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Vortex generator

A vortex generator (VG) is a small aerodynamic device, typically a low-aspect-ratio vane or tab mounted perpendicular to a lifting surface such as an aircraft wing, that creates controlled vortices to energize the low-speed boundary layer by mixing it with higher-energy free-stream airflow, thereby delaying flow separation and improving aerodynamic performance.^[1] These devices are usually arranged in pairs or arrays, spaced a few inches apart and angled at 12° to 15° relative to the oncoming airflow, often positioned ahead of control surfaces like ailerons to maintain attached flow at high angles of attack.^[2] The concept of vortex generators originated in the mid-20th century, with early applications documented in a 1947 United Aircraft Corporation report by H. D. Taylor, which demonstrated their effectiveness in suppressing boundary layer separation in diffusers and subsonic flows.^[3] Since then, VGs have been extensively studied and refined through experimental and computational methods, including NASA investigations into their modeling for turbomachinery and wing applications, confirming their role in thinning the boundary layer.^[4] In aviation, they enable lower stall speeds, better roll control during stalls, and enhanced lift coefficients without significant cruise drag penalties when optimized.^[2] Beyond aircraft, vortex generators find use in diverse fields, including wind turbine blades to mitigate stall and boost energy capture at low wind speeds,^[3] automotive designs for drag reduction on trailers,^[5] and even marine propellers for efficiency gains.^[6] Modern variants include micro-VGs^[7] and active systems that deploy selectively, as explored in sustainable aviation research to minimize fuel burn across flight phases.^[8] Their design—often aluminum or composite vanes less than 1% of chord length—balances minimal added weight against substantial performance benefits, making them a staple in aerodynamic flow control.^[9]

Fundamentals

Definition and Purpose

A vortex generator (VG) is a small aerodynamic device, typically consisting of a vane, tab, or plate attached to a lifting surface such as an aircraft wing or a wind turbine blade, designed to produce streamwise vortices that interact with the boundary layer.^[10] These vortices arise from the device's orientation relative to the oncoming flow, creating controlled swirling motions that influence the airflow characteristics near the surface.^[4] The primary purpose of vortex generators is to delay flow separation by energizing the low-momentum fluid in the boundary layer through mixing with higher-energy freestream flow, thereby enhancing aerodynamic efficiency.^[10] This mechanism improves lift generation, reduces drag penalties associated with separation, and postpones stall conditions, leading to better overall performance in high-lift or adverse flow scenarios.^[4] By maintaining attached flow over surfaces, VGs contribute to safer and more effective operation across various engineering contexts. Vortex generators are broadly classified into passive and active types, with passive designs being the most prevalent due to their simplicity and lack of energy requirements. Passive VGs are fixed vanes or plates that generate vortices solely through aerodynamic forces, while active variants, such as deployable flaps or synthetic jet actuators, incorporate mechanisms for on-demand operation to adapt to varying flow conditions.^[10] First conceptualized in the late 1940s for aviation applications, vortex generators have since expanded to broader fluid dynamics uses, including wind energy systems and ground vehicles, underscoring their versatility in flow control.^[10]

