Advanced Construction Systems PDF

Summary

These lecture notes cover advanced construction systems, their impact on architectural space, and different types of building constructions. The course delves into aspects like building envelopes, various structural systems, and the relationship between building loads and construction systems.

Full Transcript

ADVANCED CONSTRUCTION
SYSTEMS
‫نظم انشاءات متقدمة‬

Dr. Mais AL-Ruwaishedi

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
INTRODUCTION 2
Course disceptation
This course presents creative structural systems and their impact on
architectural space in terms of ideas, meanings, and integration in
building construction. It also explains parts of modern structural
frameworks by studying surface and linear configurations: beam,
column, and various trusses systems (spatial, Vierendeel, and multi-
sided frameworks), planar spatial structures, box structures with vertical
and horizontal slabs, curved shell structures (double and single
curvature), tensile membranes, and inflatable structures. Additionally, it
covers the development of prefabricated buildings, their construction
methods, and their coordination.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 LECTURE (1)
OUTLINE

Advanced Construction systems definition

Overview of creative structural systems and their

impact on architectural space

Building envelope

Types of buildings in terms of construction method

and systems

Relationship Between building Loads and

Construction system

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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ADVANCED STRUCTURAL SYSTEMS
Advanced building technology defined as the development of traditional
construction methods by incorporating modern construction technology.

The need for advanced structural systems and their application requirements:
The need for advanced structural systems is driven by the need to expand vertical
architecture and cover large spaces to meet contemporary requirements and the
technological development that aligns with modern human needs.

Why should an architect be knowledgeable about structural systems?

The architect must choose a system that aligns with the architectural concept and
the project's function and concept.
For example, in the case of theaters, large spaces without columns are needed;
hence, knowing the structural system is essential to determine the appropriate
type that does not conflict with the architectural concept.
The architectural design will specify the structural engineer's work by identifying
any type of system that may conflict with the architectural idea.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 WHAT IS THE DIFFERENCE BETWEEN 5

ARCHITECTURAL AND STRUCTURAL
DESIGN?
ARCHITECTURAL:
The architectural engineer defines the shape of the building, the interior layout, and the
required spaces and heights.
When choosing the structural system, it must fit the idea and it is preferable for
architects to have sufficient information about this system and its implications, as it
facilitates the construction process.
STRUCTURAL:
The structural engineer determines the placement of the columns and distances
between them, as well as the structural loads.
Defines the diameters of the reinforcement bars used and their quantity based on load
calculations.
Shows the details of the structural connections and installation methods, which are to be
coordinated with the architectural elements.
Ensures the structural safety of the building and provides calculations based on the
actual loads it will bear.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 OVERVIEW OF CREATIVE STRUCTURAL SYSTEMS
6
AND THEIR IMPACT ON ARCHITECTURAL SPACE
Creative structural systems are innovative methods and technologies used in
construction to support buildings in a way that enhances both functionality and
aesthetics. These systems are designed to meet specific architectural needs,
often pushing the boundaries of traditional construction to create more versatile
and expressive spaces.
Impact on Architectural Space
1. Aesthetic Appeal:
1. Creative structural systems often result in visually striking designs.
2. They allow architects to explore unique forms and complex geometries that
traditional methods cannot achieve.
3. Examples include iconic buildings like the Sydney Opera House and the Beijing
National Stadium (Bird's Nest).
2. Functional Versatility:
1. These systems enable the creation of large, unobstructed spaces that enhance
usability.
2. They are particularly beneficial in public buildings, sports arenas, and exhibition halls
where open space is critical.
3. Flexible design options allow for multi-functional spaces that can adapt to different
uses over time.
Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
OVERVIEW OF CREATIVE STRUCTURAL SYSTEMS
7
AND THEIR IMPACT ON ARCHITECTURAL SPACE
Impact on Architectural Space

3. Environmental Efficiency:

Many innovative structural systems are designed with sustainability in mind.
They often use fewer materials and reduce waste, lowering the environmental impact.
Structures like geodesic domes and tensile systems can incorporate natural ventilation
and lighting, reducing energy consumption.

4.Structural Integrity:

Advanced engineering ensures that creative structural systems are robust and resilient.
They can withstand environmental stresses such as wind, earthquakes, and heavy
loads.
This reliability allows for safer, longer-lasting buildings.

