Fact-checked by Grok 2 weeks ago

John Stringfellow

John Stringfellow (1799–1883) was a British engineer and aviation pioneer renowned for his pioneering work in powered flight, including the construction of the first successful steam-powered model aircraft in 1848.^[1] Born on December 6, 1799, in Attercliffe near Sheffield, Stringfellow apprenticed in the lace-making trade and later became a skilled machinist specializing in lightweight steam engines.^[1] He relocated to Chard, Somerset, where he worked at Oram's Lace Mill while pursuing aeronautical experiments.^[2] Stringfellow's interest in flight began in the early 1830s with experiments involving hot-air balloons, one of which traveled over four miles in 1832, and later work on clockwork and rubber-band powered model aircraft.^[1] By 1840, he collaborated with fellow engineer William Samuel Henson, studying bird flight through observation and taxidermy to inform wing designs.^[2] Together, they patented the "Aerial Steam Carriage" in 1842, a visionary monoplane concept powered by a steam engine, though full-scale construction proved challenging due to technological limitations.^[3] The partnership led to the formation of the Aerial Transit Company in 1843, aimed at developing passenger-carrying aircraft, but Henson departed for the United States in 1848.^[3] Stringfellow's breakthrough came in 1848 when he built a 10-foot-wingspan model aircraft with contra-rotating propellers and a lightweight steam engine, achieving the first recorded powered flight indoors at Chard's Oram's Mill, covering approximately 30 to 40 feet.^[1] An outdoor attempt with a larger model on nearby Bewley Down that year failed due to adverse weather.^[2] His innovations continued into the 1860s; in 1868, he constructed a steam-powered triplane model that demonstrated sustained flight along guide wires at the Crystal Palace exhibition in London, earning a £100 prize for its exceptional power-to-weight ratio.^[3] Stringfellow's son, Frederick J. Stringfellow, also contributed a tandem-wing monoplane model displayed at the same event.^[3] Beyond aviation, Stringfellow was a polymath who patented galvanic batteries in 1856 and a bullet-protection apparatus in 1869, and he later became a professional photographer.^[1] He was elected a member of the Aeronautical Society of Great Britain (now the Royal Aeronautical Society) in 1868.^[1] Stringfellow died on December 13, 1883, in Chard, leaving a legacy as a foundational figure in aeronautical engineering whose model flights predated manned powered flight by over half a century and inspired future innovators.^[1] His triplane model is preserved at the National Air and Space Museum in Washington, D.C.^[3]

Early Life

Birth and Family Background

John Stringfellow was born on 6 December 1799 in Attercliffe, a suburb of Sheffield, England.^[1] He was the son of William Stringfellow, a cutler by trade, and his wife Martha.^[1] He was one of six children.^[4] Stringfellow's family embodied the working-class milieu of early 19th-century Sheffield, a burgeoning industrial center famed for its cutlery production and metalworking craftsmanship during the Industrial Revolution.^[5] This vibrant engineering environment, centered on skilled fabrication of tools and machinery, offered young Stringfellow initial glimpses into mechanical principles through his father's workshop and the city's innovative workshops.^[1] Lacking formal education beyond rudimentary schooling, Stringfellow cultivated a self-taught aptitude for mechanics from childhood observations of local trades and industrial processes.^[4] This foundational exposure naturally led to his later apprenticeship in the lace trade.^[4]

