HP Pavilion DV7-2020EO battery - 7800mAh,14.8V

PRLog (Press Release) – Jul 25, 2011 – Buy this battery at  http://www.hplaptopbattery.com.au/hp-pavilion-dv7-2020eo-battery.htm

This brand new replacement HP Pavilion DV7-2020EO battery is made with high quality cells from Samsung. Our replacement battery for HP Pavilion DV7-2020EO is 100% compatible and meet or exceeds original battery performance.

Buy this battery at  http://www.hplaptopbattery.com.au/hp-pavilion-dv7-2020eo ...

These brand new 14.8V, 7800mAh(12 cell) & 5200mAh(8 cell) replacement HP Pavilion DV7-2020EO batteries are made with high quality cells from Samsung. All our Li-Ion replacement batteries for HP Pavilion DV7-2020EO have been tested and proven to match and/or exceed original Pavilion DV7-2020EO battery performance and are 100% compatible Original Manufacturer Specifications. Every piece HP Pavilion DV7-2020EO battery has been tested on HP systems to ensure the safety for your HP laptop. This high quality replacement HP Pavilion DV7-2020EO laptop battery is designed with highest control standards, have internal circuit boards with smart chips ( Cell imbalance shut off protection, Thermal runaway protection, Overcharge shut off protection, Over discharge shut off protection, High/low temperature shut off protection ), and produced by eco-friendly materials without lead or mercury. Every HP Pavilion DV7-2020EO batteries have Certified by CE, UL, ROHS, ISO9001/9002 and passed through strict safety testing. Long lasting, this extend 12 Cells HP Pavilion DV7-2020EO battery can be charged/discharged 600-800 cycles. Thank you shopping HP Pavilion DV7-2020EO battery at HPLaptopBattery.com.au, before placing an order please to make sure the model(or part number) of this HP Pavilion DV7-2020EO battery can fit well with your HP laptop. Each battery has its model name(or part number,P/N) which you can find them on your original HP Pavilion DV7-2020EO battery. If your information cannot match the model name or compatible part No.. Please tell us the part number of your original battery or the exact name of your machine, we will recommend you the right battery. HP Pavilion DV7-2020EO laptop battery compatibles Part Number List

   464058-121    464058-141    464058-161    464058-251    464058-361    464058-362    464059-001    464059-121    464059-122    464059-141    464059-142    464059-161    464059-221    464059-222    464059-251    464059-252    464059-361    464059-362    4644059-121    4644059-141    480385-001    481194-B21    486766-001    497705-001    509422-001    516354-001    516355-001    534116-291    DYNA-CHA-LOC    GA04    GA06    GA06047    GA08    GA08073    HP7028LH    HSTNN-C50C    HSTNN-DB74    HSTNN-DB75    HSTNN-IB74    HSTNN-IB75    HSTNN-OB74    HSTNN-OB75    HSTNN-Q35C& my photo and wallpaper #13;    HSTNN-XB75    KS525AA    KS525AA#ABA    NBP6A95    NH494AA � oled technology on mobile phone �  NH494AA#ABA

Buy this battery at  http://www.hplaptopbattery.com.au/hp-pavilion-dv7-2020eo-battery.htm

HP Pavilion DV7-2020EO laptop battery fits Model List

   Pavilion dv7    Pavilion dv7-2020eb    Pavilion dv7-2020ef    Pavilion dv7-2020ek    Pavilion dv7-2020eo    Pavilion dv7-2020es    Pavilion dv7-2020ev    Pavilion dv7-2020tx    Pavilion dv7-2020x    Pavilion dv7-2021tx    Pavilion dv7-2021x    Pavilion dv7-2022eg    Pavilion dv7-2022tx    Pavilion dv7-2023eg    Pavilion dv7-2025ef    Pavilion dv7-2025eg    Pavilion dv7-2025eo    Pavilion dv7-2025es    Pavilion dv7-2027eo

Get automobile news and garbage compactor

Bright Prospectives for Computer Scientists in High Performance Computing

PRLog (Press Release) – Jul 22, 2011 – Supercomputers contribute significantly to the oil, automobile, aerospace, and chemical and pharmaceutical industries' ability to solve complex problems.They enable companies within these industries to design new and better products in less time, and to simulate product tests that would have been impossible without spending months developing and experimenting with expensive product models. Some companies have attributed significant cost savings to the use oled technology on mobile phone of supercomputers. For example, although exact figures were not always available, representatives of some automobile and aerospace companies estimated that millions of dollars have been saved on specific models or vehicle parts because of reduced manufacturing or testing costs. In addition, one oil company representative estimated that over the last 10 years, supercomputer use has resulted in increased production of oil worth between $6 billion and $10 billion from two of the largest U.S.oil fields.

