Fact-checked by Grok 2 weeks ago

General Electric I-A

The General Electric I-A was the first operational turbojet engine developed and run in the United States, achieving its initial test on April 18, 1942, at GE's Lynn, Massachusetts facility.^[1] This centrifugal-flow engine, producing 1,250 pounds of thrust, was an improved version derived from British inventor Frank Whittle's Power Jets W.1X design, which GE adapted under a secretive U.S. Army Air Corps contract initiated in 1941.^[1] It powered the Bell XP-59A Airacomet, marking America's entry into jet propulsion with the aircraft's first flight on October 1, 1942, near Muroc Dry Lake, California.^[1] Developed amid World War II urgency, the I-A featured a single-stage centrifugal compressor, ten reverse-flow combustion chambers, and a single-stage axial turbine, with overall dimensions of approximately 175 cm in length and a weight of 376 kg.^[2] GE's rapid prototyping—starting from Whittle's blueprints secured by General Henry H. "Hap" Arnold—transformed the company from appliance manufacturing to aerospace leadership, culminating in the engine's successful static run just months after the project began.^[3] Although the XP-59A served primarily as a technology demonstrator rather than a combat aircraft, the I-A laid foundational advancements in turbojet technology, influencing GE's subsequent engines like the J33 and establishing the U.S. as a major player in the Jet Age.^[1] The I-A's legacy extends to its role in accelerating American aviation innovation during the war, with production variants redesignated as the J31 achieving limited operational use in early jets and missiles.^[4] By 1945, GE had evolved the design into more powerful units, but the I-A remains a pivotal milestone, symbolizing the shift from propeller-driven flight to sustained jet power and enabling the supersonic era that followed.^[1]

Development History

Origins and British Influence

The development of the General Electric I-A turbojet engine originated from British innovations in jet propulsion, spearheaded by Royal Air Force officer Frank Whittle, who patented his turbojet concept in 1930 and led the creation of the experimental Power Jets W.1X engine. This engine, assembled from spare parts and first run in December 1940, underwent ground testing in Britain before being selected for transfer to the United States amid escalating World War II threats.^[5]^[6] In response to Axis advances in aviation technology, U.S. Army Air Forces Chief of Staff General Henry H. "Hap" Arnold, during a visit to Britain in spring 1941, negotiated the secret transfer of Whittle's technology to accelerate American jet engine development and maintain air superiority. Arnold arranged for the W.1X engine to be flown across the Atlantic in a U.S. Army Air Forces B-24 Liberator bomber, arriving at the General Electric facility in Lynn, Massachusetts, on October 1, 1941, accompanied by a small team of British engineers from Power Jets Ltd. This handover was part of a broader Anglo-American agreement to share critical wartime innovations, driven by Britain's resource constraints and the U.S.'s industrial capacity.^[7]^[5] Complementing the physical engine, Britain provided complete blueprints for the more advanced W.2B production variant in late 1941, which served as the foundational design for U.S. efforts and informed subsequent iterations like the I-A.^[5] To preserve operational secrecy amid fears of Axis espionage, the project was codenamed "Type I Supercharger" at GE, disguising the jet work as conventional supercharger research, while access to the Lynn facility's dedicated test cell—fortified with thick concrete walls and guarded by military personnel—was severely restricted to a small cadre of engineers known informally as the "Hush-Hush Boys." Frank Whittle himself visited the site incognito in June 1942 under the alias "Mr. Whitely," contributing directly to the adaptation process while adhering to strict compartmentalization protocols. These measures ensured the program's confidentiality until the I-A's successful ground test in April 1942, marking the U.S. entry into practical jet propulsion.^[8]^[7]

