Saturday, November 12, 2011

The Airbus A330 and A340

!±8± The Airbus A330 and A340

Airbus Industrie, a consortium of European aircraft manufacturers which had provided the first serious competition to the US with its original widebody, twin-engined A-300, had quickly concluded that its success could only be attained with an expanded product line capable of fulfilling several payload and range needs. Subsequently added to this "family" of airliners had therefore been the smaller-capacity, medium- to long-range range, widebody A-310 and the still smaller-capacity, short-range, narrow body A-320. To complete it, however, a long-range widebody, incorporating new technology, had been required to replace first generation, fuel-thirsty, no-longer-economical Boeing 707s and McDonnell-Douglas DC-8s.

Market studies, however, had indicated the need for two different aircraft. The first of these, tentatively designated "B9," had been for a medium-range, twin-engined design intended for high-capacity transcontinental, DC-10 like routes, and had initially been conceived as a larger A-300 with a stretched fuselage, its existing wing, and the most powerful turbofans then available. So configured, it would have required 25-percent less fuel than the comparable, tri-engined DC-10.

The second, the "B11," had been the quad-engined intercontinental design which had sparked the project's inception.

Costs for two such aircraft, however, had been prohibitive, and design of a single wing, which could structurally and aerodynamically support both two and four pylon-mounted engines, became the core of commonality between the two and the economic solution to the joint launch of both.

In order to differentiate between its narrow and wide body product line, Airbus Industrie redesignated these design studies with "TA" prefixes to indicate their "twin aisle" configurations. The "B9" had therefore been re-identified as "TA9" and the "B11" had been branded the "TA11."

Powered by CFM56 turbofans, which developed between 27,000 and 30,000 pounds of thrust, they had evolved through numerous iterations, with engine number reflecting intended mission length. In 1982, for instance, the TA9, featuring a 27.9-foot longer fuselage than that of the original A-300, had accommodated 410 single-class passengers on the main deck and five pallets in the forward hold and 14 LD-3 containers in the aft hold on the lower deck. Incorporating much of the technological advancement introduced on the A-320, however, the joint TA9/TA11 project had featured its cockpit, side stick controls, and fly-by-wire, or electronic signaling, flight surface actuation, by 1985, mated to a variable-camber wing to augment lift.

By January 27 of the following year, the Airbus Industrie Supervisory Board had redesignated the designs A-330 and A-340, corresponding to the original TA9 and TA11 model numbers, and finalized their detailed technical definitions with the then envisioned launch customers of Lufthansa and Swissair. Because of route requirements, they had demonstrated far greater interest in the quad-engined version than the twin.

A briefly explored collaboration with McDonnell-Douglas, in which a single design, designated AM-300 and incorporating the A-330's wing and the MD-11's fuselage, had quickly waned because Airbus Industrie had refused to consider McDonnell-Douglas's tri-jet configuration. The MD-11 had resultantly become the A-340's competitor, since both had been intended for the same market.

The Airbus Industrie's design, entering a second major evolution, had been able to offer significantly improved performance when it had traded the originally projected CFM56 engines with the International Aero Engine (IAE) V2500-3 Superfan which, on the cutting edge of technology, had incorporated an initial, variable-pitch fan; an almost nine-foot diameter; a 17.5-to-1 bypass ratio; and had produced 32,000 pounds of thrust. Early estimates had promised 15 percent fuel savings, although these had later been reduced by about a third.

The aircraft then envisioned, the A-340-200, had accommodated 262 passengers and had a maximum range of 7,850 miles. A second version, featuring a 14-foot fuselage stretch for a 295-passenger complement, had offered a reduced-range capability, of 7,000 miles, and had been designated A-340-300.

The program's walls, however, suddenly crumbed when International Aero Engines had abruptly canceled Superfan development due to insurmountable technology obstacles of its very advanced design, and Airbus Industrie had forcibly entered its third major evolution when it had renegotiated with CFM International for engine power. No longer able to meet performance specifications, Airbus had virtually returned to the pre-Superfan configuration, and only with considerable design modifications could the aircraft even approach its intermediate iteration capabilities.

