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![Page 1: Environmental Skin](https://reader034.fdocuments.us/reader034/viewer/2022042617/568c49a51a28ab491694fe30/html5/thumbnails/1.jpg)
AN ENVIRONMENTAL SKINSEnhancing Thermal Performance with Double-Skin Facades for Hawaii’s
Climate.
Christopher G. Strahle
Research Document Presentation
Committee Members
Chair: David Rockwood, PhD
Stephen Meder, Arch.D, LEED
Kris Palagi, AIA, M.Arch,
Manfred Zapka, PhD, PE, LEED-AP, CEM
School of Architecture
University of Hawai’i at Mānoa
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ABSTRACT
Highly glazed commercial buildings in Hawai`i present overheating challenges due to high outside
temperatures combined with solar gains. In order to optimize thermal performance and reduce
excessive cooling loads, the thermal behavior of this type of building requires careful investigation. As
an increasing interest in double-skin facades as a successful methodology for controlling building
performance continues to be explored in Europe , its feasibility within Hawai`i’s climate has yet to be
discovered. In this study, double-skin façade design strategies are examined in Hawai`i’s climate
focusing on enhancing thermal performance on an existing building model. This research adopts a CFD
simulation approach to model heat and air flow transfers in various double-skin façade design scenarios.
The impact of solar radiation, surface temperature, cavity height and air flow rate on temperature and
velocity fields inside the channel of the double-skin facade is analyzed. This research focuses on the
investigation of context based design for double-skin facades, particularly focusing on design
considerations during the design process. In conclusion, this investigation will help to identify the
potential of this specific system within Hawai`i’s climate and its ability to improve thermal performance
within existing buildings.
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CONTENTS
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I. INTRODUCTION
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The Problem:
Hawaii’s climate present overheating challenges due to high outside temperature, solar gains and
internal heat gains which lead to an excess in cooling loads.
A Solution:
Can double skin facades act as a ventilated thermal buffer in an attempt to improve thermal
performance?
Investigation of context based design for double skin facades, particularly focusing on climatic considerations
during the design process.
THE PROJECT
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GOALS
In this study, double skin façade design strategies are investigated to enhance building envelope performance by modeling energy
performance of different design scenarios on the existing building model. Finally a discussion and conclusion section follows in
which the point of view of the author is given and comments are made
Intelligent Buildings: What makes a building Intelligent?
Intelligent features: What are the genetic characteristics?
Thermal Performance: What is thermal comfort, current standards?
Parameters for Design: What are the parameters of thermal comfort?
The Double Skin Facade: How can this system effect performance?
Typology: Façade characteristics?
High-Rise Development: How did it get so bad?
Characteristics: Common characteristics of high-rise stock?
Retrofitting: How do we retrofit these buildings?
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II. PROJECT RESEARCH
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A NEW ERA OF INNOVATION
Intelligent Buildings: What makes a building Intelligent?
“Intelligent design means striving to have our buildings in harmony (and integrate) with nature, to protect its qualities, and to
recognize its dynamic (and unpredictable) qualities, whether assets or liabilities.”
“Adaptation is essential for survival and success: This is true for our buildings as it is for all other aspects of life.”
What if you could design a building that had the ability to self-adjust itself in order to optimize the environmental conditions
within?
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WHAT IS AN INTELLIGENT BUILDING?
An intelligent building is one that maximizes the efficiency of the occupants while at the same time minimizing the cost associated
with running the building.”
- David Boyd
An intelligent building is a house with no style. It is possible that such a building would be positively unsightly, or that there might not
even be anything to see.”
- Ole Bouman, Archis
Building which have fully automated building service control systems.”
- Cardin
“Buildings where the fabric is used to serve as ‘half of the buildings service’.”
- Building Services
Intelligence to a building owner is a good business decision.”
- Alan Abramson
A building becomes intelligent as soon as it is fully rented.”
- New York Developer
A building that responds to its function and environment through technology.”