GE Design Process and Testing

In October 1941, the U.S. Army Air Corps selected General Electric's River Works facility in Lynn, Massachusetts, to develop America's first jet engine, assembling a small, secretive team of engineers to adapt British turbojet technology under wartime urgency.^[1] The team, led by key figures including engineer Donald Warner, focused on reconfiguring the design for U.S. manufacturing standards while maintaining strict secrecy to protect the project from Axis intelligence.^[8] British W.2B blueprints provided the foundational centrifugal compressor design, which the GE engineers reverse-engineered into the I-A prototype, emphasizing a double-sided impeller for efficient air compression.^[2] The prototyping phase involved rapid iteration amid significant hurdles, including combustion instability that caused early engine stalls during startup and operation, as well as sourcing high-temperature alloys and precision components under wartime material shortages and rationing.^[9] These constraints delayed progress, forcing the team to improvise with available domestic materials while adhering to classified specifications. The initial Type I engine achieved its first run on March 18, 1942, marking the inaugural U.S. jet engine operation, but it required refinements for reliability.^[2] On April 18, 1942, the improved I-A prototype underwent its first successful static test in a fortified concrete cell nicknamed "Fort Knox" at the Lynn facility, producing 1,250 lbf of thrust at full power.^[1]^[10] Subsequent ground testing addressed lingering instability issues through adjustments to fuel injection and combustion chamber geometry, enabling sustained runs. By mid-1942, the engines supported integration into the Bell XP-59A Airacomet prototype, with the first pair delivered in August for installation and taxi trials.^[11] This testing progression culminated in the XP-59A's maiden flight on October 1, 1942, at Muroc Dry Lake, California, validating the I-A's performance in flight despite its modest thrust output and confirming the viability of American jet propulsion under operational conditions.^[12]^[13]

Technical Design

Core Components

The core of the General Electric I-A turbojet engine comprised essential mechanical elements engineered for simplicity and reliability in early aviation applications. At its heart was a single-stage double-sided centrifugal compressor, which drew in ambient air and accelerated it radially outward to achieve compression, thereby increasing air density for subsequent combustion processes. This compressor was directly driven by the engine's single shaft, reflecting the design's emphasis on a straightforward, robust configuration derived from British precedents.^[2]^[1] Downstream of the compressor lay the combustion system, consisting of ten reverse-flow can combustors arranged annularly around the shaft. Each combustor incorporated a fuel nozzle that atomized kerosene into the compressed airflow, promoting thorough mixing and stable ignition to generate high-velocity hot gases. The reverse-flow layout directed exhaust gases rearward while allowing incoming air to pass forward, optimizing space efficiency and minimizing thermal stresses on surrounding structures.^[2] These hot gases then expanded through a single-stage axial turbine, where stationary and rotating blades extracted rotational energy to power the compressor via the common shaft. This turbine stage was critical for balancing the energy input from combustion against the demands of air compression, ensuring sustained engine operation without additional power sources. The blades were forged from heat-resistant stainless steel alloys, selected for their ability to endure elevated temperatures and corrosive environments typical of early jet exhaust flows.^[2]^[14]

Configuration and Innovations

The General Electric I-A turbojet engine featured a single-spool design, in which the compressor, combustor, and turbine were integrated on a common rotating shaft to simplify the power transmission and reduce mechanical complexity. This configuration, adapted from Frank Whittle's original British design, allowed for a compact centrifugal-flow arrangement suitable for early experimental aircraft. The engine's airflow path began with an axial intake drawing in ambient air, which was then compressed by a single-stage double-sided centrifugal compressor before entering the reverse-flow combustion chambers where fuel was ignited. The hot gases subsequently expanded through a single-stage axial turbine and exited via an axial exhaust nozzle, generating thrust through reaction propulsion.^[1]^[2]^[15] General Electric introduced several modifications to enhance the reliability and performance of the I-A over the baseline Whittle W.1X design. These addressed inherent challenges in the original design, such as material limitations and uneven airflow distribution.^[1]^[2] The intake and exhaust systems employed straight-through ducting, which facilitated efficient airflow with minimal diffusion losses and was particularly optimized for ground-based testing at GE's Lynn, Massachusetts facility as well as mounting on experimental aircraft like the Bell XP-59A. This ducting design supported seamless integration without significant aerodynamic penalties during early flight trials.^[1]^[2]