Principles of Operation

Vortex generators (VGs) operate by protruding into the boundary layer of a fluid flow, typically as small vanes or plates oriented at an angle to the oncoming flow, which induces the formation of counter-rotating vortex pairs. These vortices generate spanwise flow components that effectively transport high-momentum fluid from the outer inviscid region into the low-momentum near-wall area of the boundary layer, thereby enhancing overall flow stability and attachment to the surface.^[10]^[11] The interaction with the boundary layer primarily delays the transition from laminar to turbulent flow or re-energizes regions prone to separation by promoting three-dimensional mixing without significantly altering the mean streamwise velocity profile far from the wall. Vortex strength is closely tied to the VG height h, which is optimally set to approximately 0.5 to 1 times the local boundary layer thickness \delta, ensuring the device remains embedded within the layer to maximize momentum transfer while minimizing parasitic effects.^[12]^[11] A key aspect of this mechanism is quantified by the circulation \Gamma around each vortex, approximated as \Gamma \approx U_\infty h \sin \alpha, where U_\infty is the freestream velocity and \alpha is the incidence angle of the VG; this circulation drives the induced tangential velocity u_\theta \approx \frac{\Gamma}{2\pi r}, with r as the radial distance from the vortex core, facilitating the necessary cross-stream mixing to counteract adverse pressure gradients.^[10]^[13] Flow visualization techniques, such as smoke wire methods, oil flow patterns, or particle image velocimetry (PIV), reveal the trailing vortices as persistent streamwise structures that alter the surface pressure distribution by reducing suction peaks and increase local skin friction through enhanced shear in the mixed region.^[10]^[11] However, if VGs are oversized relative to \delta or improperly positioned, they can generate excessive form drag and amplify turbulence intensity, potentially leading to net performance degradation rather than improvement.^[10]^[11]

History

Invention and Early Development

The vortex generator was first proposed by H. D. Taylor in 1947 while working at the United Aircraft Corporation, initially to eliminate flow separation in diffusers through boundary layer control.^[10] This development occurred in the post-World War II era. Taylor's approach involved creating streamwise vortices to mix high-energy free-stream air into the low-momentum boundary layer, thereby preventing separation without requiring complex mechanical systems.^[14] Early prototypes consisted of simple metal tabs or vanes hand-attached to wind tunnel models, positioned normal to the surface at small incidence angles to generate the desired vortices.^[11] These devices, typically with heights comparable to the boundary layer thickness, were tested in controlled environments to validate their ability to delay separation in diffusers and, subsequently, on airfoil sections. First patents related to vortex generators for aerodynamic applications were filed in the early 1950s by aeronautical engineers at organizations like United Aircraft, formalizing the technology for potential aircraft integration.^[15] The initial focus remained on experimental validation rather than full-scale deployment. A key early publication was Taylor's 1950 summary report, which detailed the fundamental vortex effects, including momentum transfer mechanisms and performance improvements in turbulent boundary layers.^[16] This work synthesized findings from wind tunnel tests and laid the groundwork for broader adoption. Vortex generators represented an evolution from precursors like boundary layer fences, which restricted spanwise flow, and trips, which promoted transition to turbulence; unlike these, vortex generators specifically produced longitudinal vortices for sustained boundary layer energization.^[10]

Adoption and Evolution

The adoption of vortex generators in aviation accelerated during the 1950s and 1960s, marking their transition from experimental devices to standard features on commercial and military aircraft. The Boeing 707, introduced in 1958, was among the first commercial jetliners to integrate vortex generators on its wings to mitigate stall characteristics and enhance low-speed controllability.^[8] In military applications, vortex generators were employed on fighter aircraft such as swept-wing designs to improve maneuverability at transonic speeds by delaying flow separation and augmenting lift during high-angle-of-attack maneuvers.^[17] During the 1970s and 1980s, vortex generator technology evolved through material innovations and computational advancements, broadening their utility in transport aircraft. Materials shifted from heavy metal tabs to lighter plastic and composite variants, reducing structural penalties while maintaining aerodynamic effectiveness.^[18] Optimization techniques, including early applications of computational fluid dynamics (CFD), enabled precise placement and sizing to maximize boundary layer control. A key milestone was NASA's research in the 1970s on the F-8 supercritical wing airplane, where vortex generators were used to suppress pitchup and influence buffet characteristics at transonic speeds.^[19] Additionally, FAA supplemental type certificates (STCs) issued in the late 1980s facilitated retrofitting vortex generators on existing fleets for performance upgrades, such as improved stall margins.^[20] From the 1990s onward, innovations like micro-vortex generators and active variants expanded the technology's scope beyond traditional aviation. Micro-vortex generators, scaled down to sub-boundary-layer heights, emerged in the late 1980s and gained prominence in the 1990s for general aviation, offering reduced drag while preserving lift benefits.^[21] Active vortex generators, which deploy dynamically via actuators, were developed in the 2000s to provide on-demand flow control, minimizing constant drag penalties.^[22] Concurrently, post-1970s oil crises spurred adoption in wind energy during the 2000s, where vortex generators on turbine blades increased annual energy production by up to 2.6% at low wind speeds by stabilizing airflow and delaying separation.^[23] In the 2020s, computational tools including CFD have refined designs for emerging applications like drones and electric vertical takeoff vehicles, enhancing efficiency in urban and low-speed environments.^[24] Throughout this evolution, early challenges such as induced drag were addressed through meticulous tuning of generator spacing and height, ensuring net aerodynamic gains; for instance, optimal spacing ratios around five times the generator height can boost lift by nearly 50% with minimal drag increase.^[25] Patents in the 2000s further propelled non-aviation uses, such as in automotive aerodynamics, by protecting designs for boundary layer management on ground vehicles.^[26]