- Rab Bennetts
An Intelligent Building is one that creates an environment that maximizes the efficiency of the occupants of the building while at the
same time allows effective management of resources with maximum lifetime cost.”
- Robathan
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INTELLIGENT[in-tel-i-juhnt]
Adjective
Ability to vary its state or action in
response to varying situations and
varying requirements.
ENVIRONMENTAL[en.viren’men(t)l]
Adjective
Relating to the natural world and the
impact of its conditions.
SKIN[skin]
Noun
The thin layer of tissue forming the
natural outer covering of the body
of a person or animal.
“one which integrates various systems to effectively manage resources in a coordinated mode to maximize: occupant and building
performance; investment and operating cost savings; and, flexibility.”
INTELLIGENT ENVIRONMENTAL SKIN
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THERMAL PERFORMANCE & THE FACADE
To be able to evaluate thermal comfort, target criteria for the relevant thermal performance for the design must be established,
both design and analysis must be implemented to present a successful solution.
Thermal Performance: What is thermal comfort, current standards?
Environmental Conditioning: Methods of space conditioning?
Parameters for Design: What are the parameters of thermal comfort?
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FAÇADE INTERACTION
The façade of a building forms the interface between the environment outside and the user inside. The objective in the design of
the façade is to find the optimum compromise between the internal and external environment and the requirements of the
planned building use.
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INTELLIGENT FEATURES
These intelligent features have been found to represent the components within built examples of intelligent buildings and what
is being called the “genetic characteristics” which establish the makeup of the intelligent skins.
Intelligent features: What are the genetic characteristics?
Integration : Methods of integrating these features?
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THE DOUBLE SKIN FACADE
The consideration that building envelopes can respond and interact with environmental conditions, the evolution of the double
skinned façade had been the forefront of the design of ‘Intelligent Environmental Skins’.
“The double skin façade system involves the addition of a second glazed envelope that has the ability to maximize opportunities
for thermal control and improving a buildings energy performance.”
Building Performance: How can this system effect performance?
Typology: Façade characteristics?
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DEFINITION OF DOUBLE SKIN FACADE
“Essentially a pair of glass “skins” separated by an air corridor. The main layer of glass is usually insulating. The air space between the layers of glass acts as insulation against temperature extremes, winds, and sound. Sun-shading devices are often located between the two skins. All elements can be arranged differently into numbers of permutations and combinations of both solid and diaphanous membranes”.
- Harrison and Boake
“A façade that consists of two distinct planar elements that allows interior or exterior air to move through the system. This is sometimes referred to as a twin skin.”
- Arons
“A pair of glass skins separated by an air corridor (also called cavity or intermediate space) ranging in width from 20 cm to several meters. The glass skins may stretch over an entire structure or a portion of it. The main layer of glass, usually insulating, serves as part of a conventional structural wall or a curtain wall, while the additional layer, usually single glazing, is placed either in front of or behind the main glazing. The layers make the air space between them work to the building’s advantage primarily as insulation against temperature extremes and sound.”
- Uuttu
“A second skin façade is an additional building envelope installed over the existing façade. This additional façade is mainly transparent. The new space between the second skin and the original façade is a buffer zone that serves to insulate the building.
- Claessens and DeHerde
“an envelope construction, which consists of two transparent surfaces separated by a cavity, which is used as an air channel. This definition includes three main elements: (1) the envelope construction, (2) the transparency of the bounding surfaces and (3) the cavity airflow.”
- Saelens
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Comparative matrix based on façade classifications by Battle McCarthy and the specific ventilation, solar control, and construction
strategies; identifying the different classifications of the double-skin façade and the different cases that can be considered.
CLASSIFICATION
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THERMAL INSULATION
Compared to single-layered facades, the double skin construction can achieve a comfortable degree of thermal insulation; but when the
two layers are designed with poor performance fully glazed skins, the cooling loads will increase in proportion to the area of glazing.
