriate and consistent with the historic context and buildings of the district and also in harmony with each other. Despite the attempts to meet the targets, a broad variety of newly constructed facades can be observed now throughout the historic areas of the city, which may range widely in terms of harmony with each other and consistency with the context.
Aims: Given the issue explained above, this article aims to detect the weaknesses and drawbacks resulted from the failure to meet the objectives of the instructions on façade design of new buildings in the historic area of Tabriz; hence the existing guidelines on façade design in the historic area of Tabriz are analyzed to investigate the dimensions of their feasibility for newly constructed residential buildings. The objective is met through multidimensional attention to the facades of new buildings.
Methods: In this article, the implementation process is thus qualitative and the data is collected through a descriptive-analytical method based on scientific references and field research.
Findings: The investigations on newly constructed residential buildings in the historic area of Tabriz reflect two major types of failure (i.e. theoretical and practical) in regard to the feasibility of façade design instructions.
Conclusion: Therefore, corrective measures and revisions are required theoretically in addition to the actions necessary for implementation of façade design instructions.

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Objectives: Today, the expansion of urbanization is associated with the disappearance of human activities in the space between buildings. The purpose of this research is to understand the dimensions of the connection between buildings and the city and how it is captured by the dispositive, and finally to find a way to emancipate in the form of an immanent connection.
 Method: The research is done by a qualitative method. The research paradigm is emancipation, the strategy is discourse analysis and the tactics are data collection, coding, analysis, display, explanation, and profanation.
Result : The findings indicate that the building and the city connection factors are related to each other through a hidden network in the form of three scales: the large scale includes semantic factors, the medium scale social factors, and the small scale include formal and functional-behavioral aspects. Therefore, social institutions on a medium scale, will be captured by the dispositive after constituting as they have a specific form and function, and will lose their relationship with the large scale and exist officially in the form of a formal institution, which ultimately leads increasing control and power, and further disintegration.
Conclusion: To achieve an immanent connection between the building and the city, the official institution should be disabled to reconnect the semantic scale for redefining the social institution. Also, it should be profane from whatever dispositive has been placed on the concept of institution. This is realized by the presence of non-institution in the space between the buildings

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Aims: How to design spaces in cities can have different effects on citizens. The objectives of this study can be to examine the impact of biophilic urban space on the stress of people.
Methods: The research method is quasi-experimental. The statistical population of the study consists of 20 bachelor and master students in the field of architecture and urban planning at Tabriz University of Islamic Arts in the academic year 1400. First, students' health was identified using a call announcement and a demographic questionnaire, and these individuals were quantified for stress with the help of a smart wristband while viewing images of biophilic and non-biophilic urban spaces with the help of virtual reality glasses.
Findings: Analysis of the results shows that the average change in stress of individuals while viewing non-biophilic images was approximately 2/5 units higher than biophilic ones in the second minute. p-Value is significant between individuals with education in biophilic state and rest in 1 minute and non-biophilic in 2 minutes. The difference between stress number in non-biophilic state and biophilic in 2 minutes is significant (p-value = 023/0) and shows the positive effect of biophilic approach on reducing stress that this efficiency can be considered in the design of future urban spaces.
Conclusion: Special attention of urban designers on the structure of spaces and the use of extraction measures from the biophilic model in different scales cause the design or organization of spaces that significantly reduce the stress of people living in cities.

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The building sector is responsible for one-third of global final energy consumption and thus environmental damage, carbon dioxide production. Some reasons for ever increasing building energy consumption : climate change, increase in household electricity load , the growth of real estate, fast-growing household electrical appliances, changes in industrial structure, huge energy consumption of the existing buildings, and the lack of strict government supervision. The world's total energy requirements are mostly used in sectors such as transportation, industry, residence, commerce, etc.. Although most of the energy consumption during the period 1973 to 2009 belonged to the industrial sector, it can be said that the proportion of residential buildings is very high and is increasing rapidly.. World Statistics published by the Department of Energy, United States of America in March 2010 shows that most houses widely use energy for heating and hot water and then cooling and lighting. Therefore, the revision of quality architectural design of buildings, based on the climatic principles , will be very effective in optimizing fuel consumption so that the energy consumption can be controlled wisely and optimally. On the other hand the use of renewable energy technologies can provide energy surplus of buildings and eliminate the problems associated with fossil energy in great extent.Adopting conservation measures on a large scale does allow reducing both electricity and total energy demand from present day levels while the building stock keeps growing. They simulate climate-dependent hourly building energy demands at user-defined scales, typically an individual state or utility zone. Due to the effective role of energy in economic development and its increasing consumption in parallel with the growth of human communities , considering resource constraints and preventing from facing with an energy crisis, the need for conservation through management application is necessary which demands new strategies and approaches in both environmental and architectural revisions for design and building. In particular, the high energy consumption especially in buildings is a major problem in developing countries which has economic and environmental impacts of prime importance while it is considered to be the most significant cornerstone of growth in different dimensions. Buildings , it is statistically shown, account for a third of total global energy consumption. Energy consumption in buildings is increasing due to several factors including climate change, increasing electrical energy consumption in households, real estate development, diversity of modern appliances, changes in industry structure, very high energy consumption in existing buildings and the lack of adequate supervision of the state.. Therefore, efforts must be focused on the control and management of energy consumption . The purpose of energy management is reducing energy consumption in a way that is logical and economical and can cause no negative effects on welfare and thermal comfort. So, a focus for building energy consumption efforts is of great importance. The occupant behavior and building manner can both increase the building energy consumption, especially residential ones.In the building quality part, there are many techniques affects on building energy consumption, which divide to passive and active. The passive ones are the techniques that related to the body and design of a building as material, utilization of solar radiation on the bodies, length and width of building, insulation, window, and so on without electrical or other energy portfolio, but the effect of these parameters was not equal. Therefore, this study presents an approach to determine the effect of main parameters of some of the building techniques on energy consumption. In this study, these parameters were identified and evaluated and finally were Prioritized. Not all of the parameters has equal role on energy consumption, which the mentioned weights indicated. The remainder of the paper organized as follows. Firstly, the parameters were identified by research and interview. The effective parameters recognized as the alternatives of the mentioned hierarchy3 step trees, which can be listed as follows: occupants; built area; Step