Applications

In Aviation

Vortex generators are widely used in aviation to manage airflow over aircraft surfaces, enhancing overall flight characteristics without requiring extensive structural changes. These small aerodynamic devices are typically installed on fixed-wing aircraft to improve performance during critical flight phases, such as takeoff, landing, and low-speed maneuvers.^[27] In aircraft design, vortex generators are primarily located on wings at the leading or trailing edges, tailplanes, nacelles, and flaps to control spanwise flow and prevent tip stall. On wings, they are often placed forward of control surfaces like ailerons to maintain attached airflow during high angles of attack. Nacelle strakes, a type of vortex generator, are strategically positioned on engine pods to induce vortices that stabilize flow around protrusions.^[27]^[28] Their application spans various aircraft types, including general aviation planes like the Cessna 172, where they are a popular supplemental type certificate (STC) modification for better handling. Commercial airliners, such as the Boeing 737, incorporate them as nacelle strakes to optimize engine airflow. In military jets, like the F/A-18 Hornet variants, vortex generators support high-alpha performance by mitigating flow separation in inlets and wings during aggressive maneuvers.^[29]^[28]^[30] Integration typically involves counter-rotating pairs on airfoils to generate paired vortices that effectively energize the boundary layer while minimizing drag penalties. These installations must comply with aviation regulations, such as FAR Part 25 for transport category airplanes, ensuring certification through flight testing and structural analysis for supplemental type certificates.^[10]^[31] The broader benefits in aviation include enhanced low-speed handling for safer approaches, improved short-field performance on STOL-configured aircraft, and gust load alleviation to reduce structural stresses during turbulent conditions—all achieved without major airframe redesigns. Vortex generators are widely used in modern fixed-wing aircraft and have seen growing adoption in unmanned aerial vehicles (UAVs) since the 2010s to optimize endurance and maneuverability in diverse missions.^[32]^[33]^[34]^[35]^[36]

