Tuesday, May 3, 2011


UNREINFORCED BRICK MASONRY CONSTRUCTION


Bricks were first fired around 3500 BC, in Mesopotamia, present-day Iraq, one of the 
high-risk seismic areas of the world. The ziggurat temples at Eridu, possibly the world’s 
first city, have withstood not only earthquakes but also wars and invasions. From Roman 
aqueducts and public buildings to the Great Wall of China, from the domes of Islamic 
architecture to the early railway arch bridges, from the first 19thcentury American tall buildings to the 20th century nuclear power plants, bricks have been used as structural material in all applications of building and civil engineering. 
The most common place for  use of bricks worldwide throughout time is in residential 
dwellings. The shape and size of bricks can vary considerably, and similarly the mortars 
used depend on local material availability, but the basic form of construction for houses 
has minor geographical variations and has changed relatively little over time.
The worst death toll from an earthquake in the past century occurred in 1976 in China 
(T’ang Shan Province), where it is estimated that 240,000 people were killed. Most of the 
deaths were due to the collapse of brick masonry buildings




simple figure of brick masonry

Sunday, May 1, 2011


video of construction of building


civil Engineering: Better Bridges Civil Engineers Test New Concrete...

civil Engineering:

Better Bridges
Civil Engineers Test New Concrete...
: "Better Bridges Civil Engineers Test New Concrete for Stronger, More Durable Bridges A new kind of concrete called Ductal will allow b..."


Better Bridges


Civil Engineers Test New Concrete for Stronger, More Durable Bridges

 A new kind of concrete called Ductal will allow bridges to hold more weight and last longer. Made of a mixture of sand, cement, water, and small steel fibers, it is 10 times more expensive than traditional materials but also stronger and virtually impermeable, helping bridges become more durable.

AMES, Iowa--Bridges take a beating, and it can really break the bank to repair them. Now, researchers are breaking bridges to learn how to build them better and save you money.
Justin Doornink spends his mornings underneath bridges. He's an engineering student and, as part of his homework, he's installing sensors to measure the impact of traffic on the bridge. He's trying to figure out how to strengthen the structures. One option is ultra-high-performance concrete, which is made from sand, cement, water and small steel fibers.
Brent Phares, a civil engineer and associate director at the Iowa State University Bridge Engineering Center in Ames, says, "It's much, much stronger. It's basically impermeable to water. What those two things mean is you can build a bridge that has a higher capacity and should last a longer period of time."
Brent did a small-scale test with the new concrete, pushing it to its breaking point. It held close to 595,000 pounds -- that's more than seven semi trucks. The material costs 10-times as much as traditional concrete, but you need less of it, and it lasts longer.
"You're never going to advance the state-of-the-art unless you do some research, try some things out, maybe take some risks and see what might ultimately save the taxpayers money," he says.
BACKGROUND: Engineers at Iowa State University have developed a new type of concrete that is much stronger than conventional concrete. It can withstand pressures up to 595,000 pounds -- more than the weight of seven semi trucks.
 LOAD-BEARING BRIDGES: The researchers conducted a load-bearing capacity test using a 71-foot beam made out the new concrete. They applied increasing amounts of hydraulic pressure to the top of the beam to see how much it could withstand before breaking. It finally broke with a loud pop at 595,000 pounds. The ultra-high performance concrete is made from sand, cement, water and small steel fibers. Standard concrete uses coarser materials. The new concrete is specifically engineered to include finer materials and steel fibers, making it denser and stronger.
WHY THE BEAM BROKE: Isaac Newton said it best: for every action there is an equal and opposite reaction. As the hydraulic pressure on the beam increases, the beam responds by exerting an equal but opposite counter-force. But it doesn't do so uniformly: certain areas bear the brunt of the increasing pressure. This produces a strain on the beam, which eventually becomes too great, and the beam cracks.
DIFFERENT DEFORMATIONS: Different materials can withstand different amounts of deformation, a property known as elasticity. Most materials are elastic to some degree: when they are deformed or bent, they will bounce back to their original shape. But elastic materials all have their limits. Metal springs and rubber bands are very elastic. Plaster and glass are not; instead, they are brittle and snap even with a small deformation

Thursday, April 14, 2011

Earthquake Resistant Structure of Japanese Houses

Damage building in Japan due to earth quake
Taking Experiment on earthquake absorption







 - Why earthquake resistant houses in Japan?