No.; Proximity degree; Window to wall ratio; Length to width ratio; Side. Secondary, the questionnaire performed and completed by experts as architects, mechanical engineers and energy engineers. Analytic hierarchy process (AHP) and its applications in surveys related to buildings were presented. Up to now, the AHP method has been widely applied in the general policymaking in buildings. Next, the effective parameters on energy consumption evaluated, and in next section the AHP for the approach concernedexplained and resultsoffered. Finally, the last Section includes the concluding remarks. The weights and priorities of the effective parameter are illustrated. As a result, considering weight of factors in building designing process, the different parameters of BO can be classified and evaluated: First, the main effective parameter is window to wall ratio. Depends on the weight of this parameter (0.36), the window area and materials are important for building designers. Another main parameter is side no., if a building has 1 or 2 or 3 or 4 side, its energy consumption differs fundamentally. Choosing the main direction, side and the side no. are all associated. One of the main results is about the building area depending on energy consumption, which considers having the main role, but in present survey concluded that the third effective parameter is area. The least effective parameter is occupant number, due to energy load of building space and quality, not building occupant. Urban designers and Architects considering Building Orientation (BO) and its parameters can design buildings that are energy efficient. If building orientation )BO( is considered, solar radiation absorbed by the surface structure of the building will become more favorable, and consequently the energy consumption will be reduced. However, if the building orientation (BO) is considered along with climatic factors, there will be direct effect of increased energy costs. In addition , urban designers must greatly pay attention to building sides while determining the building blocks as the transmitting surfaces are from outdoor to indoor in summer and vice versa in winter. Architects must also pay attention to different ratios of windows to create the proper ratio of heat transfer in the buildings. The materials used in the buildings are of great importance.

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The increase in energy consumption within modern societies in addition to expiration of fossil resources are two vital factors which compel the world to alter dangerously, while construction industry around the world consumes 25%-40% of energy in different countries. Above all postindustrial era causes the increase in number of employees as well as bureaus. As a result, the amount of energy consumption and also the quality of indoor offices has always been one of the main concerns of architects. Several studies represent that the thermal discomfort is the most common complaint in offices. The thermal aspect of indoor buildings, not only provides comfort for the residents, but also brings saving in energy, health, productivity, and also a significant morale improvement of the staff. Since most complaints of indoor environment are caused by failure in providing the adequate thermal comfort, researches concentrated on several offices around the world suggest that indoor quality of such buildings is about average; in which many are dissatisfied about their workplace and while many are suffering from building-related illnesses that negatively affect the productivity, duration of working and having economic consequences for those countries. The requisite of thermal comfort within the indoor environment is the existence of thermal comfort standards. These standards define indoor thermal comfort zone according to the physical and personal indexes. The most important international standards are ISO7730 and ASHRAE 55. Nowadays, various models are introduced for appraising thermal comfort within different standards of thermal comfort. According to ASHRAE Standard 55 (2010) thermal comfort is defined as "condition of mind that expresses satisfaction with the thermal environment". Therefore thermal comfort contains different physical and psychological aspects, which means several factors are in effect for this purpose. Thermal comfort is related to four controllable factors namely air temperature, radiant temperature, air speed and as well as humidity. thermal comfort also is influenced by three additional factors: activity, clothing and personal expectations. As mentioned above, there are several standards for thermal comfort in the world. The most important ones are international standards ASHRAE 55 (North America) and ISO 7730 (Europe). These standards congruous the theoretical analysis of heat exchange of the human body and gathering information regarding the climate chamber. These standards are appropriate for stationary and homogeneous conditions which are not suitable and hence not much used in the real world. This fact is evident by the disparity between the predicted thermal comfort by these standards and the real sense of human comfort in different places. These standards specify comfort zones in which a large percentage of people perceive the environment thermally acceptable by certain personal criteria. According to these standards, acceptable thermal zone is defined based on satisfaction of at least 80% of the occupants. In other words, performing within the provided criterion of this standard does not mean the 100% satisfaction, as if it is difficult to satisfy everybody due to personal differences. It is to be mentioned that personal control of thermal environment or personal compatibility (by clothing or activity) also increases the satisfaction level. Considering the complexities of defining thermal comfort, several models are represented which are allied to the physical and psychological parameters as the physiological ones. Two forthcoming models are available for appraisal of thermal comfort: PMV model; which explains individuals' response to the thermal comfort in the physiology of the heat transfer. This model evaluates the indoor environments and constitutes the current thermal comfort standards. According to the aforementioned standards, environmental thermal conditions must be maintained homogeneously. Therefore, PMV model is not appropriate for appraising inert thermal sense in places like residential buildings which are not thermally homogeneous and have different thermal zones. However regarding several capacities of this model, many studies have been accomplished in order to adjust this model for such buildings by implementing some changes. The other model named 'adaptive' explains individuals' response to the thermal comfort considering behavioral, psychological and physiological aspects. The thermal comfort standards define the thermal environment conditions of residents based on data obtained by climate chamber experiments. Therefore, consequently, there are problems for using these standards and also thermal comfort models for those who are living in different climates. That is to say regions with different climatic conditions may need different levels of satisfaction parameters through these standards. In other words, due to different climates, cultures, and etc.,the thermal satisfaction conditions differ in different places. Hence, many countries all over the world have conducted field studies to introduce the most favorable thermal conditions that fit their location best. The lack of essential standards for determination of thermal satisfaction limits in office buildings in Iran, results in employees’ thermal dissatisfaction and overall performance reduction. This study uses field methods for measuring environmental variables (temperature and humidity) and also leading inventory (n=328). Kermanshah city is chosen as a case study. Since this city lacks a dominant type of office buildings and the only common aspect of such buildings is indoor offices, thus this feature is considered to choose the samples. To develop the questionnaire, that of ASHRAE 55 (2010) is used, however according to type of the research and the questions cover, some related questions are added. Moreover, answers are adjusted in seven scales in order to be analyzable using available scales of thermal comfort standards such as 7-point scale of ASHRAE. According to results, 81.7% of whole 328 respondents and 65.5% are satisfiedwithtemperature and humidity respectively. Adapting these results to ASHRAE 55, it is concluded that most staff are satisfied in their work place however the results are the opposite about the humidity. To determine suitable range of temperature and relative humidity in order to define comfort zone in offices in Kermanshah, measured data using FLUKE AIR METER are opposed to the results about temperature and humidity (questionnaire). Data analysis using SPSS represents that neutral temperature range through offices in this city is 20-26 centigrade and low relative humidity is about 19%.