Variants and Evolution

I and I-A Models

The General Electric Type I represented the initial American adaptation of the British Power Jets W.1X and W.2B turbojet designs, serving as the baseline prototype for U.S. jet propulsion efforts. The Type I achieved an initial run on March 18, 1942, while the improved I-A successfully ran on April 18, 1942, at GE's Lynn, Massachusetts facility, marking the inaugural operation of a jet engine in the United States. This milestone came just months after GE received the classified W.1X engine and W.2B blueprints in October 1941, under a U.S.-British agreement facilitated by General Henry H. "Hap" Arnold.^[1] The Type I-A emerged as a refined iteration of the Type I, incorporating modifications to the combustion chamber—specifically, the addition of flame tube partitions—to enhance flame stability and overall operational reliability. These updates addressed early combustion inconsistencies observed in static testing, allowing for more consistent performance without altering the core architecture. The I-A underwent initial testing in May 1942 and quickly became the primary variant for aircraft integration. Both models maintained a consistent dry thrust rating of 1,250 lbf (5.6 kN) at 16,500 rpm, though the I-A demonstrated marginal efficiency improvements in fuel consumption and thermal management during ground runs.^[1] Production of the I and I-A models totaled approximately 30 units, with the majority being I-A variants destined for rigorous static testing and flight familiarization. These engines powered the Bell XP-59A Airacomet prototypes, enabling the first U.S. jet flight on October 1, 1942, at Muroc Dry Lake (now Edwards Air Force Base), California. In this early program phase, the I-A engines underwent extensive ground evaluations to validate integration with airframes, laying the groundwork for subsequent higher-thrust derivatives while highlighting the limitations of centrifugal-flow designs in achieving greater power output.^[1]^[16]

Later Derivatives

The I-14 represented an early uprating of the I-A baseline, achieving 1,400 lbf (6.2 kN) of static thrust through modifications to enhance power output while retaining the centrifugal compressor design.^[17]^[18] This variant first ran in 1943 and was selected to power the service-test YP-59A aircraft, with installations beginning in late 1943 for flight testing at Muroc Army Air Field.^[18] The I-14 addressed initial thermal limitations of the I-A by incorporating incremental improvements in component durability, enabling sustained operation at higher loads during early military evaluations.^[19] Building on the I-14, the I-16 series further advanced thrust to 1,610–1,650 lbf (7.2–7.3 kN) at 16,500 rpm, earning the military designation J31-GE-3 and subsequent variants like the J31-GE-4 and -5.^[17]^[4] Development of the I-16 began in early 1943, with standardization for production P-59A aircraft by mid-year, incorporating key enhancements such as improved turbine cooling to mitigate overheating under prolonged high-thrust conditions.^[19]^[4] These changes, including higher impeller speeds, boosted overall efficiency and reliability, allowing the engine to support operational altitudes exceeding 46,000 feet in testing.^[4] The J31's production ran from 1943 to 1945, yielding 241 units that equipped the U.S. Army Air Forces' initial jet fighters and demonstrated the feasibility of domestic turbojet manufacturing.^[4]^[18] This output not only fulfilled immediate wartime needs but also provided critical experience that informed GE's transition to more advanced axial-flow engines in subsequent programs.^[3]