Energy Balance- Energy flow paths - Heat transmission - Material properties - Efficiency of shading
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AIRFLOW
The thermal behavior of double-skin facades is significantly affected by the
airflow within the system. The flow of air towards, around and within the
assembly greatly affects the aerodynamics of the overall performance system.
• Type of double skin façade
• Geometry of the façade
• Layer composition
• Ventilation strategy
Fan Assist
• Pressure differences caused by
mechanical systems
Driving Force
• Pressure differences caused by wind
Stack Effect
• Pressure differences caused by
thermal buoyancy
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CASE STUDIES
The purpose of the case study section is to provide references for built examples and to identify the various intelligent features
implemented within current building envelopes. In relation to the research project, emphasis has been placed on the methods of active
responsive control of the building’s facade as it relates to thermal comfort regulation.
GWS HEADQUARETERS
Berlin, Germany
Client: Gemeinnutzige Siedlungs
Wohnungsbaugesellschaft
Architect: Sauerbruch & Hutton Facility:
Office Tower
SUVA INSURANCE BUILDING
Basel, Germany
Client: Schweizerische Unfall-
Versicherungs-Ansalt Architect:
Herzog & de Meuron
Facility: Office Building
OCCIDENTAL CHEMICAL
Niagara, New York
Client: Hooker Chemicals
Architect: Cannon Design Inc.
Facility: Research
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High-Rise Development: How did it get so bad?
Characteristics: Common characteristics of high-rise stock?
Retrofitting: How do we retrofit these buildings?
BUILDING STOCK
These intelligent features have been found to represent the components within built examples of intelligent buildings and what
is being called the “genetic characteristics” which establish the makeup of the intelligent skins.
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ENERGY CONSUMPTION
In Hawaii it is increasingly observed that existing commercial high-rise buildings with highly glazed facades present overheating
challenges due to high outside temperatures and solar gains. The increase need for air conditioning adopted to provide
comfortable temperatures within work hours corresponds with the peak temperatures in the day.
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BUILDING CHARACTERISTICS
Height
There is no absolute definition of what constitutes a “tall
building”. It is a building that exhibits some elements of
“tallness” in various categories. It’s not just about height
but about the context in which it exists.
Lease Span
The lease span of a building is the clear distance from the
service core to the external envelope. It is dependent on the
functional requirements and size of the floor plate and is an
important consideration for space planning.
Window Area & Type
A buildings window system provides visual connections
between the exterior and interior of the building but also
carry important issues of managing heat gain and loss, as well
as controlling natural daylighting from entering the building.
As the heat gains through opaque walls are low due to the
current high standard of thermal insulation required, it is the
window-to-wall ratio and the combination of glazing types
and sun shading system that effect the magnitude of the solar
gains.
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Types of Strategies:
• The Stabilization
• The Substitution
• The Double Skin Façade
BUILDING RETROFITS
As with every construction, office buildings are subject to physical and functional decline. Regular building maintenance can
slow down this process, but after a certain time larger interventions become inevitable.
Methodology:
• Building Performance Evaluation – Determine building for retrofit solution
• Energy Audit – Comprehensive and detailed energy use study
• Design Solution – Design the most appropriate building retrofit solution
• Implementation – Implement and validate the designed building solution
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III. PROJECT INVESTIGATION
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BUILDING & ENVIRONMENT
First Hawaiian Center: Building brief?
Climate as Context: What are the existing environmental issues?
Due to the fact that the fundamental role of buildings is to protect its occupants from external climactic conditions, developing
an appropriate building envelope is an important part of enhancing a building overall thermal performance. Focus is placed on
the role of the façade as its plays an important part through which these conditions can be controlled.
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FIRST HAWAIIAN CENTER
The First Hawaiian Center, located at 999 Bishop Street in downtown Honolulu, is the tallest building in Hawaii and the corporate
headquarters of First Hawaiian Bank. . Designed by the architectural firm Kohn Pederson Fox Associates (KPF), the tower is
composed of two distinct forms, one which faces the sea and the other which faces the mountains.