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Allegory represents a type of thinking and world view as well as a style of speech in Molavi’s works, Masnavi in particular. In Molalvi’s “allegoric philosophy”, what makes necessary the use of this approach – as the principal narrative style of the tales – is the necessity to carry ideas over into sense impressions. Molavi presents the theoretical foundations of this thought in Fihe-ma-Fih, and practically portrays the thought in the Masnavi.   This allegoric philosophy which is based on the two-dimensional nature of allegory – narrative surface structure and intellectual deep structure – furnishes the tale with a double structure; one functioning as literary allegory and the other as spiritual and philosophical allegory. In the writer’s narrative style, this leads to the reduction of some essential elements of a story such as suspense. It could be seen that in the Masnavi’s stories the two structural dimensions mix along the narrative line of the story in a form known as “representation building”. Another manifestation of allegory in Molavi’s works is “allegoric interpretation”, used to describe the coded and implicit themes of stories, whose main function in all its forms is “to teach”. 

 
 

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Architectural Survey in recent decades shows that the modern architecture has not been considered compatible with climatic conditions and it not only causes Environmental pollution but also increases cooling and heating costs. Nowadays architects are looking for appropriate solutions to design buildings that can be in harmony with their environment and climate. As there are different seasons and days in each climate, so designing building system that can vary with ambient conditions seems necessary. Since the sunlight is one of the most important and effective climate factors in indoor conditions, in order to control of heat and light in the window, author got the basic idea from the shadow of a cup of tea. If the colored liquid is injected between double glazed windows, light passing through the window will reduce a lot. Variable Building Layers System (V.B.L.S) is an innovative design that has been patented by the author and can control heat transfer in buildings and improve thermal comfort. The system has been designed based on the basic idea after some trial and error and includes three main components: transparent layers, color tanks, pump and control valve. Its transparent layers can be made of tempered glass or Plexiglas that both of them are separated by a spacer. The way it works is that colored liquid is injected into layers through the pump. The system has the ability to change transparency in less than an hour and make one way vision glass, if necessary. Laboratory samples of this design were built during the 8 stages of the process which includes: -1 Controlling light passing through the window by colored liquid, -2 Controlling light passing through the window by various colors, -3 Controlling window visibility and transparency, -4 Creating various colors by mixing primary colors, -5 The ability to use the idea for walls: Using window idea in designing internal walls and Using window idea in designing external walls, -6 The ability to paint a wall with various colors, -7 The ability to move the location of thermal insulation, 8. The ability to control the system by a computer. In this paper, Variable Building Layers System is explained and discussed in detail as it is used for windows and walls. Three transparent layers that is injected colored liquid between them will create variable properties in windows and walls. The main objective was to achieve maximum variability in building walls and it was assumed that changing colors will decrease or increase the light passing through layers, so in order to prove this hypothesis, experiments were performed. Due to different absorption and passing light from various colors their shadow had a different temperature. The main advantage is that these layers vary based on outside conditions by controlling sunlight and heat daily. The external walls was also added a tank of argon gas (as a thermal insulation) to reduce temperature swing inside the building. These layers can achieve benefits such as varying color and transparency, and control the amount of light passing through them, decreasing or increasing the heat capacity, and also moving the location of thermal insulation manually or automatically by computer. Using various colors in windows and walls will provide different thermal and psychological effects on occupants. Opacity or transparency of these layers can provide appropriate view and sunlight because it is possible to make part of the layer opaque and also to allow daylight to pass through from transparent part. It also creates less design limitations for architects. As bright colors reflect sunlight much more than dark colors, so changing color of façade can increase or decrease absorption of solar energy and reduce heating and cooling energy consumption. Based on Johannes Itten’s Color theory, it can make you feel 3 to 4 degrees centigrade warmer or cooler by selecting warm color for winter and cool color for summer without using energy. Each climate requires walls with different heat capacity but in this system it is possible to adjust the heat capacity with indoor temperature. Heat capacity of water is more than air so if the middle layer of the wall fills with water, temperature swing will decrease and also with reducing water level and replacing air, heat capacity will become less. In these walls, thermal insulation can be inside or outside of the walleither manually or automatically by a computer daily. In temporary-use buildings heat is removed after passing through the thermal insulation but it is possible to change location of the insulation towards outside after passing heat and it is not allowed to remove. To sum up, Heat capacity and thermal insulation can vary in every climate based on different seasons that leads to reduce indoor temperature swing. Noting that the heat transfer occurs in the building by three methods, changing layers can make different thermal resistance. As thermal conductivity of water and air and argon is respectively less than the other, heat transfer by conduction and convection depends on what matter and what height layers is filled. Glass walls are able to allow sunlight to enter rooms in the winter (if heating is needed) that absorb and store sun’s warmth and so radiation heat transfer causes a reduction in heating. Another advantage of this system is that external and internal walls are respectively up to 10 centimeters and 3 to 5 centimeters in thickness and so reduced thickness of walls leads to increase surface area and volume of the building. Wall thickness reduction compared to the same walls is noticeable because of reducing weights of building materials. Therefore it will decrease building subsidence and increase earthquake resistance of the building. As previously mentioned glass layers will provide natural light and suitable perspective and even if walls need to clean, these layers will allow washing. According to descriptions, Variable Building Layers System can be use in many buildings such as houses, offices, greenhouse, museums, galleries, libraries and etc., because of varying color of walls, controlling heat and light and moving thermal insulation and generally compatible with each climate.