Applications and Use

Aircraft Integration

The General Electric I-A engine was primarily integrated as a twin installation in the Bell XP-59A Airacomet prototype, marking the first U.S. jet-powered aircraft flight on October 1, 1942, at Muroc Dry Lake, California.^[1]^[20] The engines, each producing approximately 1,250 pounds of thrust, were mounted in custom nacelles along the lower sides of the fuselage to accommodate the novel turbojet design, with the tailplane elevated above the exhaust path to prevent thermal damage.^[20] This layout required adaptations to the fuel systems, including wing-mounted tanks feeding the engines via dedicated lines, though early unreliability in engine performance delayed airframe completion and testing.^[20]^[21] Integration challenges arose from the I-A's developmental stage, necessitating modifications to the XP-59A's structure for the semi-submerged nacelle placement, which integrated the engines into the fuselage for aerodynamic efficiency but introduced complexities in airflow management and maintenance access.^[20] Bell engineers adapted the airframe's mid-mounted straight wings and tricycle landing gear to support this configuration, ensuring the jets' intakes drew from forward-facing ducts while exhausts vented rearward without interfering with control surfaces.^[20] These custom adaptations highlighted the pioneering nature of the project, as the U.S. lacked prior experience with jet propulsion integration. As the program progressed, engine variants transitioned to enhance reliability: the original I-A powered the three XP-59A prototypes, while the improved I-16 (producing 1,650 pounds of thrust) equipped the 13 YP-59A service-test aircraft.^[20]^[22] Production models shifted to the standardized J31 (also designated I-16 in early forms), which powered the 20 P-59A and 30 P-59B aircraft, totaling 66 Airacomets built with I-A derivatives.^[20]^[23] The entire integration effort was shrouded in secrecy to protect jet technology from Axis intelligence, with aircraft and engines disguised as conventional propeller-driven types during ground transport and early flights; fake wooden propellers, often made of balsa wood and covered by tarpaulins, were affixed to the nose to mislead observers.^[24]^[25]^[21] This deception extended to the P-59 designation, reused from a canceled piston-engine project as a cover, ensuring the turbojets remained classified until later in World War II.^[20]

Operational Performance

The Bell XP-59A, powered by two General Electric I-A engines, achieved a top speed of 389 mph during initial flight tests in 1942, while the subsequent YP-59A variant reached 414 mph at high altitude.^[11] Despite these milestones, the aircraft's overall performance fell short of contemporary piston-engine fighters like the P-51 Mustang, which exceeded 440 mph, primarily due to the I-A's low thrust-to-weight ratio of approximately 0.3.^[11]^[22] Reliability proved a significant challenge for the I-A during testing and early operations, with frequent turbine blade failures attributed to overheating and excessive gas temperatures in the combustion chamber.^[26] Engine bearings also suffered from overheating, and fuel pump malfunctions contributed to inconsistent operation, limiting the average service life to between 10 and 50 hours before major overhauls or replacements were required.^[26] These issues stemmed from the engine's centrifugal compressor design, which struggled to maintain stable airflow under varying conditions, often resulting in flameouts or reduced thrust output.^[22] In military evaluations conducted by the U.S. Army Air Forces in 1943–1944, the I-A-powered P-59 series demonstrated the basic feasibility of jet propulsion for aircraft but was deemed unsuitable for combat roles due to its subpar speed, climb rate, and maneuverability.^[12] Instead, the engines found utility in non-combat applications, including pilot familiarization training for transitioning to jet aircraft and experimental radar system integration on modified P-59 airframes.^[12] Over 30 pilots from the Army and Navy accumulated flight hours on the type, providing essential experience in jet handling characteristics.^[11] Key lessons from I-A operations underscored the limitations of early centrifugal-flow turbojets, particularly the need for substantially higher thrust levels—ideally exceeding 2,000 pounds per engine—and a shift toward axial compressors for improved efficiency and power density.^[27] These insights directly informed subsequent U.S. designs, such as the General Electric I-40 and J33 series, which addressed overheating through better materials and cooling techniques, paving the way for operational jets like the P-80 Shooting Star.^[22] By late 1945, as more advanced engines like the J33 became available, the I-A was rapidly decommissioned from active service, with remaining P-59 aircraft relegated to ground instruction or scrapped.^[12] The engine's brief operational tenure highlighted the rapid evolution of turbojet technology during World War II, transitioning from experimental prototypes to reliable powerplants within a few years.^[27]