5. Economic Considerations:
While some creative systems may have higher initial costs, they often offer long-term
savings.
Reduced material use, faster construction times, and lower maintenance costs
contribute to overall economic efficiency.
Innovative designs can also enhance property value and attract tourism and business.
Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 BUILDING ENVELOPE 8

Building envelope definition: The building envelope, also known as the building
enclosure, is the physical barrier between the interior and exterior of a building. It includes
all components that separate the internal environment from the external environment, such
as walls, roofs, floors, windows, doors, and insulation.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 BUILDING ENVELOPE 9

The building envelope consists of several key components that work together to protect the interior of
the building from external elements and ensure energy efficiency, comfort, and structural integrity. The
main parts of the building envelope include:

Roof:
Protects the building from weather elements like rain, snow, and sunlight.
Includes materials such as shingles, tiles, metal panels, and waterproof membranes.
May also include insulation, ventilation, and drainage systems.
Walls:
Serve as the primary barrier between the interior and exterior environments.
Composed of structural elements (like framing), exterior cladding (such as brick, siding, or stucco),
insulation, vapor barriers, and interior finishes.
Windows:
Allow natural light into the building and provide views to the outside.
Should be energy-efficient, often featuring double or triple glazing, low-emissivity coatings, and
gas fills between panes.
Include frames that contribute to the thermal performance and air tightness of the building.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 BUILDING ENVELOPE 10

Doors:
Provide entry and exit points while maintaining the integrity of the building envelope.
Should be well-insulated and weather-sealed to prevent air and moisture infiltration.
Include various types such as exterior doors, sliding doors, and garage doors.

Foundation:
Supports the building and transfers loads to the ground.
Includes components such as footings, slabs, basement walls, and insulation.
Must be designed to prevent moisture ingress and provide thermal insulation.

Floors:
Separate different levels within the building and can include elements like slabs, joists, subflooring,
and floor finishes.
Often include insulation and vapor barriers to enhance energy efficiency and comfort.

Insulation:
Reduces heat transfer through the building envelope, improving energy efficiency and indoor
comfort.
Can be installed in walls, roofs, floors, and foundations.
Includes materials such as fiberglass, foam, cellulose, and reflective barriers
Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 BUILDING ENVELOPE 11

Vapor and Air Barriers:
1. Prevent the movement of moisture and air through the building envelope.
2. Vapor barriers are typically installed on the warm side of the insulation to prevent
condensation.
3. Air barriers are designed to stop air leakage and can be incorporated into various
components of the envelope.

Cladding and Exterior Finishes:
1. Provide the outermost layer of the building envelope, protecting against weather and
providing aesthetic appeal.
2. Include materials like brick, stone, stucco, wood, metal, and synthetic panels.

Each of these components must be carefully designed, installed, and maintained to ensure the
overall performance of the building envelope, including its energy efficiency, durability, and
ability to provide a comfortable indoor environment

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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EXAMPLES AND CASE STUDIES

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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EXAMPLES AND CASE STUDIES

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 14

CONSTRUCTION METHOD AND SYSTEMS
Buildings can be categorized by their construction methods and systems, which influence
their structural integrity, energy efficiency, cost, and construction speed. Here are some
common types:
1. Traditional Stick-Built Construction:

Definition: Involves assembling the building on-

site using individual pieces of lumber (sticks).

Characteristics: Flexibility in design, labor-

intensive, longer construction time.

Examples: Single-family homes, small

commercial buildings.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 15

CONSTRUCTION METHOD AND SYSTEMS

2. Modular Construction:
Definition: Buildings are constructed off-site in sections or

modules, which are then transported and assembled on-site.

Characteristics: Faster construction time, reduced waste,

high quality control.

Examples: Prefabricated homes, temporary buildings, some

schools, and offices.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 16

CONSTRUCTION METHOD AND SYSTEMS

3. Panelized Construction:
Definition: Prefabricated panels (such as walls and

floors) are manufactured off-site and assembled on-site.

Characteristics: Quick assembly, reduced labor costs,

improved quality control.

Examples: Residential homes, commercial buildings

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 17

CONSTRUCTION METHOD AND SYSTEMS

4. Steel Frame Construction:
Definition: Uses a steel framework to support
the building instead of wood or concrete.
Characteristics: Strong, durable, flexible
design, suitable for high-rise buildings.
Examples: Skyscrapers, industrial buildings,
large commercial structures

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 18

CONSTRUCTION METHOD AND SYSTEMS

5. Concrete Construction:
Definition: Involves the use of concrete as the
primary structural material, often reinforced with steel.
Characteristics: Durable, fire-resistant, suitable for
heavy loads and large spans.
Examples: Parking structures, bridges, large
residential and commercial buildings.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 19