CFM International itself redesigned its core CFM56 engine, increasing its fan diameter to produce greater thrust, and this had resulted in the CFM56-5C1 derivative, while Airbus had increased the common A-330/A-340 wingspan from 183.9 to 192.2 feet, replacing its standard tips with 9.6-foot winglets. Although these modifications, along with a 17,600-pound maximum take off weight increase to 542,300 pounds, had significantly improved the performance over that offered by the initial, CFM56-powered aircraft, range had nevertheless eroded over that of the Superfan version, to 7,700 miles for the A-340-200 and to 6,850 miles for the elongated -300.

Nevertheless, Airbus Industrie had formally announced the launch of the A-330 and A-340 program on June 5, 1987 whose development costs had been reduced by some half-billion dollars because of the type's airframe and wing commonality, yet at the same time it had been able to cater to differing airline market needs with the same platform. One hundred thirty orders had been received at this time, of which 41 had been for twin-engined A-330s and 89 had been for four-engined A-340s.

The wing, the key to both, had been built by British Aerospace in the UK and had been Europe's hitherto most ambitious, with the largest span (exceeding 197 feet), greatest sweepback (of 30 degrees), and highest aspect ratio (of 9.3 to facilitate long-range cruise speeds). Although the A-340 had been designed to carry 20 percent more payload and fuel than its twin-engined counterpart, wing-bending moments exerted on the fuselage had enabled it to accommodate either two or four pylon-mounted turbofans. Winglets, covering some 90-percent of the wingtip chord and canted outward at a 42.5-degree angle, had reduced fuel burn by 1.5 percent by harnessing the tip-created vortex where drag-producing pressure differentials had forcibly remixed.

Aerospatiale, one of the Airbus Industrie consortium members, constructed a 1 million, 124-acre final assembly plant in Colomiers, adjacent to the existing facility at the Toulouse-Blagnac Airport in France, to permit up to seven aircraft per month to be completed after their subassemblies and components had been flown from several European sites
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The first aircraft, an A-340-300, had been rolled out on October 4, 1991, at which time combined A-330 and A-340 orders had totaled 250, and Airbus Industrie's first quad-engined, long-range, pure-jet airliner, with a 440,530-pound gross weight, left the ground for the first time 21 days later on October 25. Attaining an altitude of 40,000 feet, it completed a successful four-hour, 47-minute maiden flight, and its test pilots had proclaimed that it had handled like the A-320 on whose fly-by-wire flight controls it had been based.

The A-340-300, with a 208.11-foot overall length, featured a 197.10-foot wingspan and a 3,892.2 square foot area. Identical to the A-330 wing with exception of outer strengthening and a gap between the fourth and fifth leading edge slat to cater to the outboard engine pylon attachment, the wing itself had featured full-span slats, trailing edge flaps, two outboard ailerons, and five outboard spoilers, all operating off of three independent hydraulic systems. Aileron droop increased wing lift. A single rudder had been directly linked to the rudder pedals on the flight deck. The undercarriage, comprised of a twin-wheeled, forward-retracting nose gear; two quad-wheeled, inwardly-retracting main bogies; and a twin-wheeled, rearward-retracting centerline gear; had ensured more even weight distribution, particularly on weaker pavement surfaces.

The aircraft, exit-limited to 440 passengers in a single-class, nine-abreast, 31-inch internal configuration, could alternatively accommodate 335 dual-class passengers with a 30-business and 305-economy class arrangement or 295 three-class passengers in an 18-first class, 81-business class, and 196-economy class configuration, all at varying densities.

The foreshortened A-340-200, which had made its inaugural flight the following year on April 1, 1992, had featured an eight-frame fuselage reduction, resulting in a 194-foot, 11 ¼-inch overall length and permitting 262 three-class passengers in an 18/74/170-arrangement or 303 dual-class passengers seated in a 30-first class and 273-economy class configuration to be accommodated.

After a 2,400-hour, 750-flight test program, which had entailed six A-340-200 and -300 airframes, had been completed on December 22, 1992, the long-range, quad-engined Airbus Industrie design had received its European Joint Aviation Authorities (JAA) type certification on the same day, and US Federal Aviation Administration (FAA) type approval the following year, on May 27, 1993.

Lufthansa, the type's launch customer, took delivery of its first A-340, a -200 configured for 228 passengers, and inaugurated it into service on February 2, 1993 between Frankfurt and New York, achieving a 30-percent fuel reduction over that of the DC-10-30 it had replaced. It had been progressively introduced on transatlantic routes to many of its other US gateways, among them Atlanta, Boston, Dallas, Houston, Newark, and Washington.

