Fact-checked by Grok 2 weeks ago

Jet pack

A jet pack, also known as a rocket belt or rocket pack, is a portable, wearable device typically strapped to a person's back that uses jet or to enable short-duration flight or hovering through the air. Jet packs employ various methods, such as engines using monopropellants like that decompose into high-velocity steam and oxygen via a , or engines that compress air, mix it with fuels such as , and expel the combusted gases from nozzles, often located at the wearer's shoulders and hips for directional control. While popularized in science fiction and media as a of futuristic personal mobility, real-world jet packs have historically been limited by short flight times—often under a minute—high consumption, and significant operational hazards, restricting their use primarily to demonstrations, tests, and specialized applications. The concept of the jet pack originated in 1919 when Russian inventor Alexander Andreev proposed a rocket pack design powered by a combination of oxygen and methane for thrust. Early development accelerated during the mid-20th century amid Cold War-era interest in personal flight technology, leading to the creation of the first functional prototype: the , developed by Bell Aerosystems in the late 1950s using concentrated as a monopropellant that decomposed into steam and oxygen for propulsion. This device achieved its first untethered flight on April 20, 1961, when test pilot Harold "Hal" Graham covered approximately 112 feet (34 meters) in 13 seconds near , marking the first true manned jet pack flight. Subsequent advancements diversified jet pack designs, including water-jet variants like the Jet Lev, which uses a hose connected to a to propel the rider upward with high-pressure water streams rather than onboard fuel. In space exploration, pioneered the (MMU) in the , a nitrogen-gas that allowed astronauts like to perform untethered spacewalks during missions, achieving stable propulsion in microgravity for up to 90 minutes per tank. Despite these milestones, jet packs have seen limited commercial adoption due to engineering challenges, but innovations as of 2025—such as turbine-powered models and electric ducted fans from companies like Jetpack Aviation—signal a resurgence, with prototypes demonstrating flights of several minutes and potential for applications. As of 2025, the wearable jetpack market is expanding, projected to reach $5.7 billion by 2033.

Definition and Principles

Overview

A is a propulsion device, typically worn on the back like a , that enables short-duration flight through the air or in space via directed or . This allows an individual user to achieve vertical takeoff, hovering, and controlled movement without reliance on external structures or vehicles. The core components of a jet pack include a system—such as engines, thrusters, or ducted fans—that generates the necessary ; or tanks to supply the system; control mechanisms like hand-held throttles, gyroscopic stabilizers, or arm-mounted gestures for directing flight; and a structural frame with harnesses to secure it to the user's . These elements work together to provide stability and maneuverability during operation, though flight times are generally limited to minutes due to constraints and considerations. Jet packs differ from related aerial devices such as wingsuits, which enable unpowered from , or drones, which offer remote-controlled flight without an onboard human pilot; instead, jet packs emphasize autonomous, powered personal locomotion.

Physics of Flight

The operation of a jet pack relies on Newton's third law of motion, which states that for every action, there is an equal and opposite reaction. In jet packs, is generated by expelling a high-velocity stream of exhaust gases—typically from a or engine—downward, producing an upward reaction force that propels the user. This principle applies universally to jet pack propulsion systems, whether rocket-powered or turbine-based, enabling vertical takeoff and sustained flight. The magnitude of the thrust force F is given by the equation F = \dot{m} v_e, where \dot{m} is the mass flow rate of the exhaust and v_e is the exhaust velocity relative to the jet pack. For stable hovering, this thrust must balance the user's weight, such that F = mg, where m is the total mass (user plus jet pack) and g is gravitational acceleration (approximately 9.81 m/s²). Achieving this balance requires precise control of exhaust flow and velocity, as any imbalance results in acceleration or descent. Maintaining stability during flight presents significant challenges, as the user must control orientation in three axes: , yaw, and roll. Without stabilization, the jet pack is prone to tumbling due to from uneven or external disturbances like wind. Solutions include gimbaled thrusters, which the exhaust direction to counteract rotations, or proposed advanced gyroscopic controls, such as control-moment gyroscopes (CMGs) in research concepts, that provide through for . These systems demand rapid response times to ensure the center of mass remains aligned with the . Energy efficiency in jet packs is quantified by specific impulse (I_{sp}), which measures per unit of consumed per second, typically around 150 seconds for monopropellant systems used in early rocket-powered jet packs, with variations depending on the and . A high I_{sp} indicates better fuel economy, allowing longer flight durations, but jet packs require a minimum of at least 1:1 for takeoff and hovering, often exceeding 1.5:1 for maneuverability. Additionally, aerodynamic opposes motion, modeled by the equation F_d = \frac{1}{2} \rho v^2 C_d A, where \rho is air , v is , C_d is the , and A is the reference area; at low speeds typical of jet pack flight, drag is relatively minor compared to but increases quadratically with , influencing demands.

History

Early Concepts

The earliest conceptual designs for jet packs emerged in the early amid advancing rocketry and experiments. In , Russian inventor Fedorovich Andreev patented the first known rocket pack, consisting of a backpack-mounted fueled by and to generate for short flights. The design incorporated small stabilizing wings to aid control and balance, though it was never constructed due to technological constraints of the era. Andreev's was praised by contemporary expert Nikolai Rynin for its potential in military applications, such as enabling soldiers to leap over obstacles. During the and , significantly amplified interest in jet pack concepts, bridging fiction and engineering aspirations. Pulp magazines, particularly Hugo Gernsback's Amazing Stories, featured rocket backpacks in serialized adventures, most notably in the debut of in the August 1928 issue, where the character used a similar device for . These stories inspired real-world inventors by portraying jet packs as practical tools for personal mobility, fueling patents and sketches despite the lack of viable materials or propulsion systems at the time. Gernsback's publications, as the founder of modern , played a pivotal role in disseminating these ideas to engineers and the public. In the during the 1930s, engineers built on early liquid-fueled rocket concepts like Andreev's, exploring applications for personal flight amid broader rocketry advancements. The establishment of the Reactive Scientific Research Institute (RNII) in 1933 marked a key effort in developing liquid-propellant engines using oxygen-methane mixtures, with stabilizing features such as wings considered for manned devices to enhance during ascent. These experiments, though focused primarily on larger rockets, laid foundational work for individual propulsion systems but remained theoretical due to fuel instability and material limitations. Pre-World War II, the U.S. Navy expressed interest in personal flight devices for naval operations, such as rapid troop deployment from ships, leading to exploratory patents in the late . However, these efforts were unrealized owing to inadequate lightweight materials and reliable thrust control, shifting focus to conventional until postwar developments. This conceptual phase highlighted jet packs' allure for utility despite persistent engineering hurdles.

20th Century Prototypes

The development of functional jet pack prototypes in the 20th century began in the 1950s with early experiments leveraging hydrogen peroxide as a monopropellant for short-duration lifts. These initial efforts built on wartime rocket technologies but were limited by rudimentary control systems and fuel efficiency. In the 1960s, Bell Aerosystems advanced the field with the Rocket Belt (RB-2000), a hydrogen peroxide-powered device designed for short hops. The system used pressurized nitrogen to feed 90% pure peroxide into a catalytic chamber, generating steam thrust up to 1,000 pounds for brief flights. The first untethered flight occurred in 1961 by test pilot Harold Graham, covering 113 feet at 10 mph over 13 seconds. Bill Suitor, hired as chief test pilot in 1964, conducted the first public demonstration in 1965 at the Niagara Falls Air Show, achieving flights of about 30 seconds duration and reaching altitudes of up to 10 meters. Over his tenure until 1970, Suitor completed more than 200 flights with the Rocket Belt, showcasing its potential for controlled maneuvers despite the need for a support crew to handle the 125-pound unit and its fuel. A tethered variant, the Bell , emerged in 1964 specifically for U.S. Army evaluation. This single-person lift device, also peroxide-fueled, allowed sustained hovers and reached heights of 15 meters during tests at , , demonstrating feasibility for rapid vertical mobility. The Army conducted trials to assess its utility for crossing obstacles or short , but interest waned due to safety concerns and operational complexity. By the 1970s and , private ventures like Powerhouse Productions continued peroxide-based rocket belt development for and limited applications, performing over 100 flights in shows and trials. These devices retained the core Bell design but emphasized reliability for public demos, such as those at air shows. Concurrently, Jetpack International introduced turbine-powered innovations, including the JB-7 variant in the late , which shifted to kerosene-fueled mini-turbines for potentially longer endurance while maintaining backpack portability. The U.S. Army explored these for roles during the era, conducting trials to evaluate soldier-borne flight for scouting in rugged terrain, though such programs were ultimately discontinued due to persistent challenges. A primary limitation across these prototypes was fuel constraints, restricting flight times to 20-30 seconds per tank, as or early turbine fuels burned rapidly—often at 2.5 pounds per second—without viable means for safe, extended storage or mid-air refueling. This curtailed practical applications, confining use to demonstrations and tests rather than sustained operations.

Post-2000 Developments

The post-2000 era marked a transition in jet pack development from experimental rocket-based systems to more reliable -powered and hybrid designs, building briefly on 20th-century rocket technology for improved endurance and control. In the 2000s, companies like Jetpack International advanced , culminating in the JB-9 jet pack, a backpack-style device with twin engines capable of 10-minute flights at speeds up to 80 mph. David Mayman, the company's founder and , demonstrated the JB-9's capabilities in a landmark 2015 flight over , circling the at altitudes of 300-500 feet while maintaining stable hover and directional control through body movements. The 2010s saw further innovation with wing-assisted systems, exemplified by Yves Rossy's Jetman project, which integrated four JetCat P200 turbine engines into a rigid carbon-fiber wing pack weighing 55 kg. Rossy achieved the first jet wing crossing of the on September 26, 2008, covering 35 km in 13 minutes at an average speed of 200 km/h after deploying from a Pilatus Porter at 2,500 meters. Later demonstrations, such as a 2015 formation flight alongside an over , highlighted the system's precision and safety features, including a for emergencies. These advancements incorporated lightweight composites for structural integrity and electronic stabilization to enhance pilot intuition and reduce fuel consumption. Entering the 2020s, arm-mounted turbine designs emerged as a focus for agility, with Richard Browning's Gravity Industries developing the Jet Suit featuring five micro- engines distributed across the body for intuitive . Browning set the Guinness World Record for the fastest speed in a body-controlled jet-engine-powered suit at 85.06 mph (136.89 km/h) on November 14, 2019, during a controlled run at an English lake, surpassing prior benchmarks through optimized arm-based controls. The suit's design emphasized human , allowing flights of up to 5 minutes with rapid directional changes. By 2024-2025, jet pack technology evolved toward scalable platforms, as seen in JetPack Aviation's Speeder, a one-person turbine-powered craft selected in 2021 for the U.S. Air Force's AFWERX High Speed Concept Challenge in collaboration with U.S. Command. The Speeder underwent flight trials, achieving tethered hovers and demonstrating potential for military applications like rapid insertion, with ongoing evaluations focusing on its 150 top speed and 30-minute . Market projections indicate the flying jetpacks sector will grow from USD 300 million in 2024 to USD 1.5 billion by 2033, driven by a of 18.3%, fueled by interest and recreational adoption. Throughout this period, a key technological shift involved the adoption of advanced carbon-fiber composites and integrated electronics, reducing overall weight by up to 40% compared to earlier metal frames while enabling real-time flight computers for automated stability and modulation. For instance, Rossy's carbon-fiber wings provided rigidity without excess mass, and modern suits like the Jet Suit incorporate gyroscopic sensors and systems for precise control, paving the way for safer, more accessible personal flight. In November 2025, a team at demonstrated a functional jetpack using micro-turbine engines, capable of stable flight and hovering.