Apprenticeship and Initial Training

John Stringfellow, born in Attercliffe near Sheffield in 1799, entered the workforce around age 12 as a teenager after he relocated to Nottingham, where he was apprenticed to the local lace trade as a bobbin and carriage maker.^[6]^[1]^[4] This apprenticeship immersed him in the burgeoning machine-made lace industry, a key sector in early 19th-century Nottingham, where he learned the fundamentals of constructing the precise wooden components—bobbins for holding thread and carriages for guiding it through looms—that were essential to lace production.^[6] Through hands-on training, Stringfellow acquired core skills in precision engineering and tool-making, honing his ability to fabricate intricate mechanical parts under the demanding conditions of the era's workshops.^[1]^[7] His early exposure also introduced him to basic principles of machinery operation, including the interplay of gears and levers in lace looms, which cultivated an inventive mindset evident in his adeptness with mechanical systems from a young age.^[7] These foundational experiences in bobbin and machinery construction laid the groundwork for his later engineering innovations, emphasizing accuracy and efficiency in design.^[8] The socio-economic landscape of industrial Sheffield and Nottingham during the 1810s and 1820s profoundly shaped Stringfellow's early career, as the lace trade expanded amid rapid mechanization but faced severe labor challenges, including exhaustive work hours, low wages, and widespread unrest like the Luddite riots that protested machinery's impact on jobs.^[6]^[9] These conditions, marked by turbulent transitions from handcraft to factory production, motivated apprentices like Stringfellow to seek improvements in machinery, fostering a problem-solving ethos that drove minor adaptations to looms during his training to enhance reliability and output.^[6]^[10]

Engineering Career

Move to Chard and Business Foundations

In the early 1820s, John Stringfellow relocated from Nottingham to Chard in Somerset, drawn by the burgeoning lace industry in the West Country, where factory owners sought skilled engineers to install and maintain bobbin-net machinery.^[11] His move, around 1820–1823, capitalized on Chard's emerging status as a lace production hub, where he initially worked fitting machines for local factories such as J. Wheatley & Co.^[1] Leveraging his apprenticeship-honed expertise in lace mechanics, Stringfellow quickly established himself in the town.^[1] By the mid-1820s, Stringfellow founded his own engineering firm specializing in lace machinery, beginning operations in a modest workshop on Chard's High Street, formerly the site of a Friends' Meeting House, and employing local laborers to produce bobbins and bobbin carriages.^[11] This small-scale venture focused on supplying components to the area's growing number of lace mills, marking his transition from journeyman to independent entrepreneur.^[1] Through the 1830s, Stringfellow's business expanded considerably, supporting the operation of 49 bobbin lace machines in Chard by 1827 and contributing to the lace sector's employment of many of the town's approximately 5,000 residents.^[11] In 1834, he was elected to the Chard Council, where he aided local factories in complying with the Factory Act. The firm achieved financial stability, enabling Stringfellow to purchase three terraced houses and a meadow in 1832, followed by acquiring and rebuilding additional properties in 1833 for workshop expansion.^[11] Stringfellow's enterprise played a pivotal role in bolstering Chard's economy, contributing to full employment in local lace factories and ancillary trades like iron founding by the early 1840s, and solidifying the town as a key center for textile engineering innovation.^[11]

Innovations in Lace Machinery

John Stringfellow's contributions to lace machinery were rooted in his mechanical expertise, honed during his apprenticeship in Nottingham's lace trade and applied after his relocation to Chard around 1820. There, he established a specialized business manufacturing bobbins and bobbin carriages—critical components for the bobbin-net machines that produced intricate lace fabrics by traversing threads in complex patterns.^[1] These elements formed the core of automated lace looms, where carriages guided multiple bobbins along guides to interweave warp and weft without hand-knotting, a process that had revolutionized textile production since the early 19th century.^[12] Stringfellow's improvements focused on enhancing the reliability and efficiency of bobbin-winding mechanisms, which prepared threads onto bobbins with uniform tension to prevent breakage during weaving. By refining the winding apparatus, he minimized manual intervention in thread loading and alignment, allowing operators to oversee larger setups with less frequent adjustments. His designs emphasized compact gearing systems, using meshed wheels and levers to synchronize bobbin movements precisely, which reduced friction and operational downtime in the looms.^[8] This approach addressed common issues in early lace machinery, such as misalignment from heavy components, enabling smoother automation of the weaving cycle.^[1] In constructing these parts, Stringfellow employed lightweight materials like seasoned wood for carriages and lightweight metals for pins and guides, which decreased the inertial load on the machines and facilitated faster pattern changes. Such innovations supported the scalability of lace production in Chard's factories, where his business became a key local supplier, sustaining an industry that employed a significant portion of the local workforce by the mid-19th century and contributed to Somerset's economy.^[2] The engineering principles of precision mechanics and efficient force transmission developed here directly prefigured Stringfellow's later aeronautical work, where analogous lightweight structures and geared propulsion systems powered model aircraft.^[8]