CONSTRUCTION METHOD AND SYSTEMS

6. Masonry Construction:
Definition: Uses individual units (such as bricks,
stones, or concrete blocks) bound together with
mortar.
Characteristics: Durable, fire-resistant, good
thermal mass.
Examples: Historical buildings, schools, commercial
buildings.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 20

CONSTRUCTION METHOD AND SYSTEMS

7. Timber Frame Construction:
Definition: Uses large wooden beams and columns
as the primary structural elements.
Characteristics: Aesthetic appeal, strong and
flexible, eco-friendly.
Examples: Custom homes, barns, some commercial
buildings.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 21

CONSTRUCTION METHOD AND SYSTEMS

8. Glass and Curtain Wall Construction
Definition: Uses glass and lightweight aluminum or
steel frames to create the building envelope.
Characteristics: Modern aesthetic, allows for
natural light, energy-efficient glazing options.
Examples: High-rise office buildings, luxury hotels,
and modern commercial buildings in urban centers.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 22

CONSTRUCTION METHOD AND SYSTEMS

9. Hybrid Construction:
Definition: Combines elements from different
construction methods to optimize performance
and cost.
Characteristics: Versatile, can leverage the
benefits of multiple systems.
Examples: Mixed-use developments, complex
commercial projects.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 23

CONSTRUCTION METHOD AND SYSTEMS
10. Insulated Concrete Form (ICF) Construction:
Definition: Uses insulated concrete forms that stay in place as
permanent building insulation for cast-in-place concrete walls.
Insulated Concrete Form (ICF) is a construction system that
uses hollow blocks or panels made of rigid insulating foam,
typically expanded polystyrene (EPS), which are stacked to
create the formwork for concrete walls. The forms are then
filled with reinforced concrete, creating a strong, energy-
efficient, and durable structure.
Characteristics: Energy-efficient, strong, and durable.
Examples: Residential homes, commercial buildings, safe
rooms.
Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
 TYPES OF BUILDINGS IN TERMS OF 24

CONSTRUCTION METHOD AND SYSTEMS
11. 3D Printing Construction:
Definition: Utilizes 3D printing technology to create
building components or entire structures.
Characteristics: Innovative, rapid construction, potential
for complex designs.
Examples: Experimental housing projects, emergency
shelters.
Each construction method and system has its advantages and
is chosen based on factors like project size, budget, location,
environmental considerations, and specific building
requirements.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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HOW WE CAN CHOSE A SPECIFIC CONSTRUCTION
SYSTEM ?
Choosing a specific construction method in building architecture is influenced by various
factors that consider the overall project goals, site conditions, and desired outcomes. Here are
some key reasons for selecting a particular construction method:
1. Cost and Budget
Affordability: Traditional methods like stone masonry or mud brick construction can be more affordable
in areas with abundant local materials.
Cost Efficiency: Prefabricated and modular construction can reduce labor costs and construction
time, making them cost-effective for many projects.
2. Construction Speed
Time Constraints: Prefabricated, modular, and steel frame construction methods are often chosen for
projects with tight deadlines due to their faster assembly times.
Project Urgency: Temporary structures or emergency shelters may use rapid construction methods
like prefabrication or 3D printing.
Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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HOW WE CAN CHOSE A SPECIFIC CONSTRUCTION
SYSTEM ?
3. Design Flexibility
Architectural Style: Steel frame and reinforced concrete construction offer high design
flexibility, allowing for innovative architectural styles and large open spaces.
Cultural and Aesthetic Considerations: Traditional Islamic architecture or vernacular styles
are chosen to reflect cultural heritage and local aesthetics.
4. Sustainability and Environmental Impact
Energy Efficiency: Methods like insulated concrete forms (ICF) and green building
techniques are selected for their energy efficiency and reduced environmental footprint.
Use of Sustainable Materials: Choosing methods that utilize renewable or locally sourced
materials, such as timber frame or earth construction, supports sustainability goals.