Types of Jet Packs

Rocket-Powered Designs

Rocket-powered jet packs generate through chemical , relying on exothermic reactions to produce high-velocity exhaust gases. Monopropellant systems, such as those using high-concentration (H₂O₂), decompose the fuel over a to yield steam and oxygen, creating without requiring separate oxidizers. Bipropellant configurations, conversely, combine a fuel like with an oxidizer such as in a for higher energy release. A prominent historical example is the , developed by Bell Aerosystems in the early 1960s for the U.S. Army. This device employed a monopropellant system, delivering approximately 1,000 pounds-force (4,448 N) of from two arm-mounted nozzles, enabling short flights of up to 21 seconds over distances of about 120 meters at heights reaching 18 meters. These designs offer advantages including exceptionally high thrust-to-weight ratios, potentially up to 10:1 for the propulsion unit, allowing rapid vertical takeoff and maneuverability in short bursts. However, drawbacks include the use of toxic and corrosive fuels like , which pose handling and safety risks, and extremely limited operational durations typically under one minute due to rapid fuel consumption. One early conceptual example incorporating wings for extended gliding is the 1919 design patented by Russian inventor Alexander Fedorovich Andreev, which proposed a bipropellant pack using liquid oxygen and methane to power small attached wings, aiming to prolong flight beyond pure thrust phases—though it was never constructed. In modern times, rocket-powered jet packs have become rare, largely superseded by turbine-based alternatives owing to persistent challenges with fuel storage, toxicity, and the logistical complexities of managing volatile chemical propellants in portable systems.

Turbine-Powered Designs

Turbine-powered jet packs utilize engines, often micro-turbines such as the JetCat P400, which generate through air intake, compression, , and exhaust acceleration. These engines typically run on or , enabling sustained operation by drawing in ambient air rather than carrying all oxidizer onboard. Some designs incorporate ducted fans driven by turbines for enhanced efficiency in low-speed maneuvers, though pure turbojets dominate for high- applications. These systems offer flight durations of 5 to 10 minutes, significantly longer than rocket-based alternatives due to efficient use, with top speeds reaching up to 100 (161 km/h). is achieved through body-mounted thrusters on and legs, allowing pilots to direct vectors by gesturing, which integrates with engine power for stability. A seminal example is Visa Parviainen's 2005 jet-assisted wingsuit, where two small turbojet engines mounted to the feet provided approximately 35 kg (77 lbs) of total thrust using fuel, enabling powered from a launch for short bursts of 30 seconds, with speeds up to approximately 193 km/h (120 mph) as planned. Another notable prototype is JetPack Aviation's JB-10, introduced in the mid-2010s, featuring twin engines mounted dorsally for untethered flight at up to 124 mph (200 km/h) and altitudes over 12,000 ft (3,658 m), though early commercial efforts faced delays. Advantages of turbine designs include relatively cleaner exhaust compared to chemical rockets, as they produce primarily hot gases without solid residues, and the use of readily available, reusable liquid fuels that support extended missions. However, challenges persist, including extreme noise levels exceeding 120 from exhaust , which can cause hearing damage without protection, and intense heat from turbine exhausts reaching 500-750°C (932-1,382°F), posing burn risks to the and bystanders. As of 2025, iJETPACK's IJ6180 Jetsuit represents a recent advancement, equipping the wearer with six engines for body-controlled flight lasting up to 7 minutes at altitudes up to 15,000 ft (4,572 m), emphasizing compact deployment for training and demonstration purposes.

Hydrojet Systems

Hydrojet systems represent a category of jet packs that rely on water as the propulsion medium, distinguishing them from air- or gas-based designs by their dependence on an aquatic environment. These devices generate through high-pressure water jets expelled from nozzles attached to a wearable or board, with the water pumped from a nearby source—typically a such as a —via a flexible . The of the watercraft powers a pump that draws in and pressurizes lake, river, or water, creating upward or directional force capable of lifting a user several meters above the surface for short flights or hovers. This mechanism allows for seamless transitions between water and air, often starting from a submerged or surface position on water skis or a board. A pioneering example is the JetLev, developed by Canadian inventor Raymond Li, who filed a patent for the concept in 2005 after initial sketches in 2000 and successful thrust testing that year at Canada's National Research Council Institute for Ocean Technology. The JetLev R200 model, for instance, uses a 200-horsepower engine to produce over 400 pounds of thrust, enabling users weighing up to 113 kg to reach altitudes of up to 10 meters at speeds around 40 km/h, with flight durations extending to 2-3 hours on a full of approximately 100 liters of fuel stored in the watercraft. This design separates the heavy and fuel from the user, reducing onboard weight to about 14 kg for the backpack and hose assembly, which enhances maneuverability but requires the tether to remain within 20 meters of the water source. Key variants include the , invented by jet skier Franky Zapata in and commercially launched through his Zapata Racing. Unlike the backpack-style JetLev, the Flyboard attaches directly to the user's feet via a board resembling water skis, with five upward-facing jets channeling pressurized water from a tethered to propel the rider into flips, dives, and sustained hovers up to 10 meters high. This system gained rapid popularity in aquatic sports, with dedicated world championships established by 2012. Zapata's innovations extended to high-profile demonstrations, including a 2019 attempt to cross the using a hydrojet-derived platform, highlighting the technology's potential for extreme aquatic applications despite the initial failure due to refueling challenges. Hydrojet systems find primary use in recreational aquatic sports, such as flyboarding sessions at resorts and marinas, where participants perform over calm waters, often under guided instruction to build balance and control. Their limitations stem from the essential to a water-pumping , restricting operations to bodies of water and rendering them impractical for land-based or untethered flight, with effective ranges limited to the length of 15-20 meters. Safety profiles benefit from the absence of onboard flammable fuels, eliminating and explosion risks common in or designs; however, hazards include if users fall into deep water without immediate rescue, high-pressure impacts causing bruising or cuts, and physical strain from maintaining posture during flight. Proper use of life vests, helmets, and supervised training mitigates these risks, with manufacturers emphasizing swim proficiency as a prerequisite.

Electric and Hybrid Innovations

Electric and innovations in jet packs represent a shift toward sustainable, battery-assisted systems, leveraging advancements in electric motors and to reduce reliance on fossil fuels. These designs typically employ electric ducted fans (EDFs) or ducted propellers, where lithium-ion batteries power brushless DC (BLDC) motors to generate thrust through high-speed fan rotation. Unlike traditional turbine or systems, electric eliminates , enabling cleaner operation suitable for urban or environmentally sensitive applications. A key example is the Skypak V1 developed by Ascend Dynamics, which uses twelve 7-kW BLDC motors in EDF configuration for a total peak output of 84 kW, allowing short-duration flights while weighing just 80 (36 ) for the pack itself. Hybrid variants combine electric elements with turbine assistance to extend flight times, bridging the gap between pure power and fuel-based systems. As of 2025, solid-state batteries approaching 400 Wh/kg in prototypes promise extended flight times of 15-20 minutes, though commercial jetpack integration remains developmental. In 2024, the U.S. Department of Defense advanced all-electric personal flight testing through , collaborating with contractors on backpack-style systems for military applications, emphasizing modularity and rapid deployment. These innovations offer zero emissions and significantly quieter operation compared to turbine-powered predecessors, with noise levels reduced by up to 20 due to enclosed fan designs, making them viable for recreation. Despite these benefits, challenges persist, primarily from limitations, currently around 250 Wh/kg for high-performance lithium-ion cells—far below jet fuel's 12,000 Wh/kg—resulting in weight penalties that restrict flights to 5-10 minutes. The U.S. Space Force's 2024 project by Starfish Space exemplifies adaptation to such constraints in a context, deploying a "jetpack" module to extend orbital maneuvering by up to two years, providing a brief analog for atmospheric systems through efficient electric augmentation. Electric systems achieve an effective equivalent exceeding 400 seconds through motor efficiencies over 90%, outperforming chemical rockets in sustained low-thrust scenarios without mass flow.