Aeronautical Pioneering

Collaboration with William Samuel Henson

In the early 1840s, John Stringfellow, a skilled engineer specializing in lace-making machinery, was approached by William Samuel Henson, an inventive engineer and manufacturer also involved in the lace industry, to collaborate on ambitious ideas for powered flight. Their partnership began around 1840 in Chard, Somerset, where both men resided and shared a fascination with aeronautics, initially focusing on studies of bird flight to inform mechanical designs.^[8]^[13] The collaboration leveraged complementary strengths: Henson provided conceptual designs inspired by emerging theories of aerodynamics, while Stringfellow contributed practical mechanical expertise honed through years of innovating high-precision machinery. This synergy allowed them to translate theoretical notions into feasible engineering plans, marking a significant step toward realizing manned powered flight. Stringfellow's background in constructing intricate lace engines proved essential, enabling the duo to address the challenges of lightweight propulsion systems.^[14]^[7] By 1843, their partnership formalized into the Aerial Transit Company, a joint venture established with two additional associates to develop and commercialize flying machines for public transport. The company aimed to raise capital through subscriptions and demonstrations, securing initial funding to support prototype construction and promotion efforts, though broader investor enthusiasm proved elusive.^[13]^[8] Their shared vision drew heavily from Sir George Cayley's pioneering glider experiments and writings on lift and aerodynamics, which provided a scientific foundation for sustained flight. Contemporary advancements in steam engine efficiency further fueled their optimism, as they sought to adapt compact, high-power boilers to aviation applications, envisioning a new era of rapid aerial travel.^[14]^[13]

Development of the Aerial Steam Carriage

In collaboration with William Samuel Henson, John Stringfellow co-developed the Aerial Steam Carriage, a pioneering steam-powered monoplane design intended for passenger transport.^[8] The invention was patented under British Patent No. 9478 on September 29, 1842, describing a full-scale aircraft with a 150-foot wingspan, twin propeller propulsion driven by contra-rotating airscrews, and a wheeled undercarriage for takeoff and landing.^[15]^[16] The design featured a lightweight wooden frame constructed from bamboo spars and ribs, with rectangular cambered wings covered in oiled silk fabric for aerodynamic efficiency and water resistance.^[8]^[13] At the heart of the machine was a compact 30-horsepower steam engine, engineered by Stringfellow including boiler and accessories, enabling a total aircraft weight of approximately 3,000 pounds while providing sufficient thrust for sustained flight.^[16]^[17] The fuselage included an enclosed cabin for 10-12 passengers beneath the wing, with pilot-controlled tail surfaces for stability and steering via rudders and elevators.^[8] Stringfellow and Henson addressed key engineering challenges by drawing on Sir George Cayley's principles of aerodynamic lift, calculating that the large wing area would generate sufficient upward force to overcome the aircraft's weight through forward motion.^[13] Primary hurdles included balancing the steam engine's power-to-thrust ratio against its weight to achieve adequate lift without excessive fuel consumption, as well as ensuring structural stability amid vibration and wind forces on the expansive wings.^[16] These issues were mitigated through innovative lightweight materials and braced frameworks, though the design's reliance on unproven steam technology highlighted the era's limitations in power density.^[8] To promote the Aerial Steam Carriage, Stringfellow and Henson formed the Aerial Transit Company in 1843 and distributed illustrated prospectuses envisioning regular passenger services, such as routes from London to Calcutta, India, covering thousands of miles at speeds up to 50 miles per hour.^[16]^[18] Contemporary lithographs depicted the aircraft soaring over global landmarks like the Pyramids and the Taj Mahal, capturing public imagination and underscoring the invention's ambitious scope for commercial aviation.^[19]^[20]