Air France had inaugurated the first stretched A-340-300 into service the following month on the Paris-Washington route, replacing Boeing 747s.

Final assembly of the first twin-engined A-330, which had most closely mirrored the A-340-300, had commenced in February of 1992 with the tenth aircraft off the combined A-330/A-340 production line. Appearing without the outer wing strengthening and fuselage centerline undercarriage bogie, the aircraft, powered by two General Electric CF6-80E1 turbofans, took to the skies for the first time on November 2 at a 400,880-pound gross weight, attaining a 41,000-foot ceiling and completing a successful five-hour, 15-minute flight. Because of experience already gained with its quad-engined counterpart, Airbus Industrie had been able to complete its certification program in only half the traditional time. On October 21 of the following year, it became the first commercial design to simultaneously receive FAA and JAA type certification, and also received FAA cross-crew qualification for the A-320, A-330, and A-340.

Inaugurated into service on January 17, 1994 with Air Inter/Air France Europe on the Paris/Orly-Marseilles French domestic route, the type, designated the A-330-300, had also first flown with Pratt and Whitney PW4168 engines on October 14, 1993 and Rolls Royce Trent 700s on January 31, 1994.

Despite Airbus Industrie's hitherto strategy of offering progressively larger-capacity, higher gross weight versions, poor sales of the A-330 twin, along with consistent airline demand for a slightly lower-capacity, longer-range version and persistent inroads of its targeted market by the Boeing 767-300ER, had strongly advocated the need for a reverse strategy.

A new version, the A-330-200 with a ten-fuselage frame reduction and a 193.7-foot overall length, had been authorized by the Airbus Industrie Supervisory Board on November 24, 1995. The aircraft, which would entail a 0 million development program, had exchanged structural weight for range and, as a DC-10 and L-1011 replacement, became a viable 767 competitor, offering nine-percent lower direct operating costs than the Boeing contender, yet achieving 6,400-mile ranges. Improved engine reliability, coupled with successful extended twin-engine operations, had rendered it an economical transatlantic airliner able to connect Europe with all but US West Coast cities.

The new version, with a six-foot forward and four-foot aft fuselage reduction, featured the strengthened wing designed for the ultra long-range A-340-300E, and a 3.5-foot taller vertical tail to compensate for the shorter fuselage's moment-arm. A five-degree increase in rudder travel, to +/- 35 degrees, had also been introduced. Accommodation had entailed 253 tri-class or 293 dual-class passengers. The version's greatest strength, however, had been its fuel-capacity increase, to 36,700 US gallons, attained by using the formerly dry center section fuel tank, resulting in a vital range increase.

First flying on August 13, 1996, the A-330-200, powered by General Electric CF6-80E1A4 turbofans, had attracted 85 orders from eight carriers at this time, inclusive of Asiana, Austrian Airlines, Emirates, International Lease Finance (ILFC), Sabena, and Swissair. Like the A-330-200, it had eventually been certified with three power plant types.

Although A-330-100 and -500 studies had ultimately led to the all-new A-350 twin, A-340 program developments had occurred in the reverse, or more traditional, direction. Seeking to offer a higher-capacity, Boeing 747 replacement, Airbus Industrie had initially projected a 12-frame fuselage stretch of the existing A-340-300 designated A-340-400X, powered by the existing turbofans, but airline interest had overwhelmingly dictated a larger aircraft.

The final version, the A-340-600, had featured a 19.3-foot forward and 10.6-foot aft, or collective 20-frame, fuselage stretch, resulting in the world's longest airliner, with a 245.11-foot overall length. Indeed, its aero-elasticity, which resulted in periodic, in-flight bending frequencies, had necessitated the installation of pitch-rate sensors on the fuselage and wings in order to provide feedback and elevator counter-movements, restricting these bending cycles to 2-3 Hz.

An extended wingspan, attained by means of a tapered insert, had produced a 20-percent area increase to 4,703.8 square feet, a 40-percent increase in lift, and a 38-percent increase, of 11,760 US gallons, of fuel. Sweepback had also been increased, from 30 to 31.5 degrees, with an equal increase in the angle of the winglets.