Notable Examples

Key Inventors and Prototypes

One of the earliest military-oriented prototypes was the Jump Belt developed under Project Grasshopper by Chemical Corporation engineers in the late 1950s for the U.S. Army, utilizing compressed gas to propel a wearer up to 10 feet for brief hops, marking an initial step toward personal aerial mobility despite its limited duration of 10-15 seconds. This non-peroxide design laid groundwork for subsequent innovations, though it was never deployed operationally due to stability concerns. Pioneering the use of as a , engineer Wendell F. Moore at Bell Aerosystems created the foundational Rocket Belt, with development beginning in the mid-1950s under U.S. Army contracts. The device, weighing about 125 pounds when fueled, decomposed 90% concentrated over silver-gauze catalysts to generate up to 1,050 pounds, enabling controlled flights. Its milestone came on April 20, 1961, when Hal Graham completed the first untethered flight, traveling approximately 112 feet (34 m) forward and 4 feet (1.2 m) high in 13 seconds, demonstrating viability for short-range tactical jumps despite fuel constraints limiting flights to around 21 seconds. 's RB-2000 iteration in later years refined the concept with modern materials, but the original established core principles for rocket-belt technology. In the mid-1950s, Romanian inventor Justin Capră advanced peroxide-based designs with his "flying backpack," an experimental device using decomposition for lift. Capră claimed his design predated and influenced the , though this is disputed and unsupported by evidence. Developed amid communist-era restrictions, the backpack featured a backpack-mounted engine and control vanes but remained a prototype, never commercialized due to funding shortages and political suppression of Capră's work. This effort highlighted peroxide's accessibility for personal flight in resource-limited settings, influencing later Eastern European aviation experiments. Shifting toward wing-assisted propulsion, Swiss pilot and inventor Yves Rossy introduced the Jetman in 2006, a rigid carbon-fiber wingspan of 2.5 equipped with four micro-turbine jet engines producing 200 Newtons of each. Rossy, drawing from his experience as a military jet pilot, controlled the craft through body movements, achieving sustained horizontal flight at speeds up to 200 km/h and altitudes over 1,500 after launching from a host aircraft. The prototype's debut in , , enabled bird-like for 13 minutes, proving the feasibility of fixed-wing jet packs for recreational and . British inventor Richard Browning revolutionized agility in 2017 with the Gravity Jet Suit from his company Gravity Industries, featuring five gas-turbine engines—two backpack-mounted and one on each arm and forearm—delivering over 1,050 horsepower total. The suit's innovation lies in arm-thruster control, where pilots gesture to thrust for precise maneuvers, allowing hovers, sideways flights, and speeds exceeding 80 km/h without wings. Browning's design, inspired by principles, achieved its first public demonstration at the , emphasizing intuitive human-piloted dynamics over automated stability. French inventor Franky Zapata evolved water-jet technology into aerial applications with the in 2010, a platform powered by redirected jetski exhaust for hovering over water. By 2016, he adapted this into the turbine-powered , a with five kerosene-fueled microturbines providing 200 horsepower for vertical takeoff and up to 10 minutes of flight at 150 km/h. The pinnacle came on August 4, 2019, when Zapata successfully crossed the from Sangatte, , to , —a 36 km journey in 22 minutes—using mid-flight refueling from a , validating turbine s for extended-range personal propulsion.

Commercial Products

Commercial jet packs remain a niche market dominated by high-end, limited-production devices aimed at affluent enthusiasts, event performers, and specialized operators. These products emphasize through and , with flight durations typically ranging from minutes to enable controlled, short-range personal flight. Accessibility is limited by steep pricing, often exceeding $100,000 per unit, and requirements for professional instruction or . The JB-11 from JetPack Aviation (formerly associated with Jetpack International developments) is a turbine-powered jet pack featuring six modified engines, each delivering approximately 90 pounds of for vertical takeoff and hovering capabilities up to 10 minutes of flight time on a full load of . Priced at around $250,000, it has been utilized in public events and demonstrations since 2010, including aerial performances that showcase its stability and pilot control via hand throttles. Gravity Industries' Mark 5 jet suit employs five gas turbine engines—two on each arm and one in the backpack—generating over 1,050 horsepower for arm-controlled flight, with typical durations of 3-5 minutes per sortie depending on pilot weight and maneuvers. At $440,000 per unit, the suit is available to qualified buyers, complemented by the company's structured training programs that include tethered simulations and progressive untethered flights to build proficiency. These programs, offered at facilities in the UK and internationally, cost around $40,000 for full certification and emphasize balance and thrust management. The JetLev water-jet system, a tethered hydro-propelled pack connected to a , enables recreational flights up to 30 feet high and speeds of 20-25 mph, with effectively unlimited duration limited only by the watercraft's fuel. Launched for sales in at approximately $150,000 for complete units including the base boat, it targets water sports operators and private owners for leisure use over lakes or coastal areas. Flyboard Air, developed by Franky Zapata of Zapata Racing, is an electric-turbine hybrid hoverboard-style jet pack powered by five compact gas turbines for untethered flight up to 10 minutes and altitudes over 10,000 feet, demonstrated publicly since its 2016 debut with record-setting crossings like the . Priced at about $250,000, production has remained limited to prototypes and custom orders post-2016, primarily for promotional and experimental purposes rather than widespread commercial release. As of 2023, iJETPACK Aeronautics offers body-controlled jet suits for adventure , with portable designs capable of operations up to 15,000 feet, available through certified operators including a flight academy in . These suits, priced in the high six figures, facilitate short experiential flights in controlled environments, expanding access via packages.

Applications

Military and Government Use

The U.S. military's interest in jet packs dates back to the , when the contracted General Corporation to develop the Aeropack, a hydrogen peroxide-powered pack designed to enhance mobility for urban assault and obstacle navigation. The device enabled short-duration flights, with early tethered tests in 1960 demonstrating potential for leaping over trenches or fortifications, but the program was ultimately discontinued due to severe limitations in range and fuel efficiency, typically allowing only 20-30 seconds of powered flight covering about 100 meters. By the 2020s, renewed efforts focused on more advanced designs for . In , the U.S. Air Force and U.S. Special Operations Command selected JetPack Aviation's Speeder, a turbine-powered vertical takeoff and landing () jet pack, for evaluation under the AFWERX High-Speed VTOL Concept Challenge, with evaluations and planned delivery for testing in rapid troop insertion and extraction by early 2025. Similarly, the UK conducted trials in using Gravity Industries' jet suits—turbine-driven exoskeletons—for maritime ship-boarding operations, demonstrating the ability to fly from patrol vessels to target ships over water, enhancing speed and surprise in opposed boardings. Jet pack concepts have also extended to space applications, drawing inspiration from NASA's (MMU), a nitrogen-gas thruster backpack used for astronaut in the 1980s, which influenced subsequent designs for personal propulsion in microgravity. In 2024, the U.S. awarded a $37.5 million contract to Starfish Space for an "" satellite jet pack system, adapting ion thrusters to attach to aging , providing extended maneuverability for deorbiting and collision avoidance to mitigate orbital . Government agencies have provided substantial funding to advance these technologies, with the Defense Advanced Research Projects Agency (DARPA) investing through programs like the Portable Personal Air Mobility Systems (PPAMS), supporting prototypes for quiet, electric-powered flight to improve agility in contested environments. These initiatives often adapt and hybrid systems for military needs, prioritizing and endurance over recreational variants.

Civilian and Recreational Applications

Jet packs have gained popularity in adventure sports, particularly as assists for wingsuit jumping, allowing participants to achieve sustained horizontal flight and extended glide times. In 2007, Finnish athlete Visa Parviainen conducted the first successful powered wingsuit flight using two small engines attached to his boots, reaching horizontal speeds exceeding 255 km/h (160 mph) without significant altitude loss. This innovation built on traditional wingsuit by adding propulsion, enabling greater distances and control, and has inspired subsequent developments in personal flight gear for extreme sports enthusiasts. In tourism, jet packs offer exhilarating aerial experiences over scenic landmarks, attracting thrill-seekers seeking Iron Man-like flights. In Dubai, Jetman Dubai provides guided jet wing flights soaring above the , with sessions typically lasting several minutes and priced around $5,000, combining professional piloting with passenger participation for a premium adventure. These offerings cater to high-end tourists, emphasizing safety briefings and tandem formats to make the technology accessible without prior aviation experience. Jet packs have also featured prominently in entertainment events, enhancing spectacles at major gatherings. JetPack Aviation's JB-10 performed demonstration flights at the 2018 Air Race in , captivating audiences with high-speed maneuvers alongside aerobatic aircraft and showcasing the device's potential for dynamic displays. Similar integrations occur in air shows and promotional events, where jet packs add a futuristic element to crowd entertainment without competing directly with core competitions. Accessibility to recreational jet pack use has improved through certified training programs, making the activity viable for hobbyists. JetPack Aviation offers a two-day pilot training course that includes ground briefings, simulator sessions, and supervised flights on the JB-10, requiring no prior background and culminating in FAA-recognized proficiency for recreational operation. By 2025, the integration of jet pack experiences in adventure parks is projected to grow alongside the broader market, with the global jet pack sector expanding from $0.8 billion in 2024 to $2.2 billion by 2033 at a CAGR of 11.9%, driven by demand for novel attractions in hubs. Recreational jet pack users are predominantly affluent individuals aged 25-45, often and Gen Z adventure enthusiasts who prioritize unique, high-adrenaline activities and possess the for premium equipment and sessions. This demographic favors experiences like those from commercial products such as the JB-10 or jet suits, reflecting a blend of technological curiosity and financial means.

Emergency and Professional Uses

In the realm of , hydrojet-powered jet packs have been trialed for accessing high-rise structures and delivering water directly to blazes. In 2017, Dubai's Civil Defence introduced a system called , utilizing a modified —a water-jet —to elevate firefighters up to 20 meters while connected to a supplying unlimited water via hose. This allowed rapid deployment to coastal or urban fires, bypassing traffic delays and enabling hose positioning at elevated angles for more effective suppression. The technology, adapted from recreational hydrojet systems, demonstrated potential for high-rise scenarios where traditional ladders or helicopters face limitations. Search and rescue operations have explored turbine-powered jet suits to reach remote or rugged terrains swiftly. In 2022, the Great North Air Ambulance Service in the UK conducted trials with Gravity Industries' Jet Suit, a turbine-driven device providing 1,050 horsepower for short flights. A paramedic used it to ascend Helvellyn mountain—a 90-minute hike—in just 3.5 minutes, enabling faster medical stabilization in adverse weather where helicopters struggle. These evaluations highlighted jet packs' maneuverability for precise landings near casualties, potentially reducing response times in mountainous or disaster zones. In settings, jet packs facilitate inspections and access to hazardous structures, minimizing reliance on helicopters. Such applications extend to broader professional uses, like Aviation's jet pack for construction site inspections, enabling hands-free flight to evaluate high or confined areas. Professional training for jet pack operators emphasizes safety and certification to support emergency roles. By 2025, the (FAA) has certified programs for powered-lift devices, including JetPack Aviation's JB-10 turbine pack, requiring pilots to complete structured flight instruction covering propulsion, balance, and emergency procedures. These FAA-approved courses, lasting several days, prepare operators for professional duties like or ops, with certified pilots trained globally. A notable case involved wildfire response in Australia during the 2023 season, amid widespread blazes burning over 84 million hectares in northern Australia. This built on earlier Dubai-style hydrojet adaptations for fire proximity, prioritizing evacuations in remote savannah areas.