Key Achievements in Flight

The 1848 Model Experiment

In 1848, John Stringfellow conducted a pivotal experiment with a scaled-down model based on the Aerial Steam Carriage design, aiming to validate the feasibility of powered, heavier-than-air flight. The model featured a wingspan of 10 feet (3 meters), a lightweight structure primarily constructed from wood, silk, and wire, and was powered by a compact steam engine. The total weight of the model, including the engine, boiler, fuel, and water, was about 23 pounds (10.4 kg). To ensure controlled testing and protect the apparatus from wind, Stringfellow set up a 30-yard (27-meter) inclined wire guide within an unused section of his lace factory in Chard, Somerset, allowing the model to launch and glide along the taut wire for stability.^[12]^[21]^[22] In 1848, the model was successfully launched, achieving a short powered glide along the 30-yard wire guide, covering the distance in a few seconds at observed speeds, as witnessed by local individuals including factory workers, as later corroborated by accounts from figures such as Northcote Spicer. This brief but controlled flight demonstrated the model's ability to generate sufficient lift and forward propulsion through steam power, marking it as the first documented instance of successful powered model aviation. The experiment's immediate outcome was confirmation that a steam-driven apparatus could sustain flight, inspiring further refinements despite its tethered nature.^[23]^[24]^[11] Key technical innovations in the model included a multi-bladed propeller system—consisting of two contra-rotating propellers for efficient thrust—and tensioned wire bracing on the wings to maintain structural integrity and enable subtle control adjustments during flight. These elements addressed stability challenges inherent in early aerodynamic designs. However, the experiment faced limitations, such as rapid engine overheating due to the high heat demands of the miniature boiler, which curtailed flight duration, and the wire guidance itself, which prevented true free flight but still proved the concept of powered lift without external support.^[25]^[22]

Subsequent Aviation Experiments

Following the success of his 1848 model, which demonstrated the first powered, controlled flight of a winged aircraft, John Stringfellow pursued larger-scale experiments outdoors on Bewley Down near Chard, Somerset, during the late 1840s and into the 1850s. These trials involved a 20-foot wingspan monoplane model weighing approximately 30 pounds, with a surface area of 70 square feet, powered by a lightweight steam engine. The outdoor trials were unsuccessful due to adverse weather conditions, including variable wind and rain, preventing sustained flight and leading to the abandonment of extended outdoor testing after several weeks.^[2]^[11] In the 1850s, Stringfellow began collaborating with his son, Frederick John Stringfellow, on iterative designs that incorporated biplane configurations to enhance stability and lift. Together, they constructed several steam-powered biplane models featuring improved multi-unit boilers and contra-rotating propellers, refining aerodynamics through indoor tests at Oram’s Mill in Chard. These joint efforts halved the size of earlier outdoor models for better manageability, achieving level or slightly climbing flights along guide wires over distances of about 30-40 yards, though still constrained by the limitations of steam technology and available workspace. Frederick's involvement extended to completing unfinished biplanes after his father's primary active period, emphasizing lightweight wooden frameworks covered in silk or cotton fabric.^[3]^[11]^[2] A culmination of this work came in 1868, when Stringfellow exhibited a refined triplane model at the first Aeronautical Society of Great Britain exhibition in London's Crystal Palace. The triplane, with superimposed wings spanning approximately 8 feet, 7 feet, and 6 feet (total surface area of 30 square feet and weight of approximately 25 pounds including fuel and water), was powered by a 13-pound single-cylinder steam engine producing about 1 horsepower at 300 rpm. Demonstrated along a taut cable, the model exhibited a tendency to rise above the wire after attaining velocity, showcasing advanced aerodynamics inspired by multi-wing principles, though it did not achieve sustained free flight. For this engine's efficiency—the lightest relative to power output—the Aeronautical Society awarded Stringfellow a £100 prize, recognizing its potential for aerial applications.^[26]^[27]^[11] Despite these advancements, Stringfellow's experiments were hampered by chronic funding shortages following the collapse of the Aerial Transit Company in the 1840s, which had provided initial support, and by material constraints such as fragile silk fabrics and underpowered boilers unsuitable for scaling to full-size manned aircraft. These challenges, combined with the lack of large testing facilities and Stringfellow's health issues, prevented progression beyond models, though the work influenced later pioneers in multiplane design.^[11]^[2]