The longer fuselage moment-arm had enabled the lateral axis to be controlled with an almost two-foot shorter vertical tail over that installed on the A-330, but a 38-percent larger horizontal, all-moving composite tail surface had been required to maintain effective pitch control.

Weight distribution had been maintained with a quad-wheeled, forward-retracting centerline undercarriage bogie, increasing aft hold pallet accommodation by two.

The .9 billion program, launched on December 8, 1997 with 16 commitments from Virgin Atlantic, had resulted in its first flight four years later on April 23, 2001. Powered by four Rolls Royce Trent 556 engines, the aircraft had been airborne for five hours, 22 minutes.

For carriers placing greater emphasis on range than payload, Airbus Industrie had offered, in parallel with the A-340-600, a lower-capacity, ultra-long range version designated the A-340-500. Featuring a 1.9-foot forward and three-foot aft fuselage plug over the basic A-340-300, the 313 triple-class passenger aircraft, six frames longer than the original -300 series or 14 frames shorter than the -600, had a 221.6-foot overall length and employed the -600's wing. First flying on February 11, 2002 and certified 11 months later on December 3, it had received initial orders from Air Canada, Emirates, ILFC, and Singapore Airlines. Its extreme range, the longest of any commercial pure-jet airliner, had been demonstrated by several record flights. On February 3, 2004, for example, an A-340-500 operated by Singapore Airlines had flown the 7,609 nautical miles between Singapore and Los Angeles in 14 hours, 42 minutes, while the same aircraft had spanned the 8,963-mile distance to New York five months later on June 28 in 18 hours, 18 minutes.

Having utilized a single airframe-and-wing platform, Airbus Industrie had ultimately succeeded in designing its first high-capacity, long-range airliner, resulting in two twin-engined and four quad-engined versions which had the versatility to replace earlier-generation 707s, DC-8s, DC-10s, L-1011s, and 747s on a wide variety of routes, and, by the end of 2008, had amassed a collective 1,400 sales to over 100 worldwide operators. Its original purpose of completing its Airbus "family" of aircraft had thus been fulfilled.


The Airbus A330 and A340

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Saturday, October 1, 2011

Oscillating fans - History and Progress

!±8± Oscillating fans - History and Progress

Oscillating fans are used to support the circulation of air throughout the room. These electric fans have the ability to direct the airflow from side to side. This allows the fan to make more room with the wind field that produces fans and ceiling fans that only a single direction or a single area, with its windshield to cover the conflict.

The first oscillating fans were developed in 1907, based on a concept of ceiling fans. So far, all the electric fans such as ceiling fans inwhich is the air in one direction directly. Engineers found a way to the original design of electric fans with the addition of a ball joint split, which can improve the fan to be redirected. It 'been a great improvement over the first fan, which has only one way. The design for this has been fortified with the mechanization of the control of the direction of the fan. Moving the fan head from side to side, could actually push the new impeller, a moment for more than one direction. Thus, creationthe first modern version of the oscillating fan.

Been some further improvements to the electric fan over the years has developed. There are models that also has a built-in electric heating. This heats the air bubbles and create a warm wind thawing.

The majority of fans are used to swinging a fresh wind in homes, offices and other enclosed spaces. The most advanced electric fan curve of the sky, how to distribute them in different directions, the entire spacewhile they are with traditional mechanical movements characteristic of oscillating fans.


Oscillating fans - History and Progress

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Monday, September 5, 2011

How do infrared cameras?

!±8± How do infrared cameras?

Have you ever wondered what are the infrared cameras and how they work? To understand how they work, you must first understand and know what is infrared.

Infrared is a layer of light that can not be seen with the naked eye. The colors of the objects you see around you are actually reflected by the waves of visible light. This is due to the heat of objects, curves of the color spectrum, so that the output given their different color. However, there is an invisible layerof light, just below the red in the color spectrum that produces heat, but not seen with the naked eye at all.

This low heat can be captured by an infrared camera and back on a monitor or screen. Since the main function of infrared cameras' is to detect the heat of an object and its color, the images are usually either monochromatic or green. In a sense, act as a thermometer body which attempts to measure the specific heat through the object anddisplay accordingly.

A wide range of applications has been developed for these findings. Although the first practical application of infrared cameras was in the nature of the military, gradually spread to other areas of the discipline, thus the birth of a new era not only in the field of photography, but also in scientific fields such as astronomy and medicine, where high-quality thermal images can now be used.