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Architectural Survey in recent decades shows that the modern architecture has not been considered compatible with climatic conditions and it not only causes Environmental pollution but also increases cooling and heating costs. Nowadays architects are looking for appropriate solutions to design buildings that can be in harmony with their environment and climate. As there are different seasons and days in each climate, so designing building system that can vary with ambient conditions seems necessary. Since the sunlight is one of the most important and effective climate factors in indoor conditions, in order to control of heat and light in the window, author got the basic idea from the shadow of a cup of tea. If the colored liquid is injected between double glazed windows, light passing through the window will reduce a lot. Variable Building Layers System (V.B.L.S) is an innovative design that has been patented by the author and can control heat transfer in buildings and improve thermal comfort. The system has been designed based on the basic idea after some trial and error and includes three main components: transparent layers, color tanks, pump and control valve. Its transparent layers can be made of tempered glass or Plexiglas that both of them are separated by a spacer. The way it works is that colored liquid is injected into layers through the pump. The system has the ability to change transparency in less than an hour and make one way vision glass, if necessary. Laboratory samples of this design were built during the 8 stages of the process which includes: -1 Controlling light passing through the window by colored liquid, -2 Controlling light passing through the window by various colors, -3 Controlling window visibility and transparency, -4 Creating various colors by mixing primary colors, -5 The ability to use the idea for walls: Using window idea in designing internal walls and Using window idea in designing external walls, -6 The ability to paint a wall with various colors, -7 The ability to move the location of thermal insulation, 8. The ability to control the system by a computer. In this paper, Variable Building Layers System is explained and discussed in detail as it is used for windows and walls. Three transparent layers that is injected colored liquid between them will create variable properties in windows and walls. The main objective was to achieve maximum variability in building walls and it was assumed that changing colors will decrease or increase the light passing through layers, so in order to prove this hypothesis, experiments were performed. Due to different absorption and passing light from various colors their shadow had a different temperature. The main advantage is that these layers vary based on outside conditions by controlling sunlight and heat daily. The external walls was also added a tank of argon gas (as a thermal insulation) to reduce temperature swing inside the building. These layers can achieve benefits such as varying color and transparency, and control the amount of light passing through them, decreasing or increasing the heat capacity, and also moving the location of thermal insulation manually or automatically by computer. Using various colors in windows and walls will provide different thermal and psychological effects on occupants. Opacity or transparency of these layers can provide appropriate view and sunlight because it is possible to make part of the layer opaque and also to allow daylight to pass through from transparent part. It also creates less design limitations for architects. As bright colors reflect sunlight much more than dark colors, so changing color of façade can increase or decrease absorption of solar energy and reduce heating and cooling energy consumption. Based on Johannes Itten’s Color theory, it can make you feel 3 to 4 degrees centigrade warmer or cooler by selecting warm color for winter and cool color for summer without using energy. Each climate requires walls with different heat capacity but in this system it is possible to adjust the heat capacity with indoor temperature. Heat capacity of water is more than air so if the middle layer of the wall fills with water, temperature swing will decrease and also with reducing water level and replacing air, heat capacity will become less. In these walls, thermal insulation can be inside or outside of the walleither manually or automatically by a computer daily. In temporary-use buildings heat is removed after passing through the thermal insulation but it is possible to change location of the insulation towards outside after passing heat and it is not allowed to remove. To sum up, Heat capacity and thermal insulation can vary in every climate based on different seasons that leads to reduce indoor temperature swing. Noting that the heat transfer occurs in the building by three methods, changing layers can make different thermal resistance. As thermal conductivity of water and air and argon is respectively less than the other, heat transfer by conduction and convection depends on what matter and what height layers is filled. Glass walls are able to allow sunlight to enter rooms in the winter (if heating is needed) that absorb and store sun’s warmth and so radiation heat transfer causes a reduction in heating. Another advantage of this system is that external and internal walls are respectively up to 10 centimeters and 3 to 5 centimeters in thickness and so reduced thickness of walls leads to increase surface area and volume of the building. Wall thickness reduction compared to the same walls is noticeable because of reducing weights of building materials. Therefore it will decrease building subsidence and increase earthquake resistance of the building. As previously mentioned glass layers will provide natural light and suitable perspective and even if walls need to clean, these layers will allow washing. According to descriptions, Variable Building Layers System can be use in many buildings such as houses, offices, greenhouse, museums, galleries, libraries and etc., because of varying color of walls, controlling heat and light and moving thermal insulation and generally compatible with each climate.

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Aims: Despite the existence of potential human and executive forces in Iran, industrialization and the use of materials in buildings in order to prevent the waste of materials, has gone through a very slow process, and considering the importance of the construction sector in Iran's economic activities, it is necessary to take effective measures to be done in this context. For this purpose, this research has been carried out with the aim of identifying and ranking the effective indicators on the waste of materials according to the existing theoretical foundations.