Other Contributions and Interests

Inventions in Medical Technology

In the 1850s, John Stringfellow expanded his inventive pursuits beyond mechanical engineering into electrical devices, particularly with patents for compact galvanic batteries designed for therapeutic applications. In 1852, he secured British Patent No. 191 for improvements in galvanic batteries intended for medical and other purposes, emphasizing portability and efficiency to make electrotherapy more accessible.^[28] These batteries were constructed as multicell units, allowing for a steady electrical output suitable for personal use, and represented an advancement in miniaturizing galvanic technology derived from his precision engineering background in lace machinery.^[1]^[2] Stringfellow's Patent Electro-Galvanic Portable Battery, as it became known, was specifically marketed for medical treatments involving therapeutic electricity, such as alleviating symptoms of rheumatism and neuralgia through mild galvanic stimulation.^[29] Advertised in prominent medical publications like The Lancet starting in 1853, the device was promoted as a pocket-sized tool that patients could use at home under physician guidance, facilitating non-invasive electrical applications to nerves and muscles.^[30] This portability distinguished it from larger laboratory setups, enabling broader adoption in early electrotherapy practices where direct current was believed to relieve pain and improve circulation in chronic conditions.^[31] The commercialization of Stringfellow's battery involved partnerships with instrument makers, such as Elliott Brothers of London, who served as sole agents and distributed the devices to physicians across Britain.^[30] These sales contributed to the growing acceptance of electrotherapy in the mid-19th century, providing a reliable, compact source of galvanic current that supported clinical and domestic treatments before the widespread availability of more advanced electrical generators.^[1] By focusing on safer, longer-lasting designs, Stringfellow's innovations helped bridge the gap between experimental electrical science and practical medical tools, influencing the development of portable electrotherapeutic devices in subsequent decades.^[2]

Hobby in Photography

In the late 1850s, John Stringfellow developed a keen interest in photography as a pursuit complementary to his engineering endeavors, adopting the wet-plate collodion process pioneered by Frederick Scott Archer around 1851. Self-taught in this complex technique, which required immediate exposure and development of glass plates coated with collodion and silver iodide, Stringfellow established a portrait studio on High Street in Chard, Somerset, where he produced durable negatives suitable for printing and mailing worldwide without damage.^[11] His early advertisements for the business appeared in local publications, such as the Chard Illustrated Magazine in August 1859 and the Chard Chronicle and Advertiser, highlighting various portrait styles including cartes-de-visite.^[11] Stringfellow's photographic work extended beyond commercial portraits to document his aeronautical experiments, capturing images of his model aircraft, such as the 1847-48 monoplane and later triplane designs, often in a controlled studio setup. These photographs served as visual proof of his innovations, shared with Frederick W. Brearey of the Aeronautical Society of Great Britain in correspondence around 1868.^[11] A collection of his glass plate negatives, preserved by the Somerset Archaeological and Natural History Society at Taunton Castle, attests to the technical proficiency he achieved through his mechanical background, which informed stable setups for long exposures.^[11] As a personal outlet amid his intensive inventive pursuits, photography provided Stringfellow with a creative respite in his later years, allowing him to record local scenes and family moments while applying the precision honed in lace machinery and aviation models to refine his equipment. This hobby not only relaxed him but also preserved aspects of his life in Chard, blending artistic expression with his innate engineering aptitude.^[11]

Later Life and Legacy

Involvement with Professional Societies

In his later years, John Stringfellow played a significant role in the nascent field of organized aeronautical research through his involvement with the Aeronautical Society of Great Britain, founded in 1866 as the world's first such organization dedicated to advancing heavier-than-air flight. He was elected a member in 1868, drawing on his decades of practical experience in steam-powered models to contribute to its foundational discussions and activities.^[27]^[32] Stringfellow's most notable contributions came during the society's inaugural exhibition in 1868 at London's Crystal Palace, where he demonstrated a steam-driven triplane model suspended along a wire-guided track, showcasing sustained powered flight and earning a prestigious £100 prize for the best power-to-weight ratio in an aeronautical engine. Over the following years, through the late 1860s and 1870s, he actively participated in society meetings, presenting details of his model flights and innovative engine designs that built upon his earlier 1848 experiments, influencing contemporaries and fostering technical dialogue among engineers. These engagements highlighted his expertise in lightweight steam propulsion, a critical challenge for early aviation.^[26]^[33] Stringfellow also held affiliations with other engineering bodies, including membership in the Royal Society of Arts during the 1870s, where he engaged in discussions on steam technology applications relevant to mechanical invention. By the retirement phase of his career, as recorded in the 1881 census, he was described as a "Retired Mechanician Inventor of Flying Machines," a title underscoring his enduring legacy within these professional circles despite scaling back personal experimentation.^[1]