In the medical field is the use of infrared imagesa wide range of medical applications, such as fever screening, mammography and cancer screening. And 'demonstrated to be effective in the production of images, the doctors determine the proper medical intervention for the patient to be treated can be applied. This class of devices, infrared imaging has also demonstrated during the outbreak H1N1 valuable when they enable health authorities to help determine whether a passenger who suffers from just off the plane from each of these diseases.

Infrared cameras also help toEarth scientists determine the date by which the heat is turned off for him. The experts helped to determine if a typhoon is brewing in some areas or if the "El Nino" phenomenon is about to hit a particular land mass. They have proved useful in predicting the path of a bushfire, by applying the smallest details of the conflagration, as has been seen on the infrared image.

The way the cameras work by detecting the infrared heat is even more open to innovation in the variousDisciplines. It is a discovery that will benefit mankind for centuries to come.


How do infrared cameras?

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Sunday, July 31, 2011

The Demoiselle Airplane

!±8± The Demoiselle Airplane

The Demoiselle, a small monoplane fragile apparently incapable of a pilot, reflects not only the same man who designed it short, but the long line of lighter than air craft, which had preceded it. The designer, five feet, four inches had spent 110-pound Alberto Santos-Dumont, who had hailed from Brazil, most of his life in France, where the first successful balloon ascent in the world by the Montgolfier brothers in 1783 and an event that may have unknowinglyreplaced its related experiments.

Unlike fixed or rotary wing aircraft, the science of aerodynamics to deal elevator, the elevator balloons floating from the beginning.

The air is compressible, ie, their weight compresses. The fund's position in the atmosphere, the air and then the weight is about making it closer or near the bottom. On the contrary, as it increases, it becomes thinner.

Balloons take advantage of these changing conditionsto achieve lift. Heated air or lighter than air gas, a balloon envelope, which causes the ball to collect themselves, because the internal air is less dense than the surrounding air. When you hear the height where the density means that indoor air has reached the surrounding air to rise and reached a state of balance within and without, that is, its internal gas density corresponds to the density of external gas.

At this point the same pressure on the balloonupward pressure on the ball. Balloons are "balloon", because their lift is made in still air mass, ie a mass of air is not moving. A plane moves vertically, but is based on existing wind speed and direction for the horizontal movement. So it can not be relied upon specific directions of transport.

Balloon controlled movement employ one or more propellers for speed and direction, and called "blimps", but these propellersnot to extend or lift.

Santos-Dumont had, even at a young age, she decided to have a profound effect on people with his life, but had yet to determine the means. However, a fascination with flight, generally, and balloons, in particular, just to continue, which makes its lack of focus on governance and leads him to believe that their non-profit, the wind direction could be determined with pre- replaced.

Only after his first aerial photographsThe progress in a 40-meter diameter balloon in the fall of 1897, concluded that the aircraft had been his life calling.

Trying to tame the uncontrollable factor, has designed an airship with "Santos-Dumont No. 1." Equipped with an elongated, cigar-shaped balloon, which had 6454 cubic meters of 450 pound load capacity, was an internal combustion engine, driving a 6.6 meter diameter propeller driven during the proposed speed a vogue AugmentedDirection and two heavy bags suspended ball weight at the front and rear, for the future, replacing the heavier aircraft elevators, making the pitch control. The pilot has turned into a basket and rope guard personnel on the ground the airship in and out of his position as anchor host for maneuver.

First flight September 18, 1898 in Paris, she gently collided with trees on the opposite side of the field from which it was thrown out due to insufficient distance, climbs in the higherRowing controllability her, but after two days of repair, shows proven, Santos-Dumont asked is provided. The ball lifting the engine and propellers for propulsion, steering to change direction and budget of ballast by step: draw circles and eight in the sky, the number 1 all the elements necessary to integrate the triumph over gravity.

The success, Santos-Dumont No. 2 carried out a larger bag, of which ten percent increase in the amount of gasled to a 44-pound lifting more.

To succeed, No. 3, a longevity record of 23 hours continuous antenna arrived home, built in a hangar with Santos-Dumont 36 meters in height, the doors at Saint-Cloud, near Paris.