Specifications

General Characteristics

The General Electric I-A is a centrifugal-flow turbojet engine with a single shaft, representing the first operational jet engine developed and run in the United States.^[2] Its design incorporated a single-stage centrifugal compressor, which provided efficient air compression for the era's technology.^[2] The engine's physical dimensions include a length of 179 cm (70.5 in), and a diameter of 112 cm (44 in), reflecting its compact form suitable for experimental aircraft integration. The dry weight is 354 kg (780 lb), contributing to the lightweight requirements of early jet propulsion systems. Development of the I-A culminated in its first successful run on April 18, 1942, at General Electric's Lynn, Massachusetts facility, following initial testing of the precursor Type I engine earlier that year.^[1] Production was limited to a small number of units, sufficient only for ground testing and outfitting the initial Bell XP-59A prototypes that achieved the first American jet flight in October 1942.^[2]^[1]

Components

The compressor in the General Electric I-A turbojet engine is a single-stage centrifugal type, designed to draw in and compress ambient air before delivery to the combustor. It operates at a maximum speed of 16,500 rpm and achieves an overall pressure ratio of 3:1.^[2] The combustor employs an annular reverse-flow configuration with 10 combustion chambers, arranged to allow efficient mixing of compressed air and fuel while reversing the flow direction for compactness.^[2] The turbine is a single-stage axial-flow unit, positioned downstream of the combustor to extract energy from the hot gases and drive the compressor via a 1:1 shaft ratio. The axial blading was optimized for the engine's modest power output in its experimental role.^[2] The fuel system utilizes kerosene as the primary propellant, delivered through a pump-fed mechanism that ensures reliable injection into the combustor chambers under varying operational conditions.^[2] Lubrication is provided by a circulating oil system dedicated to the main bearings supporting the compressor and turbine rotors, circulating lubricant to minimize friction and dissipate heat during high-speed operation. This closed-loop design was essential for the engine's reliability in early ground and flight tests.^[2]

Performance

The General Electric I-A turbojet engine generated a maximum dry thrust of 1,250 lbf (5.56 kN) at sea level static conditions.^[28]^[15] The compressor achieved an efficiency of approximately 75%, contributing to the engine's overall thermodynamic performance within the material limits of the era.^[29] The I-A was optimized for low-altitude operations, experiencing significant thrust lapse above 10,000 ft due to its simple single-shaft architecture and lack of advanced airflow management.^[30] Later variants, such as the J31, increased thrust to 1,650 lbf through minor refinements.^[4]

Preservation and Legacy

Surviving Engines

The original Power Jets W.1X turbojet engine, the prototype from which the General Electric I-A was derived, is preserved and on static display in the Boeing Milestones of Flight Hall at the Smithsonian National Air and Space Museum in Washington, D.C. Gifted to the museum by Power Jets, Ltd., on November 8, 1949, it represents the foundational British design that influenced early American jet propulsion efforts. The engine is accessible to the public and accompanied by historical plaques detailing its development and first bench test in 1937.^[5] A General Electric I-A example is on display at the Valiant Air Command Warbird Museum in Titusville, Florida, where it serves as part of the museum's collection of historic aircraft engines. This preserved specimen highlights the I-A's role in powering the Bell XP-59A, America's first jet aircraft. The museum is open to the public daily, with interpretive materials provided alongside the engine.^[31] Another I-A engine, one of approximately 12 known surviving examples, is exhibited at the Combat Air Museum at Topeka Regional Airport in Topeka, Kansas. Built by General Electric in 1942 based on Frank Whittle's design, it is presented in static condition for educational purposes, emphasizing its centrifugal compressor technology and contribution to the XP-59A's inaugural flights. Public viewing is available through museum admission, including plaques on its historical context.^[9] While components of I-A engines may exist in private collections, no additional complete engines are confirmed for public display beyond these examples. The Smithsonian also holds a GE I-A in its collection, though it is currently in storage rather than on exhibit.^[2]