Methods: In terms of the purpose of this research, it is a developmental type of research, and in terms of the method of doing the work, it is descriptive, survey and document type. In order to identify the effective factors, a sample was selected from among the community of experts in this industry with a simple random sampling method, and the desired data was collected by distributing a questionnaire and analyzed with SPSS statistical software.
Findings: The research showed that proper design  has the greatest effect on the increase in construction waste. After that, the construction industry  in the second place, education  in the third place, financial resources and economic justification  in the fourth place and finally the reserve and warehouses  have the least impact on the increase of waste.
Key Words: Modern Materials, High-Rise Buildings in urban centers, Zero Waste.
 

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Neighborhoods and public buildings are required to comply with specific criteria from the perspective of passive defense to survive and to continue its activities in conditions of crisis. In order to achieve the criteria, the recognition of threats and the priority of local public buildings based on various items can be helpful. The priorities explain which the user is more sensitive, more vulnerable and in times of crisis can be useful. The aim of the research is the priorities of existing buildings in the neighborhood on the field of functional necessity, the application in crisis and the sensitivity of the enemy. In times of crisis, Cities and accommodation and activity centers as well as public buildings as centers of human and material capital are the target for the enemy and attack them causes great damage. Accordingly, the neighborhoods that form the cities and public buildings in there are always on top of the important purposes of attackers. So through this paper study the urban buildings in the neighborhood of three terms of the amount of applicability in crisis, the sensitivity of the enemy and the sphere of functional necessity. Delphi technique used in this study and the research population included all defense experts and architecture, of which 12 samples selected. In general, the concept and household of neighborhood can be defined as different aspects of social, psychological, mental, cognitive, architecture (physical) and politically. Regarding to the world literature, two words, township and neighborhood can translated as the concept of neighborhood. While included the populations of them, respectively, 2000 and 10000 and 15000 to 40000 people. The first word is residential neighborhood that has a distinct identity but the second word refers to an area that in addition to large size has a diverse career opportunities. In urban classification, neighborhood is the first category and then the region, district, city and beyond, the next field. This neighborhood has the necessary equipment, including schools, supermarkets and entertainment centers. Public buildings of neighborhood that used as the first area of urban buildings including banks, shopping centers, libraries, mosques and religious sites, indoor clubs, schools, small industrial sites, hospitals, clinics and laboratories, emergency centers, subway, bus terminals, car parks, restaurants, fire station, power station, gas station, water and security centers. The purpose of measuring the important urban centers whit this benchmark is to find places that have the most users at the time of the invasion of the city, also have more effects in comparison with other users. This priority known against those places that is not effective in crisis. Identification of such sites has the advantage of looking for lasting strategic locations and finding solutions to maintain the physic and performance of those sites. Also, identify the places that the enemy does not considered as important targets and remove them from the priority of places in order to secure. If the domain of passive defense extended by the presence of some vital services after enemy attack, then the activities and places that are essential will identify during the threats. Other places that are diagnosed unnecessary or less effective, have the potential to change the physic to new performance. Provided that the architectural design is flexible and meet the vital needs of the city. In this study, the Delphi technique performed for the Prioritization of public buildings in terms of passive defense in times of crisis. The first point in the Delphi panel is the way to choose its members so that usually invited 10 to 15 specialists is the best for participation in Delphi. Delphi panel members for this study selected for non-probable sampling and combination of purposive or judgmental and sequential methods of 12 patients. In this method, the panel members usually offer their opinions in numbers, then the average is calculated by agree and disagree panel members, subsequently this information notified to members to obtain new ideas. In the next step, each member offers new opinion or modifies his previous opinion based on information obtained from the previous stage. This process continues until an average number is stable enough. The questionnaire designed as for the proposed priorities. According to the results shown the average per any local user, calculate by priority on the amount of applicability of the crisis, the sensitivity of the enemy and the sphere of functional necessity. In this way, there is priority on the amount of applicability of the crisis, the sensitivity of the enemy and the sphere of functional necessity for every 10 local buildings. The result in neighborhood suggests that priority applications on the sensitivity of the enemy, the first priority attack in the enemy point of view according to the panel members are military statins, power stations, gas stations and water centers. Mosques and religious sites, clinics and health centers, subway, parking and fire stations are as second priority and the banks, shopping centers and nonprofit services, libraries, indoor clubs, schools, kindergarten and restaurants is considered worthless attack. The priority on the sphere of functional necessity, clinics and health centers, subway, fire stations, power stations, gas stations, water centers and military stations are necessary, parking is rather essential and restaurants, libraries, Mosques and religious sites, indoor clubs, schools and kindergarten are non-performance. Also in priority on necessity in crisis, banks are non-usable, parking, schools and kindergarten, indoor clubs, Mosques and religious sites and libraries have possibility of granting new performance (indirect use) and shopping centers and nonprofit services, clinics and health centers, subway, fire stations, power stations, gas stations, water centers and military stations are a direct function (Maintain existing performance). The results in the prioritization in public buildings in the neighborhood suggest that the use in the prioritization in public buildings the neighborhood includes 10 users and each user also contains one or two sub-user. The applications analyzed based on three priorities (the amount of applicability in crisis, the sensitivity of the enemy and the sphere of functional necessity). The priority applications on the sensitivity of the enemy, the first priority attack in the enemy point of view according to the panel members are military statins, power stations, gas stations and water centers. The priority on the sphere of functional necessity, clinics and health centers, subway, fire stations, power stations, gas stations, water centers and military stations are necessary. In priority on necessity in crisis, shopping centers and nonprofit services, clinics and health centers, subway, fire stations, power stations, gas stations, water centers and military stations are a direct function (Maintain existing performance). Designing complex subway station and mixing them with crisis management provides an opportunity to understand multi-functional of station spaces. This article seeks to reduce vulnerabilities in the analysis subway stations measures to be considered as temporary accommodation in an emergencies and provide a safe space research questions inclusive weather do you have ability to the performance is also, in addition to its roles as station for transport and cultural and commercial complex; in critical condition become to temporary housing? Or what factors effect on flexibility of architectural complex subway? We have very good station complex in our country. A station complex itself consists of several levels of services areas include entertainment and office. This type of sorting and spatial layout is designed based on the needs. But in this paper we discussed bout benefits of this wide space and advantages of all the facilities and equipment in emergencies. Developing countries, including Iran, in addition to being more prone to accidents and natural disasters than other communities, total human casualties and property damage in case of accident these communities are heavier. To prevent the occurrence, planning to rescue damaged area and temporary accommodation, all communities need new Disaster Management. In the present study we have tried through a multi-functional and flexible design, the central station with the highest integrity economic, social and environmental be prepared to deal with the sudden crises. Despite the unexpected event and the space subway stations is located in the basement created a good spaces for sheltering people affected.