In Wind Energy and Other Fields

Vortex generators (VGs) are employed on wind turbine blades to delay boundary layer separation, particularly at low wind speeds where flow detachment typically reduces efficiency. By energizing the boundary layer through induced vortices, these devices maintain attached flow over the airfoil, thereby enhancing lift and overall aerodynamic performance. Studies have shown that applying VGs to turbine blades can increase annual energy production (AEP) by an average of 2.6% under low-wind conditions, with broader implementations yielding gains of up to 2%. For instance, Vestas has integrated VGs into the blades of its V90-3.0 MW turbines as part of aerodynamic upgrades, contributing to improved energy yields since the late 2000s. In wind energy applications, these modifications focus on optimizing the power coefficient (Cp), with reported improvements of up to 3%, contrasting with aviation uses that prioritize lift enhancement at high angles of attack.^[23]^[37]^[38] Specialized VG designs, such as those exhibiting helical symmetry, further refine axial flow control on turbine blades by promoting self-similar vortex structures that sustain momentum transfer along the span. This configuration mitigates separation more effectively in the rotor's rotational environment, leading to sustained performance gains across varying wind regimes. Retrofits of such VGs on existing turbines have demonstrated consistent AEP uplifts of 1.7-2%, underscoring their role in extending the operational life and output of aging wind farms.^[39] Beyond renewable energy, VGs find applications in automotive engineering, where they are integrated into spoilers and body panels of race cars to generate downforce and reduce drag in ground effect. These devices create controlled vortices that energize the underbody flow, preventing separation and improving high-speed stability; for example, parametric studies on ground vehicles show drag reductions of up to 4.23% with optimized VG placements. In marine contexts, VGs are applied to hydrofoils and hulls to enhance hydrodynamic performance by delaying separation in turbulent water flows, thereby reducing viscous drag on high-block-coefficient ships. Research on wedged VGs for vessels indicates net drag reductions through boundary layer re-energization, analogous to their wind turbine roles but adapted for submerged conditions.^[40]^[41]^[42] In heat exchangers, VGs promote turbulence to boost heat transfer rates while minimizing pressure losses; configurations like modified delta-wing VGs have achieved Nusselt number increases alongside drag reductions of 3.2%, making them valuable for compact thermal systems in industrial applications. For ground vehicles beyond racing, underbody VGs on sedans and SUVs manage wake turbulence, yielding drag coefficients improvements through vortex-induced mixing that delays rear-end separation. These non-aeronautical uses highlight VGs' versatility in stationary and low-speed fluid dynamics, prioritizing energy efficiency and load management over dynamic lift control.^[10]^[43]

Aerodynamic Effects in Aircraft

Lift and Drag Modifications

Vortex generators (VGs) primarily enhance lift on aircraft airfoils by energizing the boundary layer, which delays flow separation and increases the maximum lift coefficient (C_{L_{max}}) through controlled vortex formation that mixes high-momentum free-stream air into the low-energy boundary layer near the surface.^[44] Typical increases in C_{L_{max}} range from 10% to 20% for optimized configurations across various airfoil types, as documented in aerodynamic studies.^[45] For instance, investigations on airfoils have shown lift enhancements at high angles of attack with appropriately shaped VGs. Regarding drag, VGs introduce a small parasitic drag penalty due to their form drag, typically on the order of ΔC_D ≈ 0.001-0.002 at cruise conditions, yet they yield a net reduction in profile drag under off-design conditions by mitigating separation-induced pressure drag.^[46] Wind tunnel investigations confirm this trade-off, with minimal drag increments for VGs placed forward on the chord, and greater benefits in separated flow regimes.^[46] Optimal placement of VGs on subsonic airfoils typically occurs just ahead of the expected separation point, often around 20-60% of the chord length, to target the adverse pressure gradient effectively.^[47] This positioning allows generated vortices to interact with the boundary layer without excessive disruption. Empirical testing underscores these modifications: wind tunnel data reveal stall angle increases by several degrees with VG application, extending the usable lift range. In a real-world example, wind tunnel tests on a scaled Piper Cherokee wing with rectangular VGs in co-rotating arrays demonstrated lift enhancements compared to the clean configuration.^[48] The trade-offs are angle-of-attack dependent, with pronounced lift benefits and drag reductions emerging at higher AoA where separation risks rise, while cruise conditions experience negligible gains offset by the minor parasitic penalty.^[49]