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CLIMATE AS CONTEXT
If a building is designed and constructed to accommodate
the local climate (i.e. by using appropriate building
components and operation strategies), then the
achievement of occupant comfort and efficient operation
in the building will be greatly increased.
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SOLAR EXPOSURE
With an understanding of the basics, a detailed solar path analysis of solar rays that will impact the First Hawaiian Center helps to
inform schematic design decisions. The amount and intensity of solar rays that hit the façade of the building throughout the year
play a major role in determining the amount of solar access and exposure the building will endure.
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SOLAR RADIATION
The following simulations have been performed to determine the cumulative yearly value of solar radiation that strikes the buildings
envelope of a given orientation, in this case, north, east, south, west. These radiation simulations help to determine which part of
the buildings envelope receives the most solar radiation and which sections of the façade should be under evaluation.
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WIND FLOW
Hawaii benefits from steady, gentle trade winds typically moving at 15 to 20 mph from the northeast to the southwest. A wind rose
can be used to characterize the direction, speed, and frequency of wind. It gives detailed information about wind direction and
frequency for a month or a whole year.
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FORM & ENVELOPE
Façade Model: Simplified boundary condition?
Analysis: Micro-climate conditions of the existing model?
Envelope Strategies: What does the façade need to do?
To begin to understand these specific areas of the building one must run through the process of first isolation those areas of
interest resulting in a specific façade boundary model.
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FAÇADE MODEL
To begin to understand these specific areas of the building one must run through the process of first isolating those areas of
interest. The building has to be simplified in order to obtain a simulation model. In the case for such a large building with many
similar wall types, a small portion of the building’s façade has been chosen.
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HEAT GAIN
By estimating skin heat flow one can begin to understand its contribution to the building’s cooling requirements. The amount of heat that
is transferred through a buildings skin due to temperature differences between inside and outside is dependent on the size of the
difference, the resistance to heat flow by the skin materials, and the area of the assembly.
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HOURLY TEMPERATURE
These graphs display hourly temperature patterns within the space (without HVAC conditioning) on a temperature/time graph, time
running in the x-axis and temperature in the y-axis.
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SOLAR EXPOSURE
The amount of solar radiation transmitted through the skin of the building is relative to the size of surface area, orientation, and heat
transmission characteristics of the exposed surfaces. Since the solar heat gain through glazing can be fairly large, understanding the
amount of incident radiation that will strike the façade will help to determine specific measures or methods of reducing the solar load.
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FAÇADE INVESTIGATION
Skin Configurations: Specific goals and constraints guiding design?
Approach: How do you approach this model?
Simulations: What are the resulting figues?
Hawaii's location and the application of this system will require a different set of design solutions to meet performance
requirements.
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APPROACH
Simulation of the model helps to represent real physical occurrences and simplification of reality into the modeled façade
condition. As a result, the study has to be simplified in an appropriate way in order to obtain a simulation model.
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CONSTRAINING PARAMITERS
During the planning and design process, recommendations for the design of double skin walls are to select appropriate control
strategy relating to glazing properties, establishment of shading devices, and height of the cavity. Since these parameters are
greatly dependent on the environmental context of the existing building, predicting energy performance early in the design stage
can influence design decisions.
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SINGLE STORY FACADE
One of the advantages of the single story, corridor façade over other typologies is that corridor facades are not limited to the full
height of the building. However, they do not utilize the stack effect as much as the multi-story assembly because the linking
effect will be broken at each floor.
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ENERGY FLOW PATHS
Simulation of the design scenario has revealed the specific heat balance and temperature of the system. Using the graphs
below, we can analysis this specific system and how it affects the buildings internal temperature and those cooling loads needed
to provide a comfortable interior environment. The following section is again presented as two parts; the graphs shows
individual breakdowns which are measured in kBtu/h and temperature by 0F for the specific boundary condition of both the
cavity and the adjacent occupied space.