Challenges and Limitations

Technical and Safety Challenges

One of the primary technical challenges in jet pack design involves fuel volatility, particularly in rocket-based systems that rely on propellants like . This substance, used in early prototypes such as the , is highly reactive and prone to rapid decomposition, which can lead to uncontrolled explosions or fires if not handled precisely under varying temperatures and pressures. Such instability has historically complicated storage, transport, and ignition processes, limiting operational reliability. In electric and jet packs, overheating poses a significant due to the potential for in lithium-ion cells, where internal short circuits generate escalating heat that can ignite surrounding materials. This hazard is exacerbated during high-power demands, such as sustained , and has been a key concern in aviation-grade systems analogous to those in emerging personal flight devices. Engineers must incorporate advanced cooling and monitoring to prevent cascading failures, though the compact form factor of jet packs restricts implementation. Stability remains a core engineering hurdle, as jet packs lack the inherent aerodynamic surfaces of , placing the full burden of balance on human pilot input or rudimentary controls. Without automated stabilizers, operators struggle to maintain amid thrust imbalances and gusts, often resulting in uncontrolled spins or falls during maneuvers. This human balance limitation underscores the need for intuitive control interfaces, yet cognitive and physical demands frequently overwhelm users in dynamic flight environments. Safety records highlight the inherent risks, with documented fatalities linked to operational errors, such as the 2020 training crash of Jetman pilot Vince Reffet, who fell from 800 feet due to a loss of control during a backflip maneuver. Most incidents stem from fuel mishandling or stability failures rather than structural defects, though comprehensive injury statistics are limited due to the technology's experimental status. To mitigate these dangers, modern designs incorporate gyroscopes for attitude correction, as seen in NASA's , which uses them to stabilize against unintended rotations. Redundant thrusters provide vectors, while mandatory safety gear—including helmets, fire-resistant suits, and harnesses—offers protection against impacts and thermal events. Human factors further compound risks, with acceleration forces reaching up to during rapid ascents or turns, inducing disorientation, reduced , or even temporary loss of akin to G-induced effects in high-performance . These physiological stresses demand rigorous pilot training to counteract vestibular illusions and maintain .

Regulatory and Economic Barriers

The adoption of personal jetpacks faces significant regulatory hurdles, particularly in airspace management and certification. In the United States, devices meeting the criteria of Federal Aviation Regulation (FAR) Part 103 for ultralight vehicles—such as an empty weight of no more than 254 pounds, fuel capacity limited to 5 U.S. gallons, maximum speed of 55 knots, and single-occupant operation—are exempt from FAA pilot certification, airworthiness requirements, and registration. However, ultralights, including qualifying jetpacks, are prohibited from operating in controlled airspace without prior authorization, effectively restricting use near airports and urban areas classified under Class B, C, or D airspace. More advanced jetpacks, like those in the experimental category, require at least a Light Sport Aircraft pilot certificate and compliance with FAA experimental aircraft rules, complicating recreational access. Globally, the absence of standardized licensing persists as a barrier, with no unified framework for personal jetpacks as of 2025. The (ICAO) has advanced guidelines for (AAM) operations, emphasizing integration of electric vertical takeoff and landing () vehicles into , but these do not yet address turbine-powered personal devices like jetpacks specifically, leaving certification to national authorities. This patchwork approach hinders international travel and commercial scaling, as operators must navigate varying rules, such as Europe's EASA requirements treating powered-lift devices under drone or categories. Environmental concerns further impede widespread use, primarily due to emissions and from engines. Jetpacks powered by small turbojets, such as those in the Gravity Industries Jet Suit, consume kerosene-based fuels, generating significant CO2 emissions from . levels often exceed 105 decibels at close range, surpassing urban limits set by bodies like the (typically 65-70 dB daytime averages), potentially violating community noise ordinances and restricting operations in populated zones. Electric or hybrid prototypes aim to mitigate this, but current models remain non-compliant with stringent emission standards for non-road mobile machinery. Economic barriers are pronounced, with high upfront costs limiting accessibility to affluent individuals or institutions. Commercial models like the Jetpack Aviation JB-12 retail for approximately $380,000 per unit, while the Gravity Industries Jet Suit commands around $440,000, driven by specialized engines and materials. Insurance premiums add to the burden, often significantly higher for experimental category operations due to elevated liability risks from unproven technology and potential third-party damage, far surpassing those for standard ultralights. constraints exacerbate scalability, as small-scale production relies on limited suppliers for aviation-grade fuels and components, increasing costs by 20-30% amid global shortages. Progress toward overcoming these barriers includes U.S. exemptions for recreational ultralight operations in , allowing low-altitude flights in rural or designated zones without full certification as of 2025. In the , while no specific jetpack bans exist, 2024 updates to and rules under EASA permit experimental personal flying devices in open categories if under 25 kg, fostering limited testing but not broad adoption.

Future Outlook

Current Market Trends

The global jet pack market, encompassing wearable and flying propulsion devices, is projected to reach approximately USD 450 million in 2025, up from USD 199.8 million in 2021, reflecting a (CAGR) of approximately 22.5% during this period. This growth aligns with broader trends in , where jet packs are positioned as niche tools for recreational flight experiences, though the market remains small compared to larger sectors. Another estimate places the flying jetpacks segment at USD 0.5 billion in 2025, following USD 0.4 billion in 2024, underscoring steady expansion driven by safety improvements and experiential tourism demand. Key players dominate the landscape, with JetPack Aviation having secured military contracts as of 2022 for tactical applications, such as short-range troop mobility, while Gravity Industries leads in jet suit development for both civilian and defense uses. Emerging Chinese firms are gaining traction with electric wearable jet packs. In November 2025, a team from successfully tested a jetpack capable of speeds up to 100 km/h, highlighting advancements in electric propulsion. Investments in the sector have surged, alongside partnerships between jet pack manufacturers and companies to enhance features. Regionally, the Asia-Pacific holds a 22.64% market share in 2025, propelled by tourism hotspots in countries like China and Japan, whereas the United States maintains leadership in military applications, supported by defense funding and testing facilities.

Emerging Technologies

Advancements in battery technology are poised to significantly enhance the performance of jet packs, with solid-state batteries emerging as a key focus for future designs. These batteries promise higher energy densities compared to current lithium-ion systems, potentially reaching 500 Wh/kg or more by the early 2030s, enabling extended flight durations of up to 30 minutes for personal aerial devices. Developers like JetPack Aviation are actively pursuing solid-state integration to overcome the limitations of existing packs, which currently offer low energy density relative to turbine fuels. In aviation applications, solid-state cells could reduce weight while improving safety through elimination of liquid electrolytes, making them suitable for compact jet pack propulsion systems. Integration of is expected to transform jet pack usability by providing autonomous and control features. algorithms can analyze real-time flight data to adjust and , minimizing the risk of during maneuvers and potentially reducing required pilot training from weeks to as little as 5 hours. This -assisted approach, already prototyped in wearable devices, enhances hover reliability and enables smoother transitions between takeoff and cruising, drawing from broader advancements in for aerial . Such systems could democratize access to personal flight by automating complex piloting tasks, similar to enhancements in larger . Hybrid designs, exemplified by JetPack Aviation's Speeder, represent a shift toward more versatile personal flight vehicles that blur the line between jet packs and solutions. The Speeder, a turbine-powered micro- resembling a flying , is evolving with modular configurations for manned and unmanned operations, aiming to serve as precursors to urban air taxis with speeds exceeding 200 mph. Incorporation of 3D-printed components in these designs is projected to cut costs by up to 50% through lightweight, customized parts that reduce material waste and assembly time. This additive manufacturing technique allows for complex geometries unattainable with traditional methods, further optimizing weight and performance for extended-range flights. Sustainability efforts in jet pack technology are centering on cells to achieve zero-emission , addressing environmental concerns in personal aviation. These systems convert into electricity via electrochemical reactions, offering three times the of conventional without carbon outputs, and are being explored for compact aerial devices to enable cleaner, longer-duration flights. Prototypes in related sectors demonstrate feasibility, with integration potentially extending operational ranges while maintaining the portability essential for jet packs. Additionally, concepts for orbital "jet packs"—small modules attached to for on-orbit mobility and servicing—are expanding toward personal applications, where low-thrust or electric systems could facilitate extravehicular activities or maintenance. Looking ahead, the integration of (AR) for navigation holds promise to enhance in jet pack operations, overlaying real-time flight paths, obstacles, and waypoints onto a pilot's heads-up display. This technology, adapted from AR systems in broader , could improve precision in urban environments by providing intuitive guidance without diverting attention from flight controls. Market analysts project significant growth for personal flight technologies, including jet packs, with the sector alone forecasted to reach $3.2 billion by 2040, driven by regulatory approvals and infrastructure developments. These innovations collectively position jet packs as viable tools for both recreational and professional use in a sustainable aerial ecosystem.

Cultural Impact

In Fiction and Media

Jet packs have long been a staple in science fiction literature, symbolizing personal flight and futuristic adventure. The concept gained early prominence in the 1928 novella Armageddon 2419 A.D. by , which introduced the character in a post-apocalyptic world; the subsequent 1929 comic strip adaptation featured rocket-based propulsion devices such as backpack rockets for combat and exploration, influencing later media. In the 1950s, Robert A. Heinlein's juvenile novels, such as (1959), depicted soldiers using rocket-assisted power suits for rapid aerial maneuvers during interstellar conflicts, portraying jet packs as essential tools for mobile infantry in space wars. These literary works established jet packs as symbols of heroism and technological empowerment, blending adventure with speculative engineering. In film and television, jet packs often serve as plot devices for dramatic escapes and high-stakes action. The 1965 James Bond film Thunderball featured the real Bell Rocket Belt in its pre-title sequence, where agent 007 uses the device to evade pursuers in a brief but iconic flight from a chateau rooftop, highlighting its potential for covert operations. Similarly, the 1991 Disney film The Rocketeer centers on a young pilot who discovers a prototype rocket pack, using it for animated aerial chases and rescues, including thwarting Nazi spies during daring flights over 1930s Los Angeles. These portrayals romanticized jet packs as accessible gadgets for ordinary individuals thrust into extraordinary circumstances, emphasizing visual spectacle over technical realism. Video games have integrated jet packs as gameplay mechanics, enhancing mobility in diverse settings. In the Fallout series, particularly Fallout 4 (2015) and Fallout 76 (2018), players equip jet packs to power armor for vertical propulsion and traversal in post-apocalyptic wastelands, allowing strategic jumps and escapes during combat. The sports-racing game Rocket League (2015) incorporates jet pack toppers as cosmetic items on vehicles, evoking the trope while tying into its rocket-boosted mechanics for aerial soccer matches. These implementations make jet packs interactive tools for player agency, reinforcing their role in immersive, action-oriented narratives. Common tropes in portray jet packs as enablers of heroic escapes and seamless futuristic , often exaggerating their endurance and ease of use. Characters frequently deploy them for last-second getaways from villains or collapsing structures, as seen in serials and modern blockbusters, where the device's sudden turns the tide of peril. In utopian visions, jet packs facilitate effortless urban travel, zipping protagonists between skyscrapers without traffic woes, though stories typically overlook fuel limits and stability issues, leading to an overestimation of flight duration compared to real prototypes. Such fictional depictions have inspired real-world innovators, bridging imagination and invention. Swiss aviator Yves Rossy, known as Jetman, cited early comic influences in developing his rigid-wing jet suit for sustained flight, crediting these stories for sparking his pursuit of human aerial feats. This cultural resonance underscores how media portrayals have fueled enthusiasm among engineers and adventurers, perpetuating the jet pack's allure despite practical hurdles. In October 2025, Legendary Pictures announced a new film adaptation of based on , written by , which may further revive interest in the franchise's jet pack imagery.