Stall Prevention and Control Enhancement

Vortex generators (VGs) mitigate stall in aircraft by generating streamwise vortices that energize the boundary layer through enhanced mixing of high-momentum free-stream air with low-momentum near-wall flow, thereby promoting flow reattachment and delaying separation to higher angles of attack (AoA).^[10] This mechanism maintains attached airflow over the wing surface, reducing the likelihood of abrupt lift loss during high-AoA maneuvers such as landing approaches. On control surfaces like ailerons and elevators, VGs stabilize airflow and prevent premature separation, which enhances control authority at near-stall conditions.^[50] This improvement is particularly valuable for preserving handling qualities when the main wing is approaching stall. Placement of VGs is critical for stall prevention, with outboard installations on wingtips delaying tip stall to preserve aileron effectiveness and prevent uncommanded roll-off, while inboard placements focus on root flow control. An empirical design rule sets VG height at approximately h ≈ δ, where δ is the local boundary layer thickness, to optimize vortex strength without excessive drag.^[47] Notable case studies illustrate these benefits: Aftermarket VG kits on general aviation aircraft have demonstrated reduced stall speeds and improved low-speed handling.^[51] Despite these advantages, VGs have limitations; they are less effective in fully separated flows or transonic regimes where shock waves can interfere with vortex effects.^[44]

Performance Impacts

Weight and Load Considerations

Vortex generators (VGs) can enable increases in an aircraft's maximum takeoff weight (MTOW) by enhancing climb performance and reducing stall speeds, thereby allowing certification for higher gross weights under FAA supplemental type certificates (STCs). For instance, an STC for the Piper PA-23-250 permits a 5% increase in takeoff gross weight through VG installation on the wing and vertical stabilizer.^[31] Similar approvals for light twin-engine aircraft, such as the Cessna 414A, allow gross weight increases of up to 350 pounds, while the Cessna T310R benefits from a 385-pound rise in zero-fuel weight, equating to roughly 5-10% gains relative to baseline MTOW in these categories.^[52]^[53] While VGs do not alter the structural maximum landing weight (MLW), their improvement in low-speed control and stall characteristics permits safer approaches at or near MLW without necessitating speed reductions that could compromise safety margins.^[18] This enhanced handling ensures compliance with operational limits during landing, avoiding penalties from excessive speeds tied to inadequate airflow management.^[54] The structural implications of VGs include minimal added weight, typically constituting less than 0.5% of the aircraft's empty mass due to their small size and use of lightweight aluminum construction.^[7] However, the devices redistribute aerodynamic loads across the wing, necessitating fatigue analysis during certification to verify long-term integrity under cyclic stresses.^[18] For transport-category aircraft, such evaluations align with FAA regulations under 14 CFR 25.345, which specify load factors for high-lift configurations, ensuring VGs do not exceed design envelopes.^[55] Historical retrofits, such as those on 1970s-era commercial jets like the McDonnell Douglas DC-9 series using vortilons (a variant of VGs), were certified without significant MTOW changes but demonstrated load redistribution benefits under similar regulatory scrutiny.^[56] Trade-offs involve a slight rise in empty weight from the VGs themselves, which can partially offset payload gains, though the net aerodynamic advantages generally prevail in certified applications.^[54]

Noise Reduction

Vortex generators (VGs) installed on flaps and slats mitigate airframe noise during landing configurations by energizing the boundary layer, smoothing flow separation, and diminishing vortex shedding at high-lift device edges. This process reduces the intensity of turbulent shear layers that generate acoustic radiation, particularly from the interaction of separated flows with trailing edges. Targeted applications on flap side-edges have yielded up to 1.5 dB in specific frequency bands.^[57] Specific implementations include VGs on landing gear struts and high-lift devices to control bluff-body wakes and cove instabilities. For instance, NASA experiments in the 1990s on modified high-lift systems, including flap noise assessments, reported approximately 3 dB reductions in flap-generated noise through VG-induced flow diffusion. These devices are particularly effective on slat coves and flap tips, where they alter spanwise loading gradients to suppress edge vortex formation.^[58]^[59] Acoustically, VGs suppress broadband noise arising from turbulent mixing in shear layers, primarily affecting frequencies between 500 and 2000 Hz, which dominate airframe contributions during approach. By promoting earlier transition to turbulence and reducing large-scale coherent structures, they attenuate the radiated power from these mechanisms without significantly altering overall lift. This targeted suppression aligns with regulatory requirements, such as FAA Stage 5 noise standards, which mandate cumulative reductions for community exposure.^[57]^[60] In practice, the Airbus A320 family employs vortex generators as a retrofit to reduce whistling noise from wing tank vents during approach, achieving up to 4 dB reduction as of 2015 and contributing to community noise compliance. However, VGs have minimal impact on cruise noise levels and are most effective when integrated with complementary treatments, such as acoustic liners in nacelles, to address multifaceted noise sources.^[61]