Analysts of Market Research Media project the global defense high performance computing market to increase from $2.6 billion in 2010 to $3.3 billion in 2015. The estimate for worldwide cumulative market 2010 – 2015 is $18 billion, for a compound annual growth rate (CAGR) of 4.7% in the 6-year period.

Job market analysts from JobOutlook.info have graded supercomputing field as a highly promising career pathway for computer scientists.

The following industries will be top employers of computer science professionals with specialization in high performance computing:

Oil Industry – As an early user of supercomputers, the oil industry has realized substantial benefits from supercomputer applications. By using two key applications for processing seismic data3 and simulating reservoirs, oil companies have improved their ability to determine the location of reservoirs and to maximize recovery of oil and gas from those reservoirs. This ability has become increasingly important because of the low probability of discovering large oil fields in the continental U.S. New oil fields are often small and located in harsh environments, making exploration and production difficult. Several industry representatives estimated that the use of supercomputers reduces the number of dry wells drilled (at a cost of $5 million to over $50 million per well) by about 10 percent.

Aerospace & Defense Industry – Engineers and researchers in the aerospace & defense industry use super-computers to design, de my photo and wallpaper velop, and test aerospace vehicles and related components. Supercomputers, for example, have enabled engineers to analyze aircraft structural composition for design flaws and to simulate their performance in wind tunnels. This ability is important because wind tunnels are expensive to build and maintain, and cannot reliably detect certain airflow phenomena. Simulation permits a reduction in physical model testing, and substantial savings in time and money.

Automobile Industry – Automobile manufacturers increasingly rely on supercomputers to design vehicles that are safer, lighter, more economical, and better built. A primary supercomputer application-crash analysis is used to simulate how vehicle structures collapse on impact and how fast passengers move forward. These simulations provide more precise engineering information than was possible from physically crashing pre-prototype vehicles. They also reduce the number of vehicles required for these tests by about 20 to 30 percent.

Chemical and Pharmaceutical Industries – from computer assisted molecular design to synthetic materials research, biotech companies increasingly rely on supercomputers to study critical design parameters and more quickly and accurately interpret and refine experimental results.

Media partners:

http://www.computerscience.org http://www.com puterscientist.org http://www.joboutlook.info

Get automobile news and garbage compactor

Bright Prospectives for Computer Scientists in High Performance Computing

PRLog (Press Release) – Jul 22, 2011 – Supercomputers contribute significantly to the oil, automobile, aerospace, and chemical and pharmaceutical industries' ability to solve complex problems.They enable companies within these industries to design new and better products in less time, and to simulate product tests that would have been impossible without spending months developing and experimenting with expensive product models. Some companies have attributed significant cost savings to the use of supercomputers. For example, although exact figur my photo and wallpaper es were not always available, representatives of some automobile and aerospace companies estimated that millions of dollars have been saved on specific models or vehicle parts because of reduced manufacturing or testing costs. In addition, one oil company representative estimated that over the last 10 years, supercomputer use has resulted in increased production of oil worth between $6 billion and $10 billion from two of the largest U.S.oil fields.

Analysts of Market Research Media project the global defense high performance computing market to increase from $2.6 billion in 2010 to $3.3 billion in 2015. The estimate for worldwide cumulative market 2010 – 2015 is $18 billion, for a compound annual growth rate (CAGR) of 4.7% in the 6-year period.

Job market analysts from JobOutlook.info have graded supercomputing field as a highly promising career pathway for computer scientists.

The following industries will be top employers of computer science professionals with specialization in high performance computing:

Oil Industry – As an early user of supercomputers, the oil industry has realized substantial benefits from supercomputer applications. By using two key applications for processing seismic data3 and simulating reservoirs, oil companies have improved their ability to determine the location of reservoirs and to maximize recovery of oil and gas from those reservoirs. This ability has become increasingly important because of the low probability of discovering large oil fields in the continental U.S. New oil fields are often small and located in harsh environments, making exploration and production difficult. Several industry representatives estimated that the use of supercomputers reduces the number of dry wells drilled (at a cost of $5 million to over $50 million per well) by about 10 percent.