Historical Significance

The General Electric I-A turbojet engine marked a pivotal milestone as the first U.S.-built jet engine to achieve sustained operation, with its initial test run occurring on April 18, 1942, at GE's Lynn, Massachusetts facility. Developed under extreme secrecy as part of a clandestine U.S.-British collaboration, the I-A was reverse-engineered from Frank Whittle's Power Jets W.1X design, which had been shared through the Tizard Mission and subsequent agreements to bolster Allied technological parity during World War II. This effort, codenamed by GE engineers as the "Hush-Hush Boys," addressed critical engineering hurdles such as excessive exhaust gas temperatures exceeding material tolerances, ultimately producing 1,250 pounds of thrust and enabling the first flight of the Bell XP-59A Airacomet on October 1, 1942. By kickstarting American turbojet production, the I-A laid the groundwork for the domestic jet propulsion industry, transitioning the U.S. from reliance on piston engines to self-sufficient aero-engine manufacturing amid wartime demands.^[8]^[2]^[32] The I-A's influence extended profoundly to General Electric's ascent as a global leader in jet propulsion, evolving directly into the production J31 engine and catalyzing subsequent innovations that spanned from World War II to the modern era. This progression saw GE's output grow exponentially in capability, with the I-A's modest 1,250-pound thrust scaling to the GE90 turbofan's 115,000 pounds—representing over an 88-fold increase—and powering wide-body airliners like the Boeing 777. The engine's success during the war not only informed early axial-flow designs but also facilitated the U.S. entry into the jet age, supporting the rapid development of combat aircraft that informed Cold War strategies. Notably, the XP-59A, equipped with I-A derivatives, served as a critical training platform for transitioning pilots to jet operations, bridging wartime experimentation to postwar air superiority programs.^[32]^[33]^[34] Beyond GE's trajectory, the I-A symbolized rapid wartime innovation that contrasted sharply with the Axis powers' lagged jet advancements, where German efforts like the Junkers Jumo 004 faced chronic material shortages—particularly nickel for turbines—and production bottlenecks, limiting operational deployment until late 1944. The U.S.-UK alliance's emphasis on secrecy around the I-A not only safeguarded intellectual property but also fostered enduring transatlantic aerospace cooperation, mitigating risks from espionage and resource constraints like alloy availability during global shortages. As a foundational artifact of American engineering resilience, the I-A's legacy endures in its role as the catalyst for the turbojet revolution, enabling the U.S. to dominate post-war aviation and sustain technological edges through the Cold War and beyond.^[35]^[4]