Family Life and Death

John Stringfellow married Hannah Keetch on 27 February 1827 in Chard, Somerset.^[6] The couple had ten children between 1828 and the 1840s, including six sons and four daughters among the survivors.^[1] Tragically, one son died in infancy, and their daughter Laura succumbed to epilepsy at the age of 29.^[6] Stringfellow's family played a supportive role in his professional life, with his wife Hannah managing household affairs while the children assisted in his workshop.^[6] In particular, his son Frederick John Stringfellow shared his father's passion for aviation and collaborated on experiments, later continuing the work independently after his father's death.^[6] In his later years, Stringfellow retired to Chard, where his health began to decline, notably with failing eyesight by 1868 that limited his ability to pursue further innovations.^[6] He died on 13 December 1883 at the age of 84 and was buried in Chard Cemetery, where a commemorative family monument marks the site.^[6]

Historical Impact on Aviation

John Stringfellow is credited with achieving the world's first recorded powered model flight in 1848, when his steam-driven monoplane achieved short distances of approximately 30 to 40 feet (9 to 12 meters) inside a disused lace mill in Chard, Somerset, predating the Wright brothers' manned powered flight by 55 years. This milestone demonstrated the feasibility of powered heavier-than-air flight using a lightweight steam engine producing about 1 horsepower while weighing just 13 pounds (5.9 kg), marking a pivotal advancement in aeronautical engineering. His experiments emphasized the importance of efficient propulsion and aerodynamic stability in model aircraft, laying empirical groundwork for future developments in aviation technology.^[34]^[2]^[26] Stringfellow's innovations extended beyond technical feats to visionary concepts, notably through his collaboration with William Samuel Henson on the Aerial Transit Company, established in 1843 as an early blueprint for commercial air travel, complete with proposed routes and passenger services that anticipated modern airlines. His work influenced subsequent inventors by showcasing practical powered flight principles; for instance, the Wright brothers drew indirect inspiration from Stringfellow's lightweight steam engines and model designs, which highlighted the need for balanced power-to-weight ratios in aircraft. Although direct lineages are debated, Stringfellow's demonstrations were studied by early 20th-century pioneers, contributing to the evolution of controlled flight mechanics and aerodynamics. Additionally, his son's continuations—Frederick J. Stringfellow built upon his father's biplane models and steam experiments post-1883—represent an underrecognized family legacy that sustained momentum in British aeronautical pursuits amid limited contemporary support. His 1868 triplane model is preserved at the National Air and Space Museum in Washington, D.C.^[8]^[26]^[1] Stringfellow's enduring recognition includes the annual Henson and Stringfellow Lecture and Dinner, inaugurated by the Royal Aeronautical Society's Yeovil Branch in 1956 to honor his and Henson's contributions, featuring prominent speakers on aviation advancements. His achievements were referenced in the 1965 film The Flight of the Phoenix, where a character cites Stringfellow's 1848 model as historical precedent for improvised aircraft construction, underscoring his cultural resonance in popular depictions of aviation ingenuity. In modern scholarship, Stringfellow's steam technology is viewed as foundational to aerodynamics, particularly in validating cambered wings and propulsion integration through iterative model testing, though his underappreciation stems from the era's focus on manned flight over unmanned prototypes.^[14]^[35]^[36]