Aerospace & Defense Industry – Engineers and researchers in the aerospace & defense industry use super-computers to design, develop, and test aerospace vehicles and related components. Supercomputers, for example, have enabled engineers to analyze aircraft structural composition for design flaws and to simulate their performance in wind tunnels. This ability is important because wind tunnels are expensive to build and maintain, and cannot reliably detect certain airflow phenomena. Simulation permits a reduction in physical model oled technology on mobile phone testing, and substantial savings in time and money.

Automobile Industry – Automobile manufacturers increasingly rely on supercomputers to design vehicles that are safer, lighter, more economical, and better built. A primary supercomputer application-crash analysis is used to simulate how vehicle structures collapse on impact and how fast passengers move forward. These simulations provide more precise engineering information than was possible from physically crashing pre-prototype vehicles. They also reduce the number of vehicles required for these tests by about 20 to 30 percent.

Chemical and Pharmaceutical Industries – from computer assisted molecular design to synthetic materials research, biotech companies increasingly rely on supercomputers to study critical design parameters and more quickly and accurately interpret and refine experimental results.

Media partners:

http://www.computerscience.org http://www.com puterscientist.org http://www.joboutlook.info

Get automobile news and garbage compactor

Dyna-Graphics’ New Folex Film for PCBs Provides Explosion & ESD Protection

PRLog (Press Release) – Jul 25, 2011 – Dyna-Graphics Corporation has begun integrating Folex GO-MA/2K ESD film in their graphic overlays for PCB membrane switches to provide protection against ESD and explosions.

Chaska, Minnesota-based Dyna-Graphics is an award-winning manufacturer of membrane switch panels, touch screen terminals, graphic overlays, and many other similar products. Their products are used in the agricultural, medical, and scientific industries, as well as many other applications. The inclusion of the new Folex film into their products is another of the technological innovations that have made the company an industry leader.

Folex GO-MA/2K ESD film is an "interesting new material we found in Europe that's not available in the United States [market] yet," said Ed Wulff, Vice President of Dyna-Graphics. "It has an embedded conductive surface," Wulff added, that makes it an ideal, explosion and ESD preventing safety measure in highly static- or electrically-conductive environments.

This new graphic overlay film contains rugged conductive particles in its decorative layer which dissipate static and electrical charges, including those created by the human body, at surface resistances between 10(6) and 10(9) ohms, without causing any spark discharge.

In addition to preventing electrostatic discharges that can damage electronic equipment and potentially dangerous explosions, Dyna-Graphics' Folex film graphic overlays also help counteract surface contamination caused by statically-attracted dust particles. The conductive particles in the graphic overlay film are visually inconspicuous.

Dyna-Graphics has used Folex GO-MA/2K ESD film to create thin explosion- and ESD-protection surfaces with high mechanical and chemical resistance that c my photo and wallpaper an be easily printed on to include company logos, legends, and the like. This process previously required the use of conductor pastes, which was ultimately a costly and complex process. Using Folex film allows Dyna-Graphics to create essentially the same—but in many ways superior—products for their customers faster, and at lower cost.

To learn more about Dyna-Graphics' new Folex explosion- and ESD-p oled technology on mobile phone rotection graphic overlay film, call them at 800-959-0108 or contact them via their website. Visit www.dyna-graphics.com for more information on Dyna-Graphics' many state-of-the-art membrane switch products.

Get automobile news and garbage compactor

Bright Prospectives for Computer Scientists in High Performance Computing

PRLog (Press Release) – Jul 22, 2011 – Supercomputers contribute significantly to the oil, automobile, aerospace, and chemical and pharmaceutical industries' ability to solve complex problems.They enable companies within these industries to design new and better products in less time, and to simulate product tests that would have been impossible without spending months developing and experimenting with expensive product models. Some companies have attributed significant cost savings to the use of supercomputers. For example, although exact figures were not always available, representatives of some automobile and aerospace companies estimated that millions of dollars have been saved on specific models or vehicle parts because of reduced manufacturing or testing costs. In addition, one oil company representative estimated that over the last 10 years, supercomputer use has resulted in increased production of oil worth between $6 billion and $10 billion from two of the largest U.S.oil fields.