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Introduction and Literature Review: Reducing energy consumption and greenhouse gas emissions to alleviate the effects of global warming have become a worldwide necessity. This matter has significant importance in Iran, because Iran has the seventh ranking position of global greenhouse gas emissions and its rate of growth is above global average. Building construction sector is experiencing a fast-paced growth in developing countries, like Iran, due to growth of economy and rapid urbanization. A large number of buildings are being built for residential, commercial and office purposes every year. Built environments are responsible for about 40 percent of energy consumption in Iran and it is generally approved that the greatest portion of built environment is dedicated to residential use. Energy consumed in producing and processing building materials and in the processes of building a house, is usually calculated using embodied energy concept. Until recently, it was generally accepted that the energy used during the occupation of a building represented a much higher proportion than its embodied energy; thus, great efforts were put into reducing energy use in this phase. New and improved technologies have reduced the operational energy through a variety of solutions, including energy-efficient equipment and appliances, improved insulation levels, low energy lighting, heat recovery systems, the provision of solar hot water systems, photovoltaic panels for generation of electricity, and other renewable technologies. However, these measures often imply an increase in materials use and energy demand for their production, which explains the growing importance of other phases in the total life cycle. According to the global literature, embodied energy of a building accounts for one third to one fifth of the total life cycle energy consumption of a specific building. However as the global trend for the new developments moves toward the zero energy/carbon buildings, the importance of the embodied energy increases. In fact embodied energy is one of the leading parameters in assessing building’s environmental performance, because in building projects, vast amounts of building materials are needed which consume great amounts of embodied energy and thus have negative effect on environment. With this preamble, improving energy efficiency of the existing dwelling stock of urban regions will increasingly be part of achieving sustainable development in future. Although this aspect of achieving sustainable development has been the subject of many global practices in recent years and global literature is almost rich in the calculations and analysis of embodied energy and life cycle energy consumption, this matter has been neglected almost completely in Iran and those few studies conducted focusing on energy in urban planning and designing fields, are mainly concentrating on transportation sector. Thus the main goal of this study is analyzing the sustainability of urban residential sector with focusing on embodied energy consumption. Methodology: In this regard, residential sector in Shiraz Metropolitan has been divided into seven different dwelling types including central-yard houses, attached terrace houses (one story houses, two story and three story houses), apartments (which are buildings of four story and above), villas and declined houses. Gathering raw data in this study was challenging, considering the fact that house building in Iran is far from industrialized and prefabricated building is really limited. Unfortunately there is no data available on the average material consumption of different dwelling types in Iran and the only study similar to this was done focusing on building structures. Using this only available data, we built our data bank in Microsoft Office excel and then focused on computing average embodied energy via multiplying embodied energy of common building materials extracted from a report conducted in the University of Bath titled “Embodied Carbon: The Inventory of Carbon and Energy (ICE)” into average material consumption based on building structures. Another point we had to take into account was the unit of the available data; while embodied energy of materials were presented in gigajoules per square meter, average material consumptions of dwellings were presented in different units from square meters, to cubic meters, kilograms and blocks. So using density of materials we established a second data base with similar units. Normalizing this raw data through dividing average embodied energy of residential dwelling by dwelling area we calculated the capitation of embodied energy for each dwelling. Afterwards we prioritized embodied energyconsumption of dwelling types from lowest embodied energy capitation to the highest as follows: brick and wood structures with about 3 GJ/m^2 embodied energy, clay brick concrete structures, clay brick steel structures, brick concrete structures, brick and iron structures, and at last brick steel structures with about5.35 GJ/m^2 embodied energy Results: To be sure of the validity of these comparisons analysis of variances (ANOVA) and Post Hoc Tests (Least significant difference- LSD) have been applied to these data in IBM SPSS statistics 19, and the result has been positive. Then collected data were shifted from structure types to dwelling types and we found out that central-yard houses with 3.6 GJ/m^2 embodied energy per capita are the most energy efficient dwelling types. After this type in sequence lay one-story terrace houses (4.21GJ/m^2 ), apartments (4.26GJ/ m^2 ), two story terrace houses (4.67GJ/m^2 ), declined houses (4.81GJ/m^2 ), villas (4.84GJ/m^2 ), and three story terrace houses (5.21GJ/m^2 ). Discussion and Conclusion: This paper highlights the need to use location-specific data in the development of building assessment schemes and the issues related to the use of embodied energy assessment for the building sector. Absence of localized data base on building material consumption on the basis of dwelling type and lack of data on cradle to grave embodied carbon and energy of common building materials were the most important obstacles in this research. On the basis of international research, paint, bitumen, platevirgin, sheet Galvanized-virgin, steel, ceramics, primary glass, iron bars, lime, cement, and common brick are the most energy intensive materials. So on account of lack of localized data, we used international embodied energy of common building materials (cradle-to-gate) to calculate embodied energy of different dwelling types. Despite of major shortcomings in data base, noteworthy conclusions have been deducted from this work which are summarized as follows: traditional form of housing in Shiraz which is known as central yard houses in this paper with brick and wood structures (in which there is a yard in the center of the block and the residential parts are located at its periphery) are the most sustainable form of housing according to this research criteria and case study. This may owe its accomplishment to the low embodied energy of common materials used in this type of housing which we may call the most environmental friendly form of housing in Shiraz. Furthermore there is a substantial lack of data on embodied energy and carbon of materials in general, and in particular on the embodied energy and carbon of buildings to be able to do an entire evaluation of buildings in their life long period. So to do a complete research in building sector (life cycle assessment), including embodied energy, gray energy, operational energy, induced energy, Demolition/Recycling Energy, and retrofit energy are unavoidable.