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HOW WE CAN CHOSE A SPECIFIC CONSTRUCTION
SYSTEM ?
5. Local Regulations and Building Codes
Compliance: Construction methods must comply with local building codes and regulations,
which can influence the choice based on safety standards and legal requirements.
Zoning Laws: Zoning laws and land use regulations can also dictate specific construction
methods suitable for certain areas.
6. Availability of Materials and Labor
Local Materials: The availability of local materials can drive the choice of construction method,
such as using adobe in regions with abundant clay.
Skilled Labor: The availability of skilled labor for certain construction techniques can influence
the method chosen. For instance, regions with skilled masons may prefer stone masonry.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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HOW WE CAN CHOSE A SPECIFIC CONSTRUCTION
SYSTEM ?
7. Structural Requirements
Load-Bearing Capacity: Reinforced concrete and steel frame construction are chosen for
buildings that require high load-bearing capacity, such as skyscrapers and large commercial
buildings.
Durability: Methods like stone masonry and reinforced concrete are selected for their long-term
durability and resistance to wear and tear.
8. Maintenance and Longevity
Ease of Maintenance: Methods that require less maintenance over time, such as reinforced
concrete, may be preferred for their long-term benefits.
Building Lifespan: Construction methods that ensure a longer lifespan and lower lifecycle costs,
such as steel frame or reinforced concrete, are often selected for permanent structures.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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HOW WE CAN CHOSE A SPECIFIC CONSTRUCTION
SYSTEM ?
9. Project Type and Function
Residential vs. Commercial: Different methods may be more suitable for residential versus
commercial projects based on specific functional requirements.
Specialized Uses: Certain projects, like hospitals or educational facilities, may require specific
construction methods to meet functional and regulatory requirements.
10. Aesthetic and Cultural Preferences
Aesthetic Goals: The desired aesthetic of the building can significantly influence the choice of
construction method. For example, traditional styles might be chosen to preserve cultural heritage.
Cultural Significance: In some regions, traditional construction methods are preferred to
maintain cultural significance and continuity.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
In building construction, understanding the types of loads that a structure will encounter is crucial for
selecting the appropriate construction method or system. Building loads can be broadly categorized into
static and dynamic loads, each affecting the structural integrity and performance of a building. Here’s an
overview of these loads and how they influence the choice of construction methods or systems:

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
Types of Building Loads
Static Loads (Dead and Live Loads)
1.Dead Loads:
1. Definition: The permanent, stationary loads that are constantly present in a structure. These
include the weight of the building materials, structural components, and any permanently
attached fixtures.
2. Examples: Walls, floors, roofs, beams, columns, and other permanent elements.
3. Impact on Construction Method: Construction methods must ensure that materials and
structures can support these constant loads without excessive stress or deformation. Methods like
reinforced concrete and steel frame construction are often used to handle substantial dead loads.

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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
2. Live Loads:
Definition: Temporary or movable loads that a structure must support. These
loads can change over time and include the weight of people, furniture, and
equipment.
Examples: Occupants, furniture, appliances, and vehicles (in parking structures).
Impact on Construction Method: Construction methods need to accommodate
variability and ensure that the structure can handle different load scenarios.
Modular construction and steel frame systems can be designed to adapt to varying
live loads.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM

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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
2. Dynamic Loads
1.Wind Loads:
1. Definition: Forces exerted by wind pressure on the building's surface.
2. Impact on Construction Method: Buildings in windy areas or high-rise structures must be designed
to withstand significant wind forces. Steel frame and reinforced concrete methods are often used for
their strength and flexibility. Aerodynamic shapes and bracing systems are also incorporated.
2.Seismic Loads:
1. Definition: Forces generated by earthquakes, causing ground shaking and movement.
2. Impact on Construction Method: In seismic-prone areas, buildings must be designed for flexibility
and energy dissipation. Reinforced concrete, steel frame, and hybrid systems with base isolators or
dampers are commonly used to enhance seismic performance

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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
3. Snow and Ice Loads:
Definition: The weight of accumulated snow and ice on the roof and other surfaces.
Impact on Construction Method: Roof design and materials must be chosen to handle these
loads. Sloped roofs and reinforced materials are often used in regions with heavy snowfall. Wood
and steel trusses are designed to support the extra weight.
4. Vibration Loads:
Definition: Loads caused by machinery, traffic, or other sources of vibration.
Impact on Construction Method: Industrial buildings or structures near sources of vibration need
to mitigate these effects. Vibration isolation techniques and reinforced concrete are commonly used
to absorb and dissipate vibrations.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
5. Impact Loads:
Definition: Sudden forces exerted by objects striking the building.
Impact on Construction Method: Materials and design must account for
potential impacts. Reinforced concrete and steel are preferred for their ability
to withstand sudden shocks and distribute forces.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM

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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM

SO the Relationship Between Loads and Construction Methods
1.Material Selection:
1. Steel: Chosen for its high strength-to-weight ratio, flexibility, and ability to withstand
dynamic loads such as wind and seismic forces.
2. Reinforced Concrete: Preferred for its compressive strength, durability, and excellent
performance under static and dynamic loads.
3. Timber: Used for its natural aesthetic and ability to handle moderate loads, often in
residential or low-rise buildings.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
2. Structural Systems:
Frame Systems (Steel or Concrete): Offer flexibility and strength, ideal for high-rise buildings and
areas with high wind or seismic activity.
Load-Bearing Walls: Suitable for low to mid-rise buildings where loads are evenly distributed.
3. Design Considerations:
Load Distribution: Ensuring even distribution of loads to prevent localized stress and potential failure.
Redundancy and Safety Factors: Incorporating safety margins to handle unexpected loads or
conditions.
Dynamic Response: Designing for flexibility and energy absorption to handle dynamic loads
effectively.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
Foundation Systems:
Deep Foundations: Used in areas with poor soil conditions or for structures with heavy loads,
providing stability and load distribution.
Shallow Foundations: Suitable for lighter structures with stable soil conditions

In summary, understanding the types and magnitudes of static and dynamic loads is essential
for selecting the appropriate construction method. The choice ensures that the building remains
safe, durable, and functional under various load conditions

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
EXAMPLES:

High-Rise Buildings:
Method: Steel frame or
reinforced concrete.
Reason: High strength and
flexibility to handle wind and
seismic loads.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
EXAMPLES:

Residential Homes:
Method: Masonry Construction or
Wood frame or modular construction.
Reason: Adequate for moderate
dead and live loads, cost-effective,
and quicker construction.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
EXAMPLES:

Industrial Buildings:
Method: Precast concrete or steel frame.
Reason: Ability to support heavy equipment and
handle dynamic loads from machinery

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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
EXAMPLES:

Bridges:
Method: Steel or
reinforced concrete.
Reason: High load-bearing
capacity and ability to
withstand dynamic forces
like traffic and wind.

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM

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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM

To design safe and efficient buildings,
understanding how different forces and loads
affect the structure is crucial. Here are some
common forces and loads, along with examples
and how they relate to selecting appropriate
structural systems:

Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
1. Compression
Description: Compression is a force that squeezes or compresses a
material, shortening it.
Examples:
Columns: In a building, columns are vertical structural elements that
primarily experience compressive forces. The weight of the floors, roof,
and any live loads above compresses the columns.
Load-bearing walls: These walls support the weight of the roof and
upper floors, transmitting compressive forces down to the foundation.
Relation to Structural Systems:
Material Selection: Materials with high compressive strength, such
as concrete and masonry, are preferred for columns and load-bearing
walls.
Structural Design: The cross-sectional area of columns is designed
to safely carry the expected compressive loads without buckling.
Reinforced concrete or steel columns may be used in taller buildings
to handle greater loads.
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
2. Tension
Description: Tension is a force that stretches or pulls a material,
lengthening it.
Examples:
Cables in suspension bridges: The cables in a suspension bridge
experience tensile forces as they support the weight of the bridge deck
and the vehicles on it.
Steel reinforcement in concrete: In reinforced concrete structures,
steel rebars are placed in regions where tensile forces are expected,
such as the bottom of a simply supported beam.
Relation to Structural Systems:
Material Selection: Materials with high tensile strength, such as
steel, are used for elements expected to experience tension.
Structural Design: In reinforced concrete, steel rebars are
strategically placed to resist tensile forces. In cable-supported
structures, high-strength steel cables or tendons are used.
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM

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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
3. Shear
Description: Shear forces act parallel to the surface, causing one
part of a material to slide past another.
Examples:
Shear walls: In a building, shear walls resist lateral forces from
wind or earthquakes, preventing the structure from swaying
excessively.
Beam connections: The connections between beams and
columns experience shear forces, especially during lateral loads
like earthquakes.
Relation to Structural Systems:
Material Selection: Materials with good shear strength,
such as reinforced concrete and steel, are used.
Structural Design: Shear walls are designed to have
sufficient thickness and reinforcement to resist shear forces.
Beam-column connections are designed to transfer shear
forces safely.
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RELATIONSHIP BETWEEN BUILDING LOADS
AND CONSTRUCTION SYSTEM
5. Torsion
Description: Torsion is a twisting force that causes a
material to rotate around its axis.
Examples:
Spiral staircases: The central support column of a spiral
staircase experiences torsion as the stairs twist around it.
Rotational loads: Elements like beams can experience
torsion if loads are not applied symmetrically.

Relation to Structural Systems:
Material Selection: Materials like steel, which have
good torsional strength, are preferred.
Structural Design: Structural elements subjected to
torsion are designed with cross-sections that resist
twisting, such as circular or hollow sections

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LECTURE (2)
OUTLINE
Walls
Generic wall types
Trends in facade design
Metal systems
o Sheet metal
o Profiled cladding
o Composite panels
o Rainscreens
Al-Balqa Applied University / Architecture department / Dr. Mais Al-Ruwaishedi