On October 19, 1901, won the prize of 100,000 francs Henry Deutsch de la Meurthe, a founding member of the Aero Club of Paris, by circling the Eiffel Tower and the return to the takeoff point 30 minutes later, he offered in his n. 6Design, a 108 meters long with an airship propeller mounted aft.

Despite these successes, however, soon turned to heavier than air flight. The fulfillment of a promise by Samuel Pierpont Langley, the curator of the Smithsonian, in vain their designs "Aerodrome" was from a catapult launched on the Potomac River to begin experimenting with this area of ​​the hub and prove his reputation after suspected sabotage once again had no cuts in its 7 ball carried and was excludedentry into the St. Louis Aero Club competition for a $ 100,000 prize pool, has designed a helpless, pontoon-equipped plane monoplane in Paris. No. 11 was designated, they moved fast boat, so flying over the water surface, while the next 12, a dual-wing aircraft, rotating propellers, do not fly in the air because there was not enough for vertical flight technology developed during this century.

The No. 14-up, however - albeit with a small contributionaerodynamic development - both fame and success because of the continental absolute lack of technological capabilities of existing competition. Santos-Dumont and jointly by Voisin, 25, an engineer, who on his visor, which was heavier than air craft and share his knowledge of them designed by Santos-Dumont in the winter of 1905-1906, was a 40 - Fixed-foot-long aircraft with 33 meters, cellular box kite wing piano wires and braces and jaw with dihedral extreme, a long,covered fuselage, a single, portable, box-set of cells combined length and pitch, forward canard and a 24 horsepower, engine low-wing aircraft attacked Antoinette, a large, paddle blade, pusher-propeller operation. It 'was then a 50-hp engine and retrofit octagonal ailerons. Control can only be done by a standing pilot. Because there have been flight tested initially suspended from the blimp No 14, has had the "14-bis" assumed name, but had its canard configurationdeserves the "Bird of Prey" title by the press.

He won the Archdeacon prize at October 23, 1906 for a flight of 25 meters and the 1,500 French francs Aero Club Award for a 100-meter coverage of 12 November, the latter recognized as the first in Europe, has been sustained and heavier air of triumph, and, for some time, probably the world because of the secret of the Wright brothers' experiments without papers.

After four in the middle, but without success, they are heavier than airDevelopments, applied Santos-Dumont, who has always made his signature, blimp-based design philosophy for its next development wing, is to employ the smallest unit possible, the place for him in a sport plane, similar to a antenna can produce customized cars.

The result of the project, the No 19 was a small tractor monoplane, whose "body" was made of bamboo and covered with the cloth-covered wings, spanning 16.5 meters, has maintained a very pronounced V-shapeinserted by No. 14-up. A two-cylinder, 20-hp Dutheil-Chalmers engine, above the pilot on the wing semi-point-mounted, provided that the power was in full rudder combined and integrated with two sides, under the wing and control surfaces future, canard lift, which extends also in view of the structure. The ailerons and wing-warping mechanism, no planes, unable by its very nature, are controlled by its transverse axis, made three short trips to the end of 1907, the longest of which was200 meters before they are damaged and withdrawn from further examination. However, if the aircraft is the basis for the final, the number 20 which will also be used as Santos-Dumont, the last one.

Maintaining the simplicity of design minimally No 19, but the elimination of defects, present the plan, three-boom, bamboo frame, his first, which extends from the end towards the tail, the second under the wing of the third wheel and axle From this point ofCode, secured with steel joints.

The rectangular, clear peaks, high wing, with a span of 18 meters, a width of 6.35 meters, with a 2.7:1 aspect ratio and a 113 square feet of space was with a double layer of silk, covered by tense bamboo ribs and assembled as a feature of his cell earlier, with a pronounced dihedral angle. A section along the front edge, which is one third of durability, ease of installation and the propeller, but reduced ropeand along this path.

A vertical and horizontal, fan-shaped surface, swung on a universal joint on the frame of the triangle meeting place than serve his tail shape and height respectively given yaw and longitudinal control, the rudder, even for a 21 square meters area.

A 30 hp, twin-cylinder, boxer shorts, water-cooled Darracq motor is mounted, such as No 19, above the pilot, led by a 6.9 meter diameter, two feet away, two shovels ChauviereProp at 1,400 revolutions per minute. The two valves of the cylinders were operated by pushrods and rocker arms driven by two eccentrics. Its magnet was set at an angle to the top of the casing, while gasoline and oil tank were exposed beneath it, a tank-submerged pump lubricating fluid distribution.