Analysts of Market Research Media project the global defense high performance computing market to increase from $2.6 billion in 2010 to $3.3 billion in 2015. The estimate for worldwide cumulative market 2010 – 2015 is $18 billion, for a compound annual growth rate (CAGR) of 4.7% in the 6-year period.&# my photo and wallpaper 13;

Job market analysts from JobOutlook.info have graded supercomputing field as a highly promising career pathway for computer scientists.

The following industries will be top employers of computer science professionals with specialization in high performance computing:

Oil Industry – As an early user of supercomputers, the oil industry has realized substantial benefits from supercomputer applications. By using two key applications for processing seismic data3 and simulating reservoirs, oil companies have improved their ability to determine the location of reservoirs and to maximize recovery of oil and gas from those reservoirs. This ability has become increasingly important because of the low probability of discovering large oil fields in the continental U.S. New oil fields are often small and located in harsh environments, making exploration and production difficult. Several industry representatives estimated that the use of supercomputers reduces the number of dry wells drilled (at a cost of $5 million to over $ oled technology on mobile phone 50 million per well) by about 10 percent.

Aerospace & Defense Industry – Engineers and researchers in the aerospace & defense industry use super-computers to design, develop, and test aerospace vehicles and related components. Supercomputers, for example, have enabled engineers to analyze aircraft structural composition for design flaws and to simulate their performance in wind tunnels. This ability is important because wind tunnels are expensive to build and maintain, and cannot reliably detect certain airflow phenomena. Simulation permits a reduction in physical model testing, and substantial savings in time and money.

Automobile Industry – Automobile manufacturers increasingly rely on supercomputers to design vehicles that are safer, lighter, more economical, and better built. A primary supercomputer application-crash analysis is used to simulate how vehicle structures collapse on impact and how fast passengers move forward. These simulations provide more precise engineering information than was possible from physically crashing pre-prototype vehicles. They also reduce the number of vehicles required for these tests by about 20 to 30 percent.

Chemical and Pharmaceutical Industries – from computer assisted molecular design to synthetic materials research, biotech companies increasingly rely on supercomputers to study critical design parameters and more quickly and accurately interpret and refine experimental results.

Media partners:

http://www.computerscience.org http://www.com puterscientist.org http://www.joboutlook.info

Get automobile news and garbage compactor

Bright Prospectives for Computer Scientists in High Performance Computing

PRLog (Press Release) – Jul 22, 2011 – Supercomputers contribute significantly to the oil, automobile, aerospace, and chemical and pharmaceutical industries' ability to solve complex problems.They enable companies within these industries to design new and better products in less time, and to simulate product tests that would have been impossible without spending months developing and experimenting with expensive product models. Some companies have attributed significant cost savings to the use of supercomputers. For example, although exact figures were not always available, representatives of some automobile and aerospace companies estimated that millions of dollars have been saved on specific models or vehicle parts because of reduced manufacturing or testing costs. In addition, one oil company representative estimated that over the last 10 years, supercomputer use has resulted in increased production of oil worth between $6 billion and $10 billion my photo and wallpaper from two of the largest U.S.oil fields.

Analysts of Market Research Media project the global defense high performance computing market to increase from $2.6 billion in 2010 to $3.3 billion in 2015. The estimate for worldwide cumulative market 2010 – 2015 is $18 billion, for a compound annual growth rate (CAGR) of 4.7% in the 6-year period.

Job market analysts from JobOutlook.info have graded supercomputing field as a highly promising career pathway for computer scientists.

The following industries will be top employers of computer science professionals with specialization in high performance computing:

Oil Industry – As an early user of supercomputers, the oil industry has realized substantial benefits from supercomputer applications. By using two key applications for processing seismic data3 and simulating reservoirs, oil companies have improved their ability to determine the location of reservoirs and to maximize recovery of oil and gas from those reservoirs. This ability has become increasingly important because of the low probability of discovering large oil fields in the continental U.S. New oil fields are often small and located in harsh environments, making exploration and production difficult. Several industry representatives estimated that the use of supercomputers reduces the number of dry wells drilled (at a cost of $5 million to over $50 million per well) by about 10 percent.

Aerospace & Defense Industry – Engineers and researchers in the aerospace & defense industry use super-computers to design, develop, and test aerospace vehicles and related components. Supercomputers, for example, have enabled engineers to analyze aircraft structural composition for design flaws and to simulate their performance in wind tunnels. This ability is important because wind tunnels are expensive to build and maintain, and cannot reliably detect certain airflow phenomena. Simulation per oled technology on mobile phone mits a reduction in physical model testing, and substantial savings in time and money.