References

[1]
John Stringfellow - Graces Guide
May 21, 2022 · John Stringfellow (1799-1883) was born in Sheffield and is known for his work on the Aerial Steam Carriage with William Samuel Henson.
[2]
John Stringfellow | Chard Museum
John Stringfellow of Chard was the first to achieve recorded, powered flight. In 1848 they experimented on Bewley Down with a 20 foot model.Missing: biography - - | Show results with:biography - -
[3]
John Stringfellow - England - The Aviation History Online Museum
John Stringfellow, who had grown up in the lace and carriage building industries, had a real appreciation for machines, and most especially for steam engines.Missing: biography - - | Show results with:biography - -
[4]
“Cutlery and Cutlers at Sheffield” in “The English Illustrated Magazine”
Mar 4, 2021 · The manufacture of cutting instruments in some form or other in the Sheffield district, probably dates back to the time of the Roman settlement, ...
[5]
[PDF] In the Cause of Flight - Smithsonian Institution
Born in Attercliffe, England, on 6 December. 1799, Stringfellow served his engineering appren- ticeship in the lace trade at Nottingham, but subsequently ...<|control11|><|separator|>
[6]
12. John Stringfellow Home | Chard Museum
Alongside his everyday job in the lace making industry, in his spare time he developed a passion for aviation, experimenting initial with balloons and gliders.Missing: apprenticeship | Show results with:apprenticeship
[7]
John Stringfellow and Powered Flight • Inventors and Inventions ...
John Stringfellow was born at Attercliffe in Sheffield in 1799 and became an apprentice in the lace trade. His ability with all things mechanical helped him ...Missing: biography - - | Show results with:biography - -
[8]
William Henson and John Stringfellow: Pioneer Aviation Strategists
Jun 12, 2006 · Henson and Stringfellow are remembered today as pioneer strategists who helped convince a skeptical world that the air age was within grasp.Missing: biography - - | Show results with:biography - -
[9]
commercial lace embroidery in early nineteenth- century Ireland and ...
This article traces the connection between the development of commercial lace embroidery in several locations – Nottingham, Essex and Limerick. Despite the fame ...
[10]
Women and Children in the Machine-Made Lace Industry in Britain ...
Working hours were long and toil was exhausting from a very early age. Although female lace workers featured prominently in local struggles, and were often ...
[11]
None
Below is a merged summary of John Stringfellow's business in Chard, based on the provided segments from "An Ancient Air" by Harald Penrose. To retain all information in a dense and organized format, I will use a table in CSV format for key details, followed by a narrative summary that integrates additional context, quotes, and URLs. This ensures all data is preserved while maintaining clarity.
[12]
John Stringfellow | Science Museum Group Collection
John Stringfellow, 1799 - 1883, c. 1820 - moves to Chard, Somerset, which was a centre of lace making. Within a few years establishes his own business.Missing: born October
[13]
William Samuel Henson - Linda Hall Library
May 3, 2024 · William Samuel Henson. MAY 3, 2024. Wlliam Samuel Henson, a British inventor and engineer, was born on May 3, 1812, in Nottingham. Henson was ...
[14]
The Lives and Work of William Samuel Henson and John Stringfellow
Jul 28, 2016 · The Lives and Work of William Samuel Henson and John Stringfellow. Published online by Cambridge University Press: 28 July 2016. A. M. ...Missing: collaboration | Show results with:collaboration
[15]
Patent GB-1842-9478 - Inventing aviation
May 16, 2025 · The power-driven airplane was invented by William Samuel Henson, engineer, of London, England. Previous persons indeed had flown glider ...
[16]
[PDF] The Wind and Beyond - NASA
... John J. Ide, “Report on Visit to England,” 1921 . . . . . . . . . . . . .377. 2-9(c) John J. Ide, “Wind Tunnel at Issy-les-Moulineaux,” 1921 . . . . .380. 2 ...
[17]
The Henson Aerial Steam Carriage - Pioneers Of Aviation
Jun 8, 2015 · Henson received a patent for The Henson Aerial Steam Carriage in 1842—patent #9478—explaining the principle of the machine: “In order that ...
[18]