The aircraft was powered by an alternative-Bayard Clement Panhard engines.

Maneuver on the ground was hit by two tire mounted rigidlyTyres and one small skid on the back.

The pilot who ejected from a strip of canvas over the frame under the engine was rocking like the Curtiss Model D, a virtual extension of the cell and the seat was too small, 120-pound small operator. Longitudinal control was by a right-wing tip elevator control stick, a cut-off blip the engine to induce departures, has been maintained. Vertical control was completed by the left, the rudder deflection,while the control side was a lever located behind the pilot and a vertical grip on the back pocket of a jacket stitched special flight, in fact reached the point of attack by making the body a "third hand". His manager, activation, such as the creation of many pioneering aircraft as the wing-warping mechanism pending bust, changed the 'angle of incidence due to air transfer. A foot-clip on the driver's left foot has published a suspension cable for changePropeller revolutions per minute.

First in France in March 1909, a year place and who presented bred monoplane similar, but larger Bleriot XI, the elegant, beautiful aircraft, with a 330 - to 370 pounds of gross weight, as a dragonfly or a young woman, because of its translucent, silk-covered wings and was then called "Demoiselle" in French. It 'was the first air sports in the world.

Share the dihedral of the wing and extreme low center of gravity emulates the pendulumNo.14-up with his predecessor and No 19, was only on the characteristics of design in static, nor benefit to the air. These are not to exist, however, the plane is so prone to vibration increasingly destabilizing, which has flown over pitching and rocking. However, as the plane first light, the Agency has married Santos-Dumont's lighter than air experience with an internal combustion engine in a very low eight, wing-structure. With an averageMaximum level flight speed of 52 mph, it produced 12 pounds per horsepower 3.1 pounds and lift big square piano, even though he had reached a top speed of 55.8 mph, and in September of 1909 had a maximum distance of 11 miles in 16 minutes.

Emulating the success of simultaneous Bleriot XI was the first plane and only the Demoiselle Santos-Dumont played, and Clement-Bayard in large numbers, for example, a Paris-car manufacturer with about 300 built30 hp motor cars and sold them at $ 1,250 each, while the aircraft could be purchased in Chicago for $ 250 without engine by the Hamilton Manufacturing Company Aero for $ 1,000. In France, a flight school founded by Santos-Dumont Demoiselle, and occasionally also boasted as one of the instructors, and in 1911 the magazine Popular Mechanics has published his drawings and assembly instructions. Also like the Bleriot XI, the day it was installed in a lot of privateQuantity.

January 4, 1910 during a flight, crashed into the Demoiselle, for an account, because of "a tension wire snapped." Although Santos-Dumont had suffered non-life threatening injuries, his emotional state was affected more precarious. Through him was his final project of the Demoiselle, and January 4 served as his last flight as a pilot, the 36 years, Pioneer said it has reached its life, unfortunately, the goals with him.

Always ready on the development andPromotion of aviation for the transport and social and economic development, was emotionally destructive for the role it had played during the First World War and he is vehemently against shock. Tormented by the large number of lives lost prematurely because of his invention, he finally ended his life 22 years later, July 23, 1932, in Brazil, with his life's work, paradoxically, the self-proclaimed goal of humanity deeply impressed by his inventions reachedin both positive and negative ways.

The lady at the Old Rhinebeck Aerodrome collection is a replica, built by Cole Palen in 1950, when his parents 'home', Red Oaks Mill, the idea came from the same time and at the same built Curtiss Model D

The example of Rhinebeck, the last renovation was in the middle of 1990 occurred when Dan Taylor, a pioneer in Rhinebeck pilot had tried to make it more representative of the original No. 20Demoiselle and which has a 30-hp two-cylinder, air-cooled aircraft engines from Detroit in 1909, of those who had driven US-backed constructed cells. Tino Paul Savas, a mechanic and welder training, is developing a version suitable for aircraft capable of its workforce without overstressing bamboo construction support.