Automobile Industry – Automobile manufacturers increasingly rely on supercomputers to design vehicles that are safer, lighter, more economical, and better built. A primary supercomputer application-crash analysis is used to simulate how vehicle structures collapse on impact and how fast passengers move forward. These simulations provide more precise engineering information than was possible from physically crashing pre-prototype vehicles. They also reduce the number of vehicles required for these tests by about 20 to 30 percent.

Chemical and Pharmaceutical Industries – from computer assisted molecular design to synthetic materials research, biotech companies increasingly rely on supercomputers to study critical design parameters and more quickly and accurately interpret and refine experimental results.

Media partners:

http://www.computerscience.org http://www.com puterscientist.org http://www.joboutlook.info

Get automobile news and garbage compactor

UFWC Global Coin Becomes Space Currency!

PRLog (Press Release) – Jul 22, 2011 – The world and its diverse population were brought closer together above in the heavens & cosmos when two seemingly different programs were united with just one deed.

While both initiatives seek to unite the world's people, one with the co-operation of an astronaut the International Space Station, the other through a coin with the United Future World Currency's (UFWC) initiative, there was one unusual turn of events with a difference. Both initiatives came together when Flight Engineer Paolo Nespoli, an Italian astronaut of the European Space Agency and chosen as one of the three person crew aboard the Soyuz TMA-20 which docked with the ISS -  International Space Station packed a little something extra:  a "good luck amulet" 15,5 gram and 30 mm diameter silver prototype coin issued by the Italian State Mint - Istituto Poligrafico e Zecca dello Stato for the UFWC project.

The photographs are not a virtual graphic effect, they  are spot on and they do show truly  a small, silvery and shiny object against the window of the "cupola" inside the ISS, and showing the Earth down.

Dr. Sandro Sassoli, founder as well as general coordinator of the UFWC initiative commented: "The aim of the International Space Station and of UFWC are actually one and the same, to link all countries and people of the world with the motto "Unity in diversity" further adding "I am so enthusiastic of this achievement of Paolo's which though his good deed launches a message of real unity and brotherhood" Flight Engineer Nespoli's amazing photographs clearly show both sides of the encapsulated one unit silver coin floating in weightless space with the stunning backdrop of the earth providing a spectacular image.

The coin's legend, "UNITY IN DIVERSITY" is visible as well as the UFWC's ow my photo and wallpaper n "tree of Life" design. This event is of great interest for both coin collectors and space enthusiasts alike. Paolo has had quite a following regarding his experience aboard the International space station with his tweets and photographs. He is the one and only @astro_paolo on Twitter and uploaded his images & comments about his exclusive experience, the UFWC coin was among those sent back to his many followers.

The UFWC coins, which were originally test strikes minted in both gold and silver in 2009 to mark the G8 L'Aquila Summit hosted in Italy, July 2009 with half ounce gold examples being presented to each attending heads of state & government.  One of the limited silver examples was also given to Flight Engineer Nespoli by the UFWC's founder just before Nespoli's lift-off as a good luck charm. Mr. Nespoli confirmed to Dr. Sassoli at a recent reunion between the two that he had indeed taken the coin with him as a good luck piece and as such, the coin accompanied him for the 159 days that he was a resident of the international Space Station from December 2010 to May 2011. Both versions of the coins are eagerly sought by coin collectors due to the publicity surrounding their initial launch when Russian President Dimitry Medvedev's enthusiastically endorsed the UFWC initiative in front of the world's media. Further prototype coins have since been produced in several world mints including the Royal Mint in the UK, the Italian State Mint, and the Casa De Moneda in Mexico with several other projects planned for the remainder of 2011 and well into 2015 with other national mints taking part. Luc Luycx, the designer of the E oled technology on mobile phone uro, created the first UFWC coin for the Royal Mint of Belgium.  The UFWC coins are also going to be  designated as legal tender for the duration of the EXPO MILANO 2015, a special set of coins marking this event are planned for release and will be available at the Universal  Exposition. For more information on the UFWC initiative and the coins mentioned, please visit their website at:

http://www.futureworldcurrency.com

Get automobile news and garbage compactor