Earthquake-Resistant Design
"Earthquake-resistant" conceptDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı design of a structure in accordance with regulations in force in the mind of earthquakeDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı compliance with and enforcement of regulation is reminiscent of the calculation, and often atDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı is thought to guarantee safety against earthquakes. However, the truth of this and similar comments sınandığındaDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı partially valid (ZacekDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı 2000a).
The purpose of the regulations is to prevent earthquake damage to structuresDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı to prevent loss of life. A large earthquake in a large amount of structure may be damaged structural and non structuralDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı but as long as the building yıkılmadığıDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı the objectives of the regulations is considered to be reached (Arnold et al.Depreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı 1982).
ThereforeDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı United StatesDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı JapanDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı Always improving the earthquake codes, such as ItalyDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı laws and regulations are applied rigorouslyDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı is above a certain level of quality of materials and applications, even in countriesDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı due to defects in the design of earthquake damage is often seen .
  1995 Kobe Earthquake stiffness irregularity between adjacent layers of the first and third floors of a building collapse completely. Kobe earthquake, depending on the effect of soft layer completely, especially the demolition of the ground floors were quite common.

 Figure 2 1994 NorthridgeDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı California EarthquakeDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı ground floor of an apartment building because of the collapse of the soft layer (Niseehttp: / / nisee.berkeley.edu / images / servlet / EqiisDetail? file \u003d NR328)
AlgeriaDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı Wang, conducting studies on earthquake damage to the U.S. and JapanDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı His observations on the damaged structures in CaliforniaDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı architectural design decisionsDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı damage to some buildingsDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı According to other design decisions clearly concluded that the decisive (CharlesonDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı 1995).
Earthquake-resistant architectural design plays an important role at least until the regulations are applied.
Earthquake-resistant architectural designDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı in the design and implementation, and ground effects (topographyDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı ground, etc.)Depreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı biçimlenmesinin appropriate structureDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı choice of structural systemDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı biçimlendirilmesinin structural detailsDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı addressing of the design process.
Lessons learned from the devastating earthquakesDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı the same importance for the design of earthquake resistant structures, and at the same time reveals the necessity of bringing together the three basic conditions.
a. Earthquake-resistant architectural design
b. Law and Regulatory Compliance
c. Qualified materialDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı implementation and auditing
Faulty and incomplete design decisions in terms of architectural designDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı particular resonanceDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı torsionDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı stress concentrations on the different oscillationsDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı some parts of the weakening of the structure under earthquake loads (soft coat effect)Depreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı seismic loads on the concentration of some elements (short-column effect and so on.) depending on such factors can cause devastating damage (ZacekDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı

  Likely due to faulty design decisions in terms of architectural design and missing causes of damage and destruction (ZacekDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı 2000b)
ArchitectDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı according to professionDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı responsible for carrying out all kinds of buildings that provides safety and comfort requirements. A building's earthquake resistance calculations only with the appropriate regulations for sağlanamayacağıDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı designDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı regulations should be to eliminate the negative features at the same time.
Carrier system is very well-calculatedDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı earthquake behavior of a structure with irregular structural system, butDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı carrier system is roughly calculatedDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı carrier system, but rather a more regular behavior of a structure which is negative. Carrier system is well regulated in the earthquake behavior of a structure is not possible to increase the account (Steel et al.Depreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı 2000).
ThereforeDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı in the process of earthquake-resistant designDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı architectural design decisions at least until the implementation of laws and regulations, positive or negative effects on the behavior of structures during earthquakesDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı is of vital importance.
This is primarily importantDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı greatly affect the performance of the building during the earthquake and the architect is to be decided by the architectural design stage of the process of building geometry sketchDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklıcarrier selection and carrier system critical and fundamental decisions, such as the system depends on the behavior under seismic loads.
In particular the scale of design workshopsDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı This awareness is necessary to give the students nominated architect. The complexity of current regulations and their design and the possibility it may cause many problems in practiceDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı earthquake-resistant architectural design of this complexity so as to preventDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı requires special training be given to the process of design studios.
Report of the National Earthquake Council, dated May 6, 2002Depreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı Earthquake-resistant design and implementation successDepreme Dayanıklı Japon Evlerinin Yapısı - Japonyadaki evler neden depreme Dayanıklı of professionals and technical staff operating in this area due to the improvement of university education is emphasized.