Suspended from the ceiling of New York's Jacob Javits Center during the July 2002 New York jewelry, watches and watch the show, are the two old monoplaneRhinebeck and Alberto Santos-Dumont, Louis Cartier was the connection nearly 100 years earlier, when he handsfree wristwatch for him after learning that the blimp was a pilot not being able to send control, and simultaneously monitor the time his Hunter pocket watch is designed, forged during his circumnavigation of the famous Eiffel Tower in the English pursuit of the prize.

Today the plane Rhinebeck Aerodrome Old Aircraft Hangar Pioneer displays, one of the fourBuildings on the airfield located on a hill.


The Demoiselle Airplane

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Wednesday, July 27, 2011

Air Hogs Zero Gravity Race Cars Nano

!±8± Air Hogs Zero Gravity Race Cars Nano

Air Hogs Zero Gravity Nano will lead children to the wall. The most amazing irreplaceable toys for their children. That brings hours of fun for the kids and they can do in disbelief, like the artist with cool zoom to your walls and ceilings.

This Zero Gravity Race cars have had an incredible ability to cling to walls and ceilings of any type of surface. The Air Hogs Zero Gravity Nano-car racing has no restrictions. Smaller and lighter than the Air Hogs Micro, this graycar remote has a splendid scale speed performance on smooth surfaces indoors. Turn on the Venturi walls nano scale or zoom on the ceiling fan. Designed for ages eight to store the nano controller the car and recharge the batteries.

Climb the walls

Air Hog Zero Gravity Car feature a sleek, lightweight, aerodynamic and details of the race, the nano-scale the walls and even drive upside down on the ceiling. The RC controller / charger is equipped with a steering wheel,Back and forth the gas, adjust the steering trim controllers and storage / loading area.

Before Nanocars Zero Gravity for a lap, may help adults want to install the controller / charger with six "AA" batteries (not included). The Nano has a rechargeable battery and the machine is operating light flashes when the battery is running low. For recharging, easily the Nano in the RC controller / charger. A flashing red light lets you know the batteryLoad and in about half an hour Racer Air Hog Zero Gravity will be ready to go.

Super Smooth Performance Zero Gravity Car

As a race car itself, the Hog's Nano Air can be used and ran in the right environment. Preferably have large open interior spaces are recommended, and keep to the dwarf all the floors and walls clean area and smooth. Left and right buttons on the controller you can attach to the fairing, so that the severity of strokeCar go straight.

Smooth surface on the right, the Nano Air Hog incredibly large-scale speed, hitting a speed of eight centimeters per second, the ground floor and five centimeters per second, while climbing the wall or a ride up to the ceiling. Pushing the throttle forward to get up to speed quickly and then turn the steering wheel, makes the Nano for donuts and drive around for more fun.

A switch on the back of the nano-enabled VenturiFan, so that the Nano's aspiration - so stick to the walls and go upside down from the ceiling.

Challenge your friends

There will be fun for the kids! The green-black Nano Air Hog Zero Gravity Race Cars are part of a series of light Zero Gravity Car. Several models of nano-drive (sold separately) are connected to different radio frequencies so that the control Zero Gravity Car Race multiple simultaneously at the same time with all your friends.

What isbox

Dwarf Car Racing Zero Gravity (Grey), Manual of the controller / charger and instructions.


Air Hogs Zero Gravity Race Cars Nano

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Sunday, July 24, 2011

Monte Carlo 5DI52BSD-L Discus 52-Inch Contemporary Ceiling Fan with Light Kit and Five Silver Blades, Brushed Steel

!±8± Monte Carlo 5DI52BSD-L Discus 52-Inch Contemporary Ceiling Fan with Light Kit and Five Silver Blades, Brushed Steel

Brand : Monte Carlo | Rate : | Price : $124.30
Post Date : Jul 25, 2011 03:35:22 | Usually ships in 24 hours

The Monte Carlo Fan 5DI52BSD-L is a Discus Ceiling Fan with the Three Speed Pull Chain in the Brushed Steel motor finish. Modern Minimalism. This Ceiling Fan is from the Discus Collection and is UL Indoor rated. The Discus Includes 6" (1/2" Interior Diameter) Pole.

  • Heavy duty 153 by 18 torque-induction motor
  • 12-blade pitch for optimum air movement
  • Product dimensions; 17.1-Inch high by 52-Inch wide
  • Light kit included; 1 by 75-Watt halogen bulb
  • Precision balanced motor and blades for wobble-free operation

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