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In order to reduce the energy consumption and CO2 emissions, we are supposed to find some ways to diminish our reliance on fossil fuel .Generally, energy use in residential, commercial and public buildings account for %36 of total global final energy consumption in Iran.(Secretariat of Energy and Electricity، 44 :2013) In this regard, renewable energy resources have become vital for heating and cooling. Using solar systems is an appropriate measure towards reduction of fossil fuel consumption and mitigation of adverse environmental impacts. According to the huge potential of solar radiation in Iran, integration of heating and cooling systems in the building envelope is a necessity if the systems are to be economically feasible. The integration is possible only if the design of the passive technology is included in the early stages of the design process. Space heating is the most important building energy use in regions with cold climate and one of the passive solar technologies which is used in mentioned regions is Trombe-wall. Classic Trombe-wall is a passive solar system made up of a south-facing massive wall painted in black on the external surface, an air layer and glazing on the exterior. The wall is equipped with vents at the top and at the bottom for the air thermo-circulation in the air gap. The Trombe-wall systems function by absorbing solar rays and converting their energy. A Trombe-wall stores energy during the sunshine and supplies energy when a building’s occupants require it. It has been widely studied regarding winter behavior, but in summer the system can cause undesired heat gains and overheating phenomena, especially in well insulated buildings. Only few studies focus on their summer behavior. Overshadowing on Trombe-wall’s glazing in summer is an action recommended by several authors. “Modular building envelope panel with heating and cooling capability” is inspired from Trombe-wall in heating scenario and looking forward to improving its summer behavior by the use of evaporative cooling system. In the current study, water was used instead of conventional masonry material, according to its thermal capacity, transparency and fluidity. In summer, the water is discharged and cooling loads are reduced using evaporative cooling. This strategy results in overall building efficiency improvement. (Abolhasani, 2014:21) We attempted to design a modular system for the façade. Modularity offers many advantages and solves some parts of the problems in using conventional built in-situ solar walls. It facilities industrial mass production with high quality and ease of installation, repairing and maintenance. Fully modular products could allow components to be replaced without affecting other elements and reduces the total cost of the entire product. Modular design facilitates design standardization by identifying the component’s performance clearly and minimizing the incidental interactions between a component and the rest of the product. We assessed energy performance of proposed panel using EnergyPlus 8.1 simulation software and investigated influence of it on heating and cooling loads. In order to do that, a series of hour-by-hour simulations carried out on two different models that are made of some thermal zones. The first one is a single room with the dimensions 3m*4m*3m which its south facing side is a double glazed curtain wall. The other model is a room with proposed panel which consists of two zones – a room with the same dimension as that of the first model, named “Room zone” and a zone dimensioned 0.1m*4m*3m, named Trombe zone. These two zones must have an inlet and an outlet “node” to link them in an air loop within the simulation. Air Loop is formed by defining nodes and components. We defined different components in different seasons. We used a supply plenum exposed to sun, for winter and evaporative cooler component, for summer. For winter simulation we made use of water as collector and storage material and supposed air loop between trombe zone and room zone. For summer behavior, water is supposed to be discharged to activate evaporative cooler component in the air loop. Comparing the output of simulations showed that designed panel decreases heating and cooling loads in our assumed model. We iterated the simulation in room with proposed panel to optimize different parameters and characteristics of constitutive elements. We optimized thickness of water layer as a thermal mass. The results showed that in thicknesses under 125mm, increasing the thickness decreases heating load significantly, however over 125mm, the decreasing rate slows down. The thickness of 125mm reduces 65 percent of heating load in working hours. In order to select the best exterior glazing material, a series of simulations carried out on 6 types of glazing. The effect of glazing type was investigated using net heat gain. Low emission coating showed the best performance. Using low emission glazing instead of single glazing for a Tromb-wall system not only reduced heat losses in winter but also enhanced passive cooling in summer. Results also proved that natural ventilation cannot reduce cooling demand in cold climate condition. It can be alleviated by evaporating cooling and reduction of sensible heat and have a positive impact on summer performance. To improve energy efficiency in designed panel, a forced air circulator was used. In evaporative cooling scenario water consumption and airflow rate was optimized by simulations. The results showed the best performance in an air flow rate ranging from 0.10 up to 0.15 m3/s (equivalent to 300-200 cfm). Finally, the optimized values were used to redesign details of the panel. Proposed panel consists of polycarbonate plenum, low emission glazing on exterior side, dampers, ultrasonic evaporative cooler, movable shading, centrifugal fan and horizontal stud- in order to increase resistance of plenum against static pressure of water. Evaluation of suggested system in the sample model proved its effectiveness in reduction of annual energy demand -heating and cooling loads. The results of this research is based on the weather data of Tabriz, Iran, and the specific sample, so these values cannot be applied to the other climate regions and building conditions. Independent studies should take place for various climate conditions. Also, it would be better to do some experimental surveys to validate the results of the research.