Societal Influence

Jetpacks have inspired advancements in personal flight research, catalyzing developments in drone technology and electric vertical takeoff and landing () aircraft. The historical pursuit of jetpack-like propulsion systems, dating back to early 20th-century concepts, has influenced modern designs by emphasizing compact, individual aerial mobility solutions. For instance, companies like JetPack Aviation trace the evolution of personal VTOL from early rocket packs to contemporary electric variants, which share foundational principles with eVTOL efforts by firms such as , where battery-powered lift systems enable urban prototypes. In education, jetpack models serve as practical tools in STEM programs to illustrate physics concepts like and rocket propulsion. Curricula such as those from the include jetpack design challenges, where students model low-gravity flight scenarios to explore , , and . Similarly, resources like Learning's jetpack rocket science modules use simplified simulations to demonstrate and reaction, fostering hands-on understanding of principles among K-12 learners. Culturally, jetpacks symbolize and , embodying aspirations for personal and technological liberation from ground-based constraints. This iconic status, rooted in mid-20th-century visions of effortless flight, persists in contemporary discourse as a for and . Globally, perceptions in and have evolved from viewing jetpacks as mere novelties to recognizing them as emerging transport realities, fueled by rapid market expansion—Europe holds about 28.71% share, while accounts for 22.64% amid demonstrations like China's 2025 university prototypes achieving 100 km/h speeds. Ethical debates highlight jetpacks' potential to widen gaps, positioning them as elite recreational devices rather than equitable aids for the disabled or underserved, given costs exceeding hundreds of thousands of dollars per unit. Privacy concerns also arise, as personal urban flights could facilitate unintended or intrusions, akin to issues in broader systems where low-altitude operations risk violating individual seclusion without robust regulations.