Cavity Zone
• Zonal Temperatures– Radiant Temperatures
– Operative Temperature
• Heat Balance
– Glazing
– Infiltration
– Internal Gains
Occupied Zone
• Zonal Temperatures– Radiant Temperatures
– Operative Temperature
• Heat Balance
– Glazing
– Infiltration
– Internal Gains
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AIR FLOW PATHS
The ventilation of the intermediate space involves questions relating to the velocity of air flow, the temperature distribution
within the air temperature and the pressure differences that are always the motive force of air currents. The relevant air flow
patterns for this specific scenario can be largely determined on the basis of the information contained in the CFD simulation
results concerning the ventilation of the facades intermediate space.
Velocity Flow Rate
• Point of Stagnation
• Point of Acceleration
• Point of Lowest Pressure
• Point of Separation
• Wake & Turbulence
Temperature Distribution
• Air Intake Temperature
• Air Exhaust Temperature
• Maximum Air Temperature
• Minimum Air Temperature
• Mean Air Temperature
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MULTI-STORY FACADE
The multi-story façade scenario consists of an external air curtain where the air cavity is open at the top and bottom, forming a
large open volume. The intermediate space between the inner and outer layer is joined vertically and horizontally by a selected
number of rooms.
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ENERGY FLOW PATHS
Simulation of the design scenario has revealed the specific heat balance and temperature of the system. Using the graphs
below, we can analysis this specific system and how it affects the buildings internal temperature and those cooling loads needed
to provide a comfortable interior environment. The following section is again presented as two parts; the graphs shows
individual breakdowns which are measured in kBtu/h and temperature by 0F for the specific boundary condition of both the
cavity and the adjacent occupied space.
Cavity Zone
• Zonal Temperatures– Radiant Temperatures
– Operative Temperature
• Heat Balance
– Glazing
– Infiltration
– Internal Gains
Occupied Zone
• Zonal Temperatures– Radiant Temperatures
– Operative Temperature
• Heat Balance
– Glazing
– Infiltration
– Internal Gains
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AIR FLOW PATHS
The ventilation of the intermediate space involves questions relating to the velocity of air flow, the temperature distribution
within the air temperature and the pressure differences that are always the motive force of air currents. The relevant air flow
patterns for this specific scenario can be largely determined on the basis of the information contained in the CFD simulation
results concerning the ventilation of the facades intermediate space.
Velocity Flow Rate
• Point of Stagnation
• Point of Acceleration
• Point of Lowest Pressure
• Point of Separation
• Wake & Turbulence
Temperature Distribution
• Air Intake Temperature
• Air Exhaust Temperature
• Maximum Air Temperature
• Minimum Air Temperature
• Mean Air Temperature
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HYBRID FACADE
The hybrid façade scenario consists of a double skin façade system with operable panels that can be open or close according to
the needs of the system. With this hybrid system a single story or multi-story condition can be formed by means of opening and
closing each individual panel accordingly.
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ENERGY FLOW PATHS
Simulation of the design scenario has revealed the specific heat balance and temperature of the system. Using the graphs
below, we can analysis this specific system and how it affects the buildings internal temperature and those cooling loads needed
to provide a comfortable interior environment. The following section is again presented as two parts; the graphs shows
individual breakdowns which are measured in kBtu/h and temperature by 0F for the specific boundary condition of both the
cavity and the adjacent occupied space.
Cavity Zone
• Zonal Temperatures– Radiant Temperatures
– Operative Temperature
• Heat Balance
– Glazing
– Infiltration
– Internal Gains
Occupied Zone
• Zonal Temperatures– Radiant Temperatures
– Operative Temperature
• Heat Balance
– Glazing
– Infiltration
– Internal Gains
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AIR FLOW PATHS
The ventilation of the intermediate space involves questions relating to the velocity of air flow, the temperature distribution
within the air temperature and the pressure differences that are always the motive force of air currents. The relevant air flow
patterns for this specific scenario can be largely determined on the basis of the information contained in the CFD simulation
results concerning the ventilation of the facades intermediate space.