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Energy efficiency and comfort consideration in building, contribute to significant energy saving and improvement of spatial quality. According to the importance of energy issues and lack of researches on energy use in educational buildings, climatic variation in the country and huge amount of energy consumption in educational buildings, the need of redefinition environmental design criteria is essential.
The main purpose of this article is to assess the influence of different design variables on comfort condition and energy consumption in the hot-Arid climate of Tehran. Most of the literature concerned with energy performance of school buildings is focused on using saving methods such as utilization of solar energy, constructional issues such as thermal insulation, infiltration, thermal mass, building materials, sun shadings and HVAC performance while assuring thermal comfort and indoor air quality of the building. However, the topic of energy performance and comfort condition of schools located in Iran’s climatic conditions has not been explored.
Nowadays, the subject of energy and optimizing energy consumption in different buildings and different societies is of great importance. On the other hand, energy experts claim that in designing educational buildings, natural energy resources should be used most. This subject is related to the energy consumption of schools. Furthermore, the positive effect of thermal and visual comfort on the quality of students’ education has been confirmed. Educational buildings generally are spaces with different functions.
However, classrooms not only have a central role, but also cover a great part of the school surface. Classrooms are the most fundamental and important units of the educational buildings in terms of energy consumption and thermal comfort. Students spend most of their time in the classrooms. Classrooms are more important, given the relative congestion in comparison with other educational spaces. Due to this fact, proper ventilation is considered necessary. Furthermore, students’ presence as latent thermal energy sources needs special attention in hot seasons. On the other hand, the same thermal sources can play an effective role in creating the comfortable conditions. Therefore, according to the difference of using pattern of these places and their higher internal heat gain, energy saving patterns in designing office and residential buildings cannot meet the needs of designing these buildings.
Methodology
This research using simulation method is looking forward to realize the influence of different physical variables on energy consumption in educational buildings in Tehran’s climate; the different circumstances that were resumed by diverse variables were assayed. this process took place with the help of E quest energy simulating software and during this process in two separate parts, the independent effect of each variable and the simultaneous influence of applying diverse variables on energy consumption were simulated and its results were compared and discussed in various steps.to enumerate the most essential effective parameters in determining the amount of energy consumption in educational building in Tehran’s climate, we can point out the infiltration rate, heat isolating of the building roof and windows dimension.
To understand the range of influence of each variable on the comfort condition and energy consumption in the classroom, the difference between the maximum and minimum energy consumption obtained for each of the evaluated variables was considered. This difference represents the potential savings that can be achieved by improving a variable within the considered range of values. In this work, the four main orientations were analyzed.to observer the influence of design parameters on energy consumption, a base case classroom was designed and then the absolute and simultaneous effects of different parameters were assessed. The base-case was a common classroom to where all changes were applied and examined. Based on the similar studies, the recommended value for each design variable was determined to achieve a high
performance classroom. The fixed parameters of the classroom were its size and height. The thermostat of the heating system was set at 21.1 C while the thermostat of the cooling system was set at 24 C, due to the dissimilarity in the children’s clothing in different seasons. The ventilation system provides a minimum of 4.5 air changes-per-hour (ach) when the classroom is occupied. When there were no children in theclassroom, the ventilation rate will reduce to save energy and the lighting level on the children’s tables was set at a minimum of 300 lux.
Results
The results indicate that by reducing the infiltration rate of the classroom from 4.5 ACH to 0.75 ACH, an energy saving of about 65 KWH/m2.y will achieved. The airtightness of a classroom depends on windows and doors type, quality, and materials as well as on the quality of the construction process. For obtaining infiltration rate of about 0.75 ACH, designers and contractors should give more attention to the quality control of materials and construction and energy performance of the windows and the doors. Meanwhile according to the high amount of sun radiation during the year, roof heat insulation with a 6cm polyurethane layer would reduce the energy consumption by 40 KWH / m2.y in comparison with a roof without any heat insulation. Since the windows have a significant influence on the energy consumption and performance of the classroom, In order to reduce the energy consumption, dimensions and position of the windows should be choose very carefully. It was observed that the recommended size of north and south facing windows is equal to %12 of the classrooms floor area, whilst east and west facing windows should not be exceeds from %10 of the classroom area. If the windows size exceed from %12 of floor area, the glare effect would make visual discomfort for the students. In the simulation process, three types of light control features were evaluated. The results show that with the aid of smart lighting control system, the required electrical energy for lighting would reduce 34 KWH / m2.y. And finally the types of glazing have an important role in energy consumption of the classroom. It is observed that high performance was achieved when using lowemissivity
glazing to reduce cooling loads and encourage daylight in classroom. Double glazed windows shows acceptable performance as well, in all directions compared to other alternatives.
Discussion and Conclusion
After analyzing the absolute effect of each parameters on energy consumption and comfort condition in the classroom, the cumulative effect of all parameters were analyzed. It is obvious that by changing of each parameter, the effect of other parameters will be changed. In this case two combination of design variables are assessed in “set-a” and “set-b” in which the annual energy consumption of the classroom is maximum in “set- a” and minimum in “set-b”. Based on the results obtained by simulation, this can be claimed that the proper design of classrooms in hot and arid climate, like the city of Tehran can reduce the amount of energy required for cooling, heating, ventilating and lighting systems from 232 KWH/ m2.y in “set-a” to 104 KWH/ m2.y in “set- b”. It means a %55 reduction in the classroom’s energy consumption. This statics are in conformity with the results achieved by researches in European’s green school which can reduce %55 up to %75 of heating energy consumption and 30 % up to 40 % of electrical energy consumption by using different tricks.