References

  1. [1]
    jet pack n. - Historical Dictionary of Science Fiction
    Dec 6, 2022 · a device, worn over the shoulders like a backpack, that enables the wearer to travel through the air or in space by means of jet propulsion.
  2. [2]
    How Jet Packs Work - Science | HowStuffWorks
    Jun 9, 2023 · A jet intakes air, compresses it with a turbine and pushes it out the back, mixing it with fuel and combusting it in the process.
  3. [3]
    The Ill-Fated History of the Jet Pack - Smithsonian Magazine
    In "The Great American Jet Pack," Steve Lehto gives us the definitive history of this and related devices, explaining how the technology arose, how it works and ...
  4. [4]
    The fall and rise of jetpacks - Royal Aeronautical Society
    Aug 16, 2022 · The concept of a jetpack, or rather a rocket pack, using thrust from rocket engines was first conceived by a Russian named Alexander Andreev in 1919.
  5. [5]
    A Brief History of the Jetpack - Popular Mechanics
    Aug 5, 2013 · From James Bond to JetLev, we trace humanity's quest to build this extremely unnatural way to get high.
  6. [6]
    That Time We Were Promised Jet Packs - LIFE
    The idea of a jet pack was first hatched in 1919, about sixteen years after the first flight of the Orville Brothers, when a Russian inventor drew up a design ...
  7. [7]
    What is Jet Packing | Jetpack History
    Jun 5, 2014 · Jetpack America is the first Hydro-Flight business in the United States and specializes in water jetpack, flyboard, and other water-powered ...
  8. [8]
    McCandless Orbits in Jetpack - NASA
    Nov 7, 2011 · This space first was made possible by a nitrogen jet propelled backpack, previously known at NASA as the Manned Manuevering Unit or MMU. On Feb.
  9. [9]
    https://datahorizzonresearch.com/wearable-jetpack-market-23179
  10. [10]
    https://www.collinsdictionary.com/dictionary/english/jetpack
  11. [11]
    How Does A Modern Jetpack Work? - Laminar Sim
    Dec 23, 2024 · A jetpack consists of several key components that work together to ensure safe and effective flight. These include the propulsion system, fuel ...
  12. [12]
    The dream of personal jetpacks has already (sorta) come true
    Apr 14, 2016 · It's a device that's worn on the back, propelling the user into the air by means of a jet of gas, provided by a turbojet engine or a ducted fan.Missing: definition | Show results with:definition
  13. [13]
    Why Don't We Have Personal Jetpacks? - Popular Mechanics
    Feb 7, 2013 · The idea has actually existed since the 1920s, when science-fiction pulp magazines imagined jetpack-wearing heroes. ... meaning it releases ...
  14. [14]
    General Thrust Equation
    Thrust is a mechanical force which is generated through the reaction of accelerating a mass of gas, as explained by Newton's third law of motion. A gas or ...
  15. [15]
    Introduction to Rocket Propulsion | Physics - Lumen Learning
    By Newton's third law, this force is equal in magnitude to the thrust force acting on the rocket, so F thrust = v e Δ m Δ t , where all quantities are positive.Missing: jetpack | Show results with:jetpack
  16. [16]
    [PDF] Next-Generation Maneuvering System with Control-Moment ...
    The proposed design of a next-generation maneuvering and stability system incorporates control concepts optimized to support astronaut tasks and adds control- ...
  17. [17]
    Specific Impulse
    First, it gives us a quick way to determine the thrust of a rocket, if we know the weight flow rate through the nozzle. Second, it is an indication of engine ...Missing: jetpack 200-300
  18. [18]
    Jetpacks and Thrust to Weight Ratio - fx​Solver
    May 15, 2015 · For aircraft, the quoted thrust-to-weight ratio is often the maximum static thrust at sea-level divided by the maximum takeoff weight. In ...Missing: power | Show results with:power
  19. [19]
    The Drag Equation
    The drag equation states that drag D is equal to the drag coefficient Cd times the density r times half of the velocity V squared times the reference area A.
  20. [20]
    Inside Gravity's daring mission to make jetpacks a reality - WIRED
    Oct 13, 2020 · The idea of jetpacks dates back to at least 1919, when a Russian inventor called Alexander Fedorovich Andreev filed a patent for a rocket housed ...
  21. [21]
    We were promised jetpacks decades ago. Here's where are they now
    May 20, 2022 · ... 1919. Developed by Alexander Andreev, a Russian engineer who thought soldiers might use the device to leap over walls and trenches. The ...
  22. [22]
    Why our 'amazing' science fiction future fizzled - CNN.com
    May 29, 2009 · He says the jet pack first appeared in 1928 in an Amazing Stories comic book, which featured the hero Buck Rogers zooming though the sky in a ...
  23. [23]
    Jet packs in flight and fiction - CBS News
    Apr 20, 2014 · CBS News Sci-fi hero Anthony "Buck" Rogers made his debut in the August 1928 issue of Hugo Gernsback's "Amazing Stories." In "Armageddon ...
  24. [24]
    The goofy history of jet packs (pictures) - CNET
    Sep 10, 2015 · Up, up and away! By 1928, when heroes like Buck Rogers jetted onto the scene in pulpy magazines (like this one, from that exact year) the idea ...Jetpacks: The Glorious... · Allez! Only Don't Look Down! · Rocket Man: Serial Thriller<|separator|>
  25. [25]
    RNII - RussianSpaceWeb.com
    The Jet Propulsion Research Institute, RNII, was officially created on September 21, 1933, in Moscow by Decree Number 113 of the Revolutionary Military Soviet.Missing: 1930s | Show results with:1930s<|separator|>
  26. [26]
    The Devil's Broomstick - HistoryNet
    May 23, 2018 · Scientists in the Soviet Union had also been experimenting with liquid rocket propellants in the 1930s, and by the spring of 1941 the Viktor ...Missing: jetpack | Show results with:jetpack
  27. [27]
    [PDF] The Future of Individual Lift Devices in Warfare - Army University Press
    The expecta- tions of flying shoes, platforms, ducted-fan lift devices, rocket belts, and jet belts always exceeded the tech- nological limitations of that time ...Missing: pre- WWII<|control11|><|separator|>
  28. [28]
    [PDF] Humans to Mars: fifty years of mission planning, 1950–2000
    Feb 28, 1983 · Hydrogen peroxide made from water could serve as powerful fuel for ... Buzz Aldrin, “The Mars Transit System,” Air & Space Smithsonian ...
  29. [29]
    The Rocket Belt | Invention & Technology Magazine
    The fuel used in the rocket belt was 90 percent pure hydrogen peroxide, along with pressurized nitrogen gas to move it through the system.
  30. [30]
    How to Fly a Rocket Belt - Niagara Aerospace Museum
    Apr 30, 2024 · From 1964 to 1970 Bell Rocket Belt pilot William Suitor flew and tested numerous versions of Bell rocket powered flying machines including the ...Missing: RB- 2000 Bill 1965
  31. [31]
    https://news.bellflight.com/en-US/162793-innovation-throwback-the-bell-rocket-belt
  32. [32]
    The Race to Create Working, Practical Personal Jetpacks
    Dec 13, 2022 · Originally intended for use by Apollo astronauts on the moon, POGO was also pitched to the Army as a “flying jeep” for carrying soldiers over ...
  33. [33]
    Failure to Launch: Why Jetpacks Never Took Off - Sports Illustrated
    Jul 7, 2021 · In 1970, the U.S. Army finally threw in the towel on its funding for the Bell rocket belt program. It was hard to imagine the infantry of the ...
  34. [34]
    1990-2000 | JetPack Aviation
    View 1980's & Earlier Gallery · View 2010-2020 Gallery · View 2020 Onwards Gallery. JB-5 ... JB-7 ...
  35. [35]
    Jetpack Pilot Soars Over NYC's Hudson River, Salutes Lady Liberty
    Nov 6, 2015 · A pilot can fly with the jet turbine-powered backpack for about 10 minutes before the device needs to be refueled. This meant Mayman had plenty ...
  36. [36]
    Jet Man flies across Channel on a wing | Aeronautics | The Guardian
    Sep 26, 2008 · Swiss daredevil Yves Rossy today became the first person to cross the English Channel using only a jet-propelled wing trapped to his back.
  37. [37]
    Jet pack daredevils soar alongside world's biggest airliner
    Nov 5, 2015 · Stuntman Yves Rossy and his jet-setting partner Vince Reffet flew alongside an Emirates Airbus A380, which dwarfed the daring duo in a lopsided ...
  38. [38]
    Fastest speed in a body controlled jet engine powered suit
    The fastest speed reached in a body-controlled jet-engine-powered suit is 85.06 mph (136.891 km/h) by Richard Browning (UK) of Gravity Industries.
  39. [39]
    Air Force, Special Forces competition chooses JetPack Aviation to ...
    JetPack Aviation announced that its Speeder VTOL [vertical takeoff and landing] platform was chosen by the AFWERX High Speed VTOL (HSVTOL) Concept Challenge.Missing: 2024 | Show results with:2024
  40. [40]
    Flying Jetpacks Market Size, Growth, Market Overview & Forecast ...
    Rating 4.7 (51) Flying Jetpacks Market size stood at USD 300 Million in 2024 and is forecast to achieve USD 1.5 Billion by 2033, registering a 18.3% CAGR from 2026 to 2033.
  41. [41]
    Jetman Yves Rossy is taking jetpack travel global | WIRED
    Sep 10, 2015 · Each of Rossy's flights starts with a plane jump. Using the 55kg carbon-fibre wing, powered by four small Jet-Cat P200 turbine engines and ...
  42. [42]
    [PDF] Design of Liquid Propellant Rocket Engines
    The book presents sufficient detail to familiarize and educate thoroughly those responsible for various aspects of liquid propellant rocketry, including engine ...
  43. [43]
    [PDF] PROPELLANTS SEMINAR 13-14 JUNE 1956 LIQUID ... - CIA
    Monopropellant hydrogen peroxide has been used for gas generators in large rockets, for submarine and torpedo propulsion, for rocket assist takeoff units, and ...
  44. [44]
    Rocket Belt, Bell No. 2 | National Air and Space Museum
    The idea of the rocket belt appeared in "Buck Rogers" comic strips as early as 1929. Wendell Moore of Bell Aerosystems was the first to develop the ...Missing: 1928 | Show results with:1928
  45. [45]
    Thrust to Weight Ratio - Glenn Research Center - NASA
    Jun 23, 2025 · High excess thrust results in a high rate of climb. If the thrust to weight ratio is greater than one and the drag is small, the aircraft can ...Missing: advantages packs
  46. [46]
    Jetpacks: here's why you don't have one | Aeronautics | The Guardian
    Sep 23, 2014 · At present, the most practical fuel sources we have are chemical. Jet fuel and rocket fuel are both made using highly reactive chemicals ...Missing: times | Show results with:times
  47. [47]
    Jetcat P400-PRO Turbo Jet Engine 425N for RC Plane & OEM
    In stock Rating 3.6 (75) Featuring ‌CNC-machined turbine‌, ‌kerosene fuel system‌, and ‌instant throttle response‌, it's perfect for ‌racing, ‌experimental vehicles‌, and ‌high-speed ...Missing: turbines | Show results with:turbines
  48. [48]
    EDF Ducted Fan separate - TURBINES RC
    15-day returnsA high thrust and well designed Electric Ducted Fan unit for high power applications, the 12 blades arrangement makes for a quiet fan unit ...
  49. [49]
    Finally, the Jetpack We've Always Wanted - IEEE Spectrum
    Nov 10, 2015 · Turbojets do still offer very high power density and impressive power to weight ratios, which, for something like a jetpack, is exactly what you ...
  50. [50]
    Finally. A Working JetPack | Hackaday
    Nov 9, 2015 · But just assuming two of the top turbines, you have 2×89 pounds of thrust, for a total of 178 pounds thrust, at a fuel consumption rate of 2×1.3 ...
  51. [51]
    [PDF] gravity-resource-pack.pdf
    A gas turbine is designed to hoover up huge amounts of air and burn it with vast amounts of fuel (roughly 50 parts air to 1 part fuel), so the main reason why ...
  52. [52]
    [PDF] PROPULSION TECHNOLOGY FOR JET PACK SUITS
    Jetpack suits are a type of personal flying device that allows the user to take to the skies and experience the freedom of flight. These devices rely on ...
  53. [53]
    The World Of The Future creeps closer every day department
    Nov 8, 2007 · The jets provided approximately 16 kgf of thrust each and ran on kerosene (JetA-1) fuel. Visa was able to achieve approximately 30 seconds of ...Missing: turbine | Show results with:turbine
  54. [54]
    JetPack Aviation speeds on with 2nd-gen flying motorcycle tests
    Jan 26, 2022 · The Speeder will be a totally unique and modular aircraft capable of extremely high speeds, over distances potentially as high as 1,000 miles.Missing: trials | Show results with:trials
  55. [55]
    Noise Comparisons
    Noise Sources and Their Effects ; Jet take-off (at 25 meters), 150, Eardrum rupture ; Aircraft carrier deck, 140 ; Military jet aircraft take-off from aircraft ...Missing: jetpack heat
  56. [56]
    How loud is a jet engine? - Noise Monitoring Services