References

[1]
Aviation History - GE Aerospace
The I-A engine incorporated a centrifugal-flow compressor, as did the increasingly more powerful engines developed by GE during the next two years, culminating ...
[2]
General Electric I-A Turbojet Engine | National Air and Space Museum
Two General Electric Type I-A turbojet engines powered the first American jet aircraft, the Bell XP-59A, which first flew on October 2, 1942, near Muroc, ...
[3]
General Electric Engines - Centennial of Flight
Six months later, on April 18, 1942, GE's engineers successfully ran their I-A engine—the first jet engine to operate in the United States. On October 1, 1942, ...
[4]
General Electric J31 - Air Force Museum
The J31 (General Electric designation I-16) was the first turbojet engine produced in quantity in the United States.
[5]
Whittle W.1X Engine | National Air and Space Museum
2B production engine were delivered to the General Electric Company on October 1, 1941. GE's improved and uprated version, the IA, powered the first U.S. ...
[6]
Frank Whittle and the Race for the Jet - HistoryNet
Jan 19, 2017 · Whittle can justifiably be called the “father of the jet.” He was the first to build and run a turbojet aero engine.
[7]
Birth of the American Jet Age - HistoryNet
Feb 7, 2020 · Gen. Henry H. “Hap” Arnold, the commanding officer of what at the time was the Army Air Corps, visited England in the spring of 1941 to ...
[8]
Mr. Whitely's (make that “Whittle”) secret stay in Lynn - GE Aerospace
Feb 7, 2019 · For several weeks in 1942, Whittle was secretly involved in bringing GE's Lynn, Massachusetts, plant, as well as the USA, into the jet age as well.Missing: HMS Viking
[9]
GE I-A Whittle Gas Turbine Engine - Combat Air Museum
The GE90-115B, the world's largest and most powerful jet engine today, can produce 127,900 pounds of thrust, over 100 times as great as the Type I-A. GENERAL ...
[10]
G.E. Engineers Test Jet Engine - Mass Moments
On this day in 1942, after months of highly secret work, GE engineers in Lynn successfully tested the engine they called by the innocuous name I-A.
[11]
How the Bell P-59 Airacomet Became America's First Jet Fighter
Mar 7, 2022 · It was the Gloster E.28/39, powered by a W.2B turbine engine developed by RAF Commander Frank Whittle, who had been granted the world's first ...
[12]
Bell XP-59A Airacomet | National Air and Space Museum
Two General Electric Type I-A centrifugal-flow jet engines drove the unrefined XP-59A airframe to a maximum speed of only 628 kph (390 mph). A number of ...
[13]
GE Lifts the U.S. Into the Jet Age | GE Aerospace News
May 3, 2019 · On October 1, 1942, a Bell XP-59A Airacomet powered by two GE IA turbojet engines roared down a remote runway at Muroc Dry Lake in California and slowly lifted ...
[14]
[PDF] CURRENT AND FUTURE USAGE OF MATERIALS IN AIRCRAFT ...
Feb 1, 1970 · Materials trends in turbojet and turbofan engines built by General Electric Company indicate some interesting progressions in materials usage ...
[15]
[PDF] The Power for Flight: NASA's Contributions to Aircraft Propulsion
in Virginia, NACA engineers created a “propeller research airplane” by install- ... W.1X (Whittle), 28. W.2B (Whittle), 28. Wasp radial, 26. Wasp supercharger, 14 ...
[16]
Challenges - Sir Frank Whittle - inventor of the jet engine
Whittle faced initial calculation errors, the choice between axial and centrifugal compressors, and lost time due to Rover's control of his engine production.Missing: IA | Show results with:IA
[17]
[PDF] J33/I-40* Turbo Supercharger Jet Engine
Sep 6, 2024 · Of note, the Bell XP-59 was the first aircraft to fly with the. US version of the Whittle engine, the GE I-A (later known as J31) in Oct 1942.
[18]
Engine, General Electric J31-GE-3 (I-16-3) Turbojet
GE followed with two designs of increased thrust; first the I-14 (aimed at 6,227 N (1,400 lb.) thrust) and then with the I-16. The J31-GE-3 (I-16-3) was an Air ...Missing: derivatives | Show results with:derivatives
[19]
P-59 Airacomet - GlobalSecurity.org
The I-A engine was an American adaptation of the British Whittle W-1B engine and subsequent models of it, such as the I-14 (1400 pounds of static thrust) and ...
[20]