The Aerial Steam Carriage | MIT ArchivesSpace
In April 1841, William Samuel Henson patented a light-weight steam engine, and with fellow lacemaking-engineer John Stringfellow patented a steam-powered ...Missing: 9483 1842
[19]
The Great Aerial Navigator, Atmospheric Machine! | The New York ...
A pair of English lacemakers-turned-inventors patented their design for a powered aircraft that could carry passengers.
[20]
The Ariel. The first Carriage of the Ærial Transit Company.
Physical Description. Uncolored lithograph of William Samuel Henson and John Stringfellow's aerial steam carriage, the Ariel, flying over a tropical location.Missing: patent 9483 1842
[21]
Early Aeromodeling - Academy of Model Aeronautics
In 1848 John Stringfellow constructed a steam engine monoplane. This aircraft weighed 8 pounds and had a 10-foot wingspan. The model was flown in an unused lace ...Missing: apprenticeship | Show results with:apprenticeship<|control11|><|separator|>
[22]
Steam Aeroplanes. Modern Planes for Sale. - Douglas Self
Sep 20, 2022 · JOHN STRINGFELLOW: 1848. John Stringfellow (1799 - 1883) of Sheffield ... The model had a 10 foot (3m) wingspan, and was powered by a steam engine ...
[23]
Flight Before the Airplane | National Air and Space Museum
Inspired by George Cayley, Stringfellow and fellow experimenter William Samuel Henson (1812-1888), hoped to develop their Aerial Steam Carriage to create ...Missing: met | Show results with:met
[24]
Aeroplane Model - Stringfellow Design, London, England, 1848
Aircraft History: In 1848, John Stringfellow built an experimental model aeroplane powered by a small steam engine. He flew this model along an inclined wire ...
[25]
[PDF] An Historical Perspective of Engine Development through World War I
such as those developed by Englishmen William Samuel. Henson and John Stringfellow (Berliner, pp. ... Vincent met with. Aircraft Production Board members ...
[26]
Stringfellow Steam Engine | National Air and Space Museum
Stringfellow's engine as the lightest in proportion to its power, producing 0.75 kW (one horsepower) for the weight of 5.9 kg (13 pounds).Missing: aerial | Show results with:aerial
[27]
Model Stringfellow's triplane, 1868.
Reproduction model of Stringfellow's model triplane of 1868. John Stringfellow was a founder member of the Aeronautical Society (now the Royal Aeronautical ...
[28]
1852 Patents - Graces Guide
Jul 22, 2025 · To John Stringfellow, of Chard, in the county of Somerset, Engineer, for the invention of improvements in galvanic batteries, for medical and ...
[29]
Elliott Brothers - microscopist.net
The Lancet (1853) Advertisements for Stringfellow's Patent Electro-Galvanic Portable Battery, multiple issues. The London Gazette (1870) Dissolution of ...
[30]
Elliott Brothers - Graces Guide
Jul 28, 2025 · Stringfellow's Patent Electro-Galvanic Pocket Battery. For personal medical use. Sole agents. W. Elliott and Sons, 56 Strand. 1853 ...
[31]
The Medical Battery in The United States (1870–1920)
Mar 16, 2017 · that its medical battery cured “Rheumatism, Neuralgia, Constipation, Nervousness,. Headache, Stomach Trouble or any other disease” (Figure 4).
[32]
History - Royal Aeronautical Society
The Royal Aeronautical Society was formed in 1866 so it celebrated its 150th anniversary in 2016. Find out how the RAeS supported the pioneers of flight.
[33]
Part 1 - The early years - The Royal Aeronautical Society
Jan 12, 2016 · ... John Stringfellow, who exhibited a steam-driven triplane model. Early Inventions and Theories. Members of the Aeronautical Society of Great ...
[34]
First powered flight - New Scientist
In June 1848, inventor John Stringfellow achieved the seemingly impossible when his steam-powered aeroplane flew the length of a disused lace mill in the centre ...Missing: business | Show results with:business
[35]
Celebrating 62nd Henson & Stringfellow Lecture and Dinner
Jul 14, 2017 · The RAeS Yeovil Branch celebrated its 62 nd Henson & Stringfellow Dinner and Lecture in the Fleet Air Arm Museum (FAAM) at RNAS Yeovilton.
[36]
Greatest Last Film Lines - The 1960s - Filmsite.org
The Flight of the Phoenix (1965). - "How far did you say that Henson and Stringfellow flew that rubber-powered model in 1851, Mr. Dorfmann?" - "Six hundred ...<|control11|><|separator|>