    Dec 17, 2019 · Based on the above charted data the peak noise level is between 140 and 153 decibels. The measurements were conducted near field along a 42 foot ...Missing: jetpack issues
  57. [57]
    iJETPACK Aeronautics. DEFY IMPOSSIBLE.
    JETSUIT FLIGHT TRAINING NOW AVAILABLE!** Give your arms the superpowers they need to take flight, with iJETPACK's new IJ6180 Jetsuit.Missing: 2025 8-
  58. [58]
    Water-propelled Jetlev-Flyer personal jetpack set for release
    May 9, 2011 · With a fuel capacity of 26 US gal (100 liters), pilots will be able to enjoy the views for about one hour at full throttle, or for around two to ...
  59. [59]
    Ray Li, Inventor of Jet Pack -Jetlev Technologies
    May 31, 2024 · Jetlev Technologies In January 2005, was successfully thrust-tested at Canada's National Research Council's Institute of Ocean Technology.
  60. [60]
    JetLev water propelled flying jet pack - Yachting Magazine
    Nov 6, 2012 · According to JetLev of Dania Beach, Florida, the R200 personal flying machine was invented by Raymond Li ... Contact JetLev: 954-922-3325; jetlev.Missing: 2005 | Show results with:2005
  61. [61]
    Everything you need to know about Franky Zapata
    Following this vision, he decided to diversify his activities and developed the first version of a new prototype in 2011: “Flyboard®”.
  62. [62]
    Flyboard® by Frank Zapata | Extraordinary hydroflight device
    Flyboard®, powered by the turbine of a JetSki, propels users above the water, allowing them to move several meters. This unique experience combines power, ...Missing: 2010 | Show results with:2010
  63. [63]
    Beginners Guide to Flyboarding (Updated 2024) - Extrevity
    Drowning: Drowning is a risk whenever an individual is in the water, and it can occur if the participant falls into the water and is unable to swim to safety.Missing: JetLev fire
  64. [64]
    Understanding Flyboarding Risks & Why You Need Insurance
    Jun 19, 2023 · Flyboarding risks include falls, collisions, equipment damage, drowning, environmental hazards, and legal issues. Insurance is crucial for ...Missing: fire | Show results with:fire
  65. [65]
    Jetlev-Flyer SAFETY
    The jets have very mild impact forces after they descend 30 feet. Hands and arms should be kept away from direct impact by the jets to avoid possible bruising.Missing: Flyboard drowning fire
  66. [66]
    Ascend Dynamics presents its Skypak V1 electric jetpack - New Atlas
    Apr 4, 2022 · Twelve 7-kW motors give it a total peak power output of 84 kW (112 hp), and it weighs 80 lb (36 kg). Well, the jetpack part does. At the moment, ...<|control11|><|separator|>
  67. [67]
    CopterPack
    Lightweight carbon fiber honeycomb airframe. Hybrid Jet and electric propulsion. Pressurized fuel tanks with air traps for reliable fuel flow.
  68. [68]
    The Pentagon's dream of flying troops is closer to becoming reality
    Apr 22, 2024 · The Defense Department is actively testing brand-new, all-electric personal flight systems with the help of a handful of defense contractors.
  69. [69]
    The State Of Battery Technology - JetPack Aviation
    In this blog, we'll take a brief look at where battery technology is – and what needs to be done before batteries can be used to power electric VTOL aircraft, ...
  70. [70]
    Space Force orders 'jetpack' to give 2 years of maneuverability to ...
    May 21, 2024 · The "augmented maneuver mission" will allow a U.S. military satellite to change its orbit.
  71. [71]
    Battery technology for sustainable aviation: a review of current ...
    The primary limitation is the energy density, as current batteries provide a fraction of the energy per unit mass compared to conventional jet fuel [4], [5]. In ...
  72. [72]
    The history and future of jetpacks: Mankind's obsession ... - Pocket-lint
    The Rocket Belt came about as a US Army project aimed at allowing soldiers to be able to leap over small distances and move at faster speeds to get them out of ...
  73. [73]
    Bell Aerosystems Rocketbelt - BMT 216A
    The rocketbelt was a result of the Army Transportation Command contract assigned to Bell in 1960. The unit was created and developed by Wendell Moore - a rocket ...<|control11|><|separator|>
  74. [74]
    The Inventor Iustin Capra - Radio Romania International
    Mar 15, 2015 · In 1968, Capra created an improved version of his flying backpack, using hydrogen peroxide as fuel. His first major invention also caused ...Missing: Justin | Show results with:Justin
  75. [75]
    Romanian who claimed he invented world's first jetpack dies
    Jan 20, 2015 · In 1956, under communism, Capra invented the "flying rucksack," a personal flying machine. In 1962, one was produced in the U.S. by Bell ...Missing: peroxide | Show results with:peroxide
  76. [76]
    Wing for Yves Rossy alias "Jetman" - DECISION
    This prototype with 4 jet engines, guided only with the movements of his body, allows a stabilized ascension of the flight. This was the flight of November 2006 ...
  77. [77]
    Yves Rossy: The Swiss Pilot Famous For Jet Pack Flying
    Nov 5, 2022 · In the world's playground of Dubai, on a sunny November morning in 2015, two men jump out of a helicopter at 5,500 feet (1,676 m).
  78. [78]
    Fighting Gravity with the World's First Propulsion Suit - Tech Briefs
    Oct 26, 2022 · British inventor Richard Browning has designed, built, patented, and flown the world's first propulsion suit. · One arm's worth of gas turbines.
  79. [79]
    Jet Suit: Flying just like Iron Man - FLYER
    Aug 31, 2023 · Inventor Richard Browning has 'reimagined human flight' with a pioneering jet suit. Rachel Ramsay went to Goodwood to give it a try.
  80. [80]
    Jet suit rescue demonstrated - AOPA
    Oct 8, 2020 · The September 29 demonstration was the product of a collaboration between Gravity Industries, a firm Browning ...
  81. [81]
    Flyboard Air - Wikipedia
    Zapata Racing claims that it allows flight up to an altitude of 3,000 metres (9,800 ft) and has a top speed of 150 km/h (93 mph). It also has 10 minutes' ...
  82. [82]
    Flyboard Air® by Franky Zapata
    Flyboard Air is a jet powered board designed to showcase the potential of “hypermobility”. Powered by 5 jet engines, it is the smallest redundant manned ...Missing: hybrid | Show results with:hybrid
  83. [83]
    Franky Zapata: Flyboarding Frenchman crosses English Channel
    Aug 4, 2019 · French inventor Franky Zapata has made the first-ever successful Channel crossing on a jet-powered flyboard. Mr Zapata, 40, took off from ...
  84. [84]
    Jetpack maker approaches sales with caution - AOPA
    Jan 25, 2018 · While the $250,000 price tag attached to the JB10 model will put it out of reach of the masses, Mayman has in recent years stirred plenty of ...Missing: turbine 8 minute 2010
  85. [85]
    JB-10 JetPack
    The JB10 is powered by two specially modified turbojet engines, each producing approximately 200lbs of thrust (at standard atmospheric conditions)Missing: David 2007
  86. [86]
    World's Most Advanced JetPack, the JB11 First EVER Flight at ...
    Jul 13, 2018 · Watch the world's most advanced JetPack, called JB11 making its first ever European flight debut at the 2018 Goodwood Festival of Speed.Missing: International price $250000 turbine minute events 2010
  87. [87]
    I got to test drive a $440,000 flying Gravity Jet Suit - CNBC
    Oct 22, 2018 · The CEO also offers a less expensive option called "The Experience." It's a full day of one-on-one jet suit pilot training for $40,000, jet ...Missing: Mark | Show results with:Mark
  88. [88]
    Flight Training - Gravity Industries
    Individualised flight training programs offer the chance to enrol as members of an exclusive community of Jet Suit Pilots.Flight Training Includes · What Happens · Our Training CentresMissing: Mark 5 price
  89. [89]
    Water-propelled jetpack hits the market for $99,500 (w/ video)
    May 10, 2011 · Water-propelled jetpack hits the market for $99,500 (w/ video) · Company to sell 'world's first practical jetpack' for $75,000 (w/ Video).
  90. [90]
    $$130000 JetLev Water-Powered Jet Pack Going into Production
    Jul 30, 2009 · This $130,000 gadget is “powered by a 215hp jet ski motor that produces two jet streams of water at 60 psi and a max height of 30 feet.” Video ...<|separator|>
  91. [91]
    Franky Zapata's Flyboard Air Is the World's Only Flying Hoverboard
    Jan 14, 2023 · French inventor Franky Zapata's Flyboard Air, the world's only flying hoverboard, can fly you up to 10000 feet in the air at 110 mph.
  92. [92]
    Dubai's sky-high hosts a jet suit race for 'Iron Man' pilots. | AP News
    Feb 28, 2024 · The races on Wednesday saw pilots wear 1,500-horsepower jet suits, more powerful than most luxury sports cars and using the same kind of fuel ...
  93. [93]
    [PDF] 350 UDC 167.6 JET PACK Stud. K. Klymenko, gr. BA 1-15 Scientific ...
    In 1959 Aerojet Corporation constructed an Aeropack for US Army. In this type of machine jet contains hydrogen peroxide rocket. The peculiar feature of this ...
  94. [94]
    The Army once hoped jetpacks could give soldiers the edge in combat
    Jan 1, 2025 · US Army experiments kept pushing the idea of giving soldiers limited flight, as a way to make infantry more mobile and more effective on the battlefield.Missing: pre | Show results with:pre
  95. [95]
    JetPack Aviation announces its selection in the joint US Air Force ...
    Aug 18, 2021 · JetPack Aviation announces its selection in the joint US Air Force and US Special Operations Command AFWERX High Speed VTOL Concept Challenge.Missing: 2024 | Show results with:2024
  96. [96]
    Royal Marines trial use of jet suit for boarding operations
    May 5, 2021 · Royal Marines have tested the use of a jet suit for maritime boarding operations. The trial saw patrol ship HMS Tamar and Royal Marines from Plymouth-based 42 ...
  97. [97]
    NASA awards Space Act Agreement contract for commercial ...
    Jul 3, 2023 · A variation of the AMU astronaut jetpack called the Manned Maneuvering Unit (MMU), was a key piece of standard equipment aboard NASA's Space ...Missing: designs applications
  98. [98]
    DARPA's flying forward with its jetpack program - Popular Science
    Nov 22, 2022 · DARPA is funding the development of jetpacks for soldiers. The jetpacks, and other such mobility devices, are being pursued under the Portable Personal Air ...Missing: investment | Show results with:investment
  99. [99]
    Wingsuit flying - Wings Over Kansas
    His first powered jump was in 2007. On October 25th of 2005 in Lahti ... Visa Parviainen made a second flight in February of 2006, with similar results.
  100. [100]
    Do you also want to fly in the sky? Flying jet suit in Dubai !
    Mar 12, 2023 · The Dubai Jet man suit, designed for human flight, can cost anywhere from $250,000 to $618,000. It comes with multiple components, including a ...
  101. [101]
    JetPack Aviation: Home
    We design and build everything in house. Our JetPacks have been seen around the world in movies, TV commercials and Red Bull air races.About Us · JetPack Training LP · Book a JetPack Flight · JetPacksMissing: Force trials 2024 2025
  102. [102]
    JetPack Training LP | JetPack Aviation
    It is a 2 days experience which includes all the training, briefings, flights and debriefing as well as lunch. The exact start and end times will be confirmed ...
  103. [103]
    Jetpack Market Share Report Forecast [2033]
    The global Jetpack Market size was valued at approximately USD 0.8 billion in 2024 and is expected to reach USD 2.2 billion by 2033, growing at a compound ...
  104. [104]
    Jet Pack Industry Insights Report: Analyzing Market Trends ...
    Aug 24, 2025 · Growth is anticipated at approximately 4% annually, driven by sustainability initiatives. Among these, water parks show the steepest growth ...
  105. [105]
    Waterjet-propelled hoverboards elevate Dubai firefighters - New Atlas
    Jan 24, 2017 · Rising up on a jet of water, the firefighter can get a hose onto the fire, using an unlimited source of water to douse the blaze, and ...Missing: trials 2010s
  106. [106]
    Video: Dubai firefighters use jetpacks to battle fires - FireRescue1
    Jan 23, 2017 · The jetski-jetpack uses water from Dubai's bay to propel firefighters; a hose is also part of the kit. The new tool aims to reduce response ...
  107. [107]
    Jetpack rescue: Paramedic flies to the top of a mountain in 3 minutes
    May 31, 2022 · After just six days training, Jamie Walsh, a paramedic for GNAAS used one of Gravity's Jet Suits to fly up Helvellyn for the first time ever.
  108. [108]
    Jet Suit Paramedic - Great North Air Ambulance Service
    The Jet Suit Paramedic. An emergency service response jet suit from the Great North Air Ambulance Service could save lives in the Lake District.