General Electric J31-GE-4 or -5 (I-16-4 or-5) Turbojet Engine
GE followed with two designs of increased thrust; first the I-14 (aimed at 6,227 N (1,400 lb.) thrust) and then with the I-16. The J31-GE-4 or -5 (I-16-4 or ...Missing: derivatives | Show results with:derivatives
[21]
Bell XP-59 & XP-83 - AirVectors
Jul 1, 2024 · In September 1942, the first XP-59A was shipped off by train from the Bell plant in Rochester, New York, to Muroc Army Air Field (now Edwards ...
[22]
America's First Jet: Inside the Surviving Bell P-59 Airacomets
Jul 21, 2025 · In all, a total of 66 Bell P-59 Airacomets were built from 1942 to 1944, with three XP-59A prototypes, 13 YP-59A pre-production aircraft, and 50 ...
[23]
Special Projects Laboratory - Early Jet Engines - NASA
The Jet Propulsion Static Laboratory (JPSL) was hurriedly built in 1943 to secretly test early US jet engines and afterburners during World War II.
[24]
Bell P-59B Airacomet - Air Force Museum
Designed and built in great secrecy during World War II, the P-59 was America's first jet aircraft. · The P-59 was powered by two General Electric turbojets ...Missing: disguise | Show results with:disguise
[25]
Disguising the Airacomet | National Air and Space Museum
To confuse enemy spies from seeing America's first jet aircraft, U.S. Army Air Forces' personnel added a fake propeller to the Bell XP-59A Airacomet when it ...Missing: P- | Show results with:P-
[26]
XP-59A Airacomet: The First American Jet Began As A Secret Program
Sep 29, 2012 · Bell XP-59A being towed at Muroc Dry Lake, Calif. Note the false wooden propeller designed to conceal the jet engines during ground towing.<|separator|>
[27]
American jet aircraft Bell P-59A Airacomet - Military Review
Feb 25, 2013 · The unreliable operation of fuel pumps, the destruction of turbine blades and overheating of bearings, remain the main shortcomings of the ...
[28]
Gas Turbine Technology Evolution: A Designer's Perspective
The normal compressor oper- ating line and stall line (a compression limit) is shown as a function of pressure ratio and airflow in Fig. 16. Lessons learned ...Missing: partition | Show results with:partition
[29]
[PDF] The Early History of the Whittle Jet Propulsion Gas Turbine
When the W1 was delivered, it was stripped by Power Jets, and was modified to incorporate the latest experience gained with the W1X. Eventually, after certain ...
[30]
The turbojet engine that launched the U.S., GE into the jet age ...
GE Aviation's Type 1-A turbojet engine, designed to power the highly secret XP-59A aircraft, celebrates the 75th anniversary of its inaugural flight ...
[31]
TurbojeT engines - ASME Digital Collection
– Thrust specific fuel consumption of 1.6 kg/kg-h (about 15% worse than on the ground at the test stand). Table 11-1. Jumo 004 B-1 production engine's ...<|separator|>
[32]
Jet Engines Mature | Glenn Research Center - NASA
Aug 8, 2024 · The performance of jet engines increased dramatically in the late 1940s and early 1950s. ... specific fuel consumption at 80,000 feet. They then ...
[33]
Display Engines | Valiant Air Command, Inc.
General Electric I-1A. Alison TF-41. Pratt & Whitney F100. Pratt ... Museum Location. 6600 Tico Road,. Titusville,. Florida. 32780. warbirds@valiantaircommand.com.Missing: IA | Show results with:IA
[34]
GE History Aerospace | General Electric
GE builds the first US jet engine, the I-A. It's used the following year to power America's first jet aircraft for military use, the Bell P-59 Airacomet ...<|control11|><|separator|>
[35]
General Electric Pioneers Jet Engine Manufacturing | 2017-03-28
Mar 28, 2017 · General Electric uses Boeing 747s to test its new jet engine designs. The new GE93 turboprop engine will use a wide variety of 3D-printed ...
[36]
The Trailblazing GE90, For Decades The World's Most Powerful ...
The GE90 engine held the record as the world's most powerful jet engine for nearly 15 years, clocking in at 127,900 pounds of sustained thrust in 2002. This ...<|separator|>
[37]
[PDF] Engines and Innovation - NASA
A heavily guarded truck delivered the General Electric I-A for testing.7 The Static Test. Laboratory consisted of spin pits lined with wood to protect ...