Velocity Flow Rate
• Point of Stagnation
• Point of Acceleration
• Point of Lowest Pressure
• Point of Separation
• Wake & Turbulence
Temperature Distribution
• Air Intake Temperature
• Air Exhaust Temperature
• Maximum Air Temperature
• Minimum Air Temperature
• Mean Air Temperature
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COMPARATIVE ANALYSIS
Simulations have been performed to understand how each double skin facade can be used to reduce cooling loads of the
building by minimizing thermal gains by providing a level of added performance. A comparative façade analysis can help this
understanding in identifying the most energy-efficient and effective façade type for the given application.
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COMPARATIVE ANALYSIS
The results show that any type of double skin wall performs better than the base model of a single skin double glazed façade. It
has been found that the addition of a second layer will reduce the models total cooling loads by 60% but it was the ability for the
system to maximize air flow throughout the system and drafting away surface gains is what made the difference.
0
1000
2000
3000
4000
5000
6000
7000
8000
Tota
l C
oo
lin
g (
kB
tu)
Base Model Scenario 1 Scenario 2 Scenario 3
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IV. CONCLUSION
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FINDINGS
Based on these results, recommendations for the design of double skin facades in Hawaii’s climates are:
Air cavity:
• Limiting the air cavity size reduces cooling loads by minimizing maximum air temperature. However, when external driving
forces are limited, a multi-story shaft cavity is needed to produce a pressure difference caused by thermal buoyancy
creating a stack effect.
Airflow types:
• Since majority of the commercial buildings consumed energy is utilized for cooling, there are possible advantages for
hybrid ventilation type. Diurnal changes between hot day temperatures and cool night temperatures could also be used,
where mechanical ventilation system could be used during the day and natural ventilation during the night. The thermal
behavior of double-skin facades is significantly affected by the airflow within the system. The flow of air towards, around
and within the assembly greatly affects the overall performance of the system.
Shading:
• Cavity shading devices can provide some protection against solar heat gain and incorporation of these elements within the
cavity is important to the efficiency of the system. All shading devices should be located closer to the external skin.
However, close attention should be placed on the design of cavity shading because if not designed properly, they could
create resistance and losses in airflow of the system and will cause an unwanted temperature increase. This relationship is
based on a case by case basis in order to obtain the necessary outcome.
Glazing:
• Effective window sizing and glazing types will have a significant impact on energy consumption. It is important to
understand the specifications when selecting an appropriate glazing type. This research has strictly focused on high
reflectance glass, however, low-e and high performance glazing may prove to be beneficial within this specific climate
context.
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FUTURE RESEARCH
It is necessary for the design approach to be comprehensive considering the faced as an integrated part of the building and
examined in great detail in order to determine all the parameters that will lead to a high performance solution.
Need Further Development:
• Development of advanced CFD techniques used to validate and predict the physical properties of the cavity more
accurately.
• Mock up testing of proposed solutions and feedback from real buildings.
• Comparison with external shading device on single skin façade.
• Research on the possibility of multi-layered façade systems
• Prediction of energy use for entire building
• Study application
Design objectives for any façade type are to provide thermal, visual and acoustical performance with minimum energy
consumption. Since there are numerous combinations between façade types, ventilation strategies as well as system
components, context based design that adapts to local environment conditions is of primary importance.
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The fundamental premises are that by designing the building’s facade to task the environmental
control, one can achieve better comfort and efficiency (without operating HVAC systems
unnecessarily) for any climate with a well-balanced integrated system rather than a detached
curtain. Because of the continuous fluctuations of all environmental factors across time, the
building façade must be understood not as a simple barrier but rather a selective, permeable
membrane with the capacity to admit, filter and/or reject any of these environmental factors.
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DISCUSSION