  109. [109]
    Maverick Aviation unveils jetpack for use in construction
    Sep 13, 2021 · Designed to be operated hands-free the jetpack uses Vertical Take-off and Landing (VTOL), making for safer flights and the ability to land in ...Missing: applications | Show results with:applications
  110. [110]
    Australia: 84 million hectares of northern Australia burned in 2023
    Apr 23, 2024 · My research shows the 2023 fires burned more than 84 million hectares of desert and savannah in northern Australia. This is larger than the whole of New South ...
  111. [111]
    [PDF] liquid propellants safety handbook
    This is a safety handbook for liquid propellants, prepared by NASA, covering properties of substances like ethyl alcohol, furfuryl alcohol, and anhydrous ...
  112. [112]
    Ups and downs of jetpacks | New Scientist
    Sep 28, 2005 · A rocket engine is most efficient at converting its fuel into thrust when moving close to the speed of its exhaust velocity – when the relative ...Missing: advantages | Show results with:advantages
  113. [113]
    [PDF] Battery Design Implications on Thermal Runaway Severity:
    May 10, 2017 · ▫ Jetpack operation is for contingency use in case astronaut ... No thermal runaway after 44 min. 1. 70. 15. Bottom. Ambient. ~ 22. ~ 199.
  114. [114]
    Analysis of Thermal Runaway Performance of Power Batteries for ...
    Electric aircraft powered by lithium batteries (LIBs) have seen rapid development in recent years, making research into their thermal runaway (TR) ...Missing: jetpack | Show results with:jetpack
  115. [115]
    New Details Emerge About Fatal Jetpack Crash - Futurism
    Apr 26, 2021 · Daredevil jetpack pilot Vince Reffet tragically passed away in November 2020 during a training accident. Here's what may have happened.Missing: history | Show results with:history
  116. [116]
    The Story of NASA's Jet-Propulsion Backpack - Smithsonian Magazine
    The story of NASA's jet-propulsion backpack. Thirty years ago, astronauts set out on the first untethered space odyssey.
  117. [117]
    What Is G-LOC and How Does It Work? - Sky Combat Ace
    It occurs when increased force due to gravity is applied to the body, causing a loss of consciousness. Most people can withstand anywhere between 2 to 5 G- ...Missing: pack factors
  118. [118]
    Spatial Disorientation | SKYbrary Aviation Safety
    Spatial disorientation is the inability of a pilot to correctly interpret aircraft attitude, altitude or airspeed in relation to the Earth or other points of ...Missing: pack | Show results with:pack<|separator|>
  119. [119]
    [PDF] AC 103-7 - Advisory Circular - Federal Aviation Administration
    If your ultralight does not meet 9 103.1, it must be operated in accordance with applicable aircraft regulations.
  120. [120]
    FAQs | JetPack Aviation
    At the time of writing you will need at least a Light Sports Aircraft (LSA) pilot certificate to operate our Experimental Category aircraft. In all cases you ...Missing: ICAO guidelines
  121. [121]
    [PDF] State of Global Aviation Safety - ICAO
    Aug 11, 2025 · This report makes use of information, including air transport and safety-related data and statistics, which is furnished to the ...
  122. [122]
    Drone Open Category - Applicable requirements to fly from the 1st of ...
    Dec 20, 2023 · According to the EU Regulation 2019/947, from 1 January 2024, you can fly a drone without a class identification label if you operate in the ...
  123. [123]
    A review of health effects associated with exposure to jet engine ...
    Feb 6, 2021 · Jet engine emissions contain large amounts of nano-sized particles, which are particularly prone to reach the lower airways upon inhalation.Missing: jetpack | Show results with:jetpack
  124. [124]
    Environmental Impact of Personal Aircraft
    Personal aircraft have traditionally been associated with high emissions and noise pollution. ElectraX is working to change this narrative. Electric Engines. By ...
  125. [125]
    Jetpacks Will Soon Be Headed To A Military In Southeast Asia
    Sep 7, 2021 · The company says that it expects to have fulfilled the order, which is for two JB12s at a cost of approximately $800,000, within the next six ...Missing: insurance | Show results with:insurance
  126. [126]
    The Real Cost of Aircraft Insurance - Pilot Institute
    Mar 16, 2022 · Insurance for a small aircraft will cost around $1,500 to $2,000 per year, but the amount of coverage and cost will vary significantly by the ...Types Of Aircraft Insurance · Renter's Insurance · Tips For Minimizing Aircraft...
  127. [127]
    Jetpack Aviation (Reg CF) - StartEngine
    JetPack Aviation is the first company to design and manufacture a real jet powered personal flight machine that can be easily carried by the pilot.Missing: 8 2010
  128. [128]
    About FAA Part 103 for Ultralights | EAA
    Part 103 established limits on size, performance, and configuration and also established that people flying them needed no certificate or medical qualification.
  129. [129]
    Jet Pack Market Report 2025 (Global Edition)
    According to the author, by 2033 Jet Pack market size will become $2281.9. Jet Pack market will be growing at a CAGR of 22.5% during 2025 to 2033."Missing: billion | Show results with:billion
  130. [130]
    Flying Jetpacks Market Size, Share | Global Industry Report, 2033
    The global flying jetpacks market size stood at approximately USD 0.4 billion in 2024 and is projected to reach USD 0.5 billion in 2025, growing further to ...
  131. [131]
    'CyberGuy': Chinese wearable eVTOL jetpack makes historic first flight
    May 19, 2025 · Tech expert Kurt Knutsson reports on China's Zhiyuan unveiling the world's first tri-ducted wearable eVTOL with hands-free control.Missing: companies | Show results with:companies
  132. [132]
    Jetpack Market Shows Promising Future as Demand Surges Across
    Oct 23, 2025 · The market is projected to expand significantly through 2031 as manufacturers focus on improving flight stability, fuel efficiency, and safety ...Missing: 1.5 2033
  133. [133]
    Solid-State Batteries 2026-2036: Technology, Forecasts, Players
    Unlock the potential of solid-state batteries with IDTechEx's in-depth report. Covering market forecasts, cutting-edge technologies, electrolyte innovations ...
  134. [134]
    Electric Aircraft Developers Prep for Battery Breakthroughs
    Sep 3, 2024 · Solid-state batteries have emerged as potentially the most promising alternative to lithium-ion batteries when it comes to aviation applications ...
  135. [135]
    Jetpack Air: The Future of Personal Flight Explained - Accio
    Rating 5.0 (167) · Free 14-day returnsKerosene-powered units typically carry 4.5kg (10lb) of fuel enabling 8-10 minutes of flight. Next-generation electric prototypes achieve 15-25 minutes, while ...
  136. [136]
    Chinese wearable eVTOL jetpack makes historic first flight - CyberGuy
    May 19, 2025 · This setup isn't just for show. It actually helps the vehicle fly smoother, cut down on noise, and hover more reliably.
  137. [137]
    Future passenger planes could use AI to eliminate turbulence and ...
    Nov 11, 2024 · Turbulence in airplanes could become a thing of the past with FALCON, a new AI system that helps vehicles learn how to adjust to turbulence ...
  138. [138]
    JetPack Aviation's VTOL Speeder prototype passes first round of ...
    Jul 15, 2021 · The Speeder will offer a maximum speed of 150mph (240km/h) at an altitude of up to 15,000ft, have a flight time of up to 30 minutes and be ...Missing: Force trials
  139. [139]
    The Personal Aviation Era and 3D Printing: Jetpacks and Gliders
    Jul 6, 2021 · Scalmalloy, titanium or other materials can be 3D printed to save weight and improve performance for many of the critical components in ...
  140. [140]
    The Impact of 3D Printing in the Aerospace Industry - Creality
    Jan 22, 2025 · The ability to 3D print lightweight, complex parts and on-demand components for aircraft enhances efficiency and reduces costs significantly ...3d Printing In The Aerospace... · Introduction To 3d Printing... · Applications Of 3d Printing...<|separator|>
  141. [141]
    https://www.openpr.com/news/4188625/evtol-market-is-forecasted-to-reach-us-3-2-billion-in-2040-says
  142. [142]
    Why Hydrogen Makes Sense for Aviation | Joby
    Jul 11, 2024 · Hydrogen has one hundred times the specific energy of today's batteries and three times that of jet fuel, enabling emissions-free aviation ...Missing: packs | Show results with:packs
  143. [143]
    US Space Force wants satellite 'jetpacks' to keep old spacecraft ...
    Feb 9, 2024 · Small "backpacks" that can attach to existing spacecraft in orbit may help out-of-fuel satellites live a while longer.
  144. [144]
    AR for Navigation – What You Should Know - BairesDev
    Apr 26, 2024 · You can use AR for inter-city navigation. Through this technology, you can easily identify and navigate through places such as shopping malls, museums, and ...Missing: jet packs<|separator|>
  145. [145]
    eVTOL Market is Forecasted to Reach US$3.2 Billion in 2040, Says
    Sep 18, 2025 · The global eVTOL market size was valued at US$0.06 billion in 2024, and is projected to reach US$3.2 billion by 2040, witnessing a market ...
  146. [146]
    Rocket Men: A brief history of the jetpack | Technology | The Guardian
    Oct 29, 2008 · Jetpacks, or rocketbelts, were originally conceived in science fiction and comic books in the 1920s. After they became reality in the 1960s.
  147. [147]
    James Bond's Jetpack Escape in 'Thunderball' Almost Didn't Happen
    Apr 25, 2024 · In 1965, the belt only had a 21-second maximum flight duration and a range of 393 feet. It was an intriguing idea with a flawed execution.
  148. [148]
    The Rocketeer (1991) - IMDb
    Rating 6.6/10 (64,818) A young pilot stumbles onto a prototype jetpack that allows him to become a high-flying masked hero.Full cast & crew · The Rocketeer · Le Rocketeer · Trivia
  149. [149]
    Fallout 76: How to Get a Jet Pack (& How to Craft One) - Game Rant
    Apr 30, 2023 · A Jet Pack in Fallout 76 is a utility attachment that helps players propel through the air. This guide explains how to get and craft them.<|separator|>
  150. [150]
    Jetpack Topper | Rocket League Garage
    Details, previews, designs and statistics of Jetpack Topper.
  151. [151]
    Jet Pack - TV Tropes
    A standard piece of equipment for anyone from The Future or for secret agents, a Jet Pack is a back-mounted item that uses jet propulsion to allow the …
  152. [152]
    I Want My Jet Pack - TV Tropes
    This trope is essentially the in-universe version of Failed Future Forecast, and refers to characters complaining about how unimpressive the present-day is.
  153. [153]
    Swiss Adventurer Yves Rossy Brings Us Closer to a Real Rocketeer
    Although he wasn't the first superhero to take flight with a jet pack (that would probably be Buck Rogers), The Rocketeer was one of the most prominent. In ...
  154. [154]
    The History Of Personal VTOL Technology - JetPack Aviation
    From the earliest helicopters to the latest advances in electric flight, we'll be looking at the entire history of personal VTOL technology.
  155. [155]
    The Real Jetpacks Are Finally Coming - Popular Mechanics
    Oct 7, 2016 · New footage from JetPack Aviation proves that jetpacks are now a thing of the present, not the future.
  156. [156]
    Design a jetpack for playing football on the Moon - IET Education
    This resource focusses on learners looking at jetpack aviation to design a jetpack that the players or referee can use during a game of football on the moon.Missing: programs | Show results with:programs
  157. [157]
    Jetpack rocket science - STEM Learning
    This video takes a light-hearted look at motion. It applies Newton's second and third laws to explain how motion occurs in the space shuttle and a jetpack.
  158. [158]
    Global Jet Pack Market Report 2025 And Its Market Size, Share and ...
    Jul 10, 2025 · ... Europe follows with 28.71%, showing strong growth across the UK, Germany, and France • Asia Pacific is catching up fast, claiming 22.64 ...
  159. [159]
    https://www.facebook.com/ChinaFocus2015/videos/jetpack-makes-a-stunning-debut/1753882045298267/
  160. [160]
    Is the use of jetpacks finally about to take off? - BBC
    Jul 4, 2021 · What, however, is rarely discussed is the potential recreational use of jetpacks. Observers often point to a number of problematic issues ...Missing: civilian applications
  161. [161]
    Societal acceptance of urban drones: A scoping literature review
    This scoping review offers an assessment of the societal acceptance factors of urban drones discussed in the current academic literature.Missing: jetpacks inequality