Installation and Design

Original Equipment Integration

In the design phase of aircraft manufacturing, vortex generators (VGs) are optimized for placement using computational fluid dynamics (CFD) simulations and wind tunnel testing to ensure effective flow control without compromising overall aerodynamics.^[62]^[63] These methods allow engineers to model vortex interactions with the boundary layer, determining precise locations—typically ahead of potential separation points—to maximize lift enhancement and stall delay.^[10] Materials for VGs in original equipment manufacturer (OEM) applications commonly include lightweight aluminum alloys, such as 6063-T6, or composite materials, which are bonded to the airframe using high-strength adhesives like Loctite AA 330 to ensure durability under aerodynamic loads.^[64]^[65]^[7] During the manufacturing process, VGs are produced via CNC machining for metal variants or molding for composites, enabling precise replication of aerodynamic shapes.^[64] They are installed on wing surfaces prior to the painting stage to integrate seamlessly with the airframe skin, avoiding surface irregularities that could arise from post-paint adhesion. Array spacing is typically set at 3 to 5 times the chordwise height of the individual generators to optimize vortex merging and boundary layer energization without excessive drag penalties.^[66]^[67] OEM integration of VGs has been a standard practice in modern commercial aircraft, such as Boeing models where they contribute to flow management on wings and control surfaces as part of the baseline design.^[68] This factory-level incorporation minimizes production disruptions and ensures aerodynamic consistency across the fleet. Emerging technologies, such as smart or retractable vortex generators, are being explored for future OEM designs to further optimize performance across flight regimes.^[69] VGs undergo rigorous testing as integral components of the aircraft, including full-scale static load evaluations and flutter dynamics assessments to verify structural integrity under operational stresses.^[70] Durability is confirmed through compliance with standards like MIL-STD-810, which includes vibration and environmental exposure protocols relevant to VG performance in flight conditions.^[71] The primary advantages of OEM VG integration lie in achieving seamless aerodynamic surfaces that enhance performance from the outset, eliminating the need for subsequent field modifications and supporting efficient certification processes.^[62]

Aftermarket and Retrofit Methods

The retrofit process for installing vortex generators on existing aircraft typically begins with thorough surface preparation to ensure adhesion and longevity. The aircraft surfaces, such as wings, horizontal stabilizers, and vertical stabilizers, must be cleaned to remove contaminants like dirt, grease, and old paint using approved solvents, followed by abrading or scuffing to create a suitable bonding area without compromising the airframe integrity.^[72] Adhesives commonly employed include high-strength double-sided tapes, such as 3M VHB acrylic foam tapes, which provide a secure, weather-resistant bond suitable for aerodynamic environments. Precise alignment is achieved using manufacturer-provided templates or laser-guided tools to position the generators at specific chord percentages and spacings, often requiring masking tape for temporary placement before final commitment. For small general aviation aircraft, the full installation, including both wings and control surfaces, generally requires 6-14 man-hours, depending on the aircraft size and installer experience, and must be performed by certified mechanics in accordance with FAA Supplemental Type Certificate (STC) instructions.^[7]^[73] Several suppliers offer STC-approved kits tailored for aftermarket retrofits, enabling compliance with FAA regulations for certified aircraft. Micro AeroDynamics provides comprehensive kits made from aircraft-grade aluminum, including all necessary vortex generators, templates, adhesives, and installation manuals, with STCs available for models like the Cessna 150/152, 172, and Maule M-7 series. Other providers, such as BLR Aerospace and D'Shannon Aviation, offer similar certified options for twin-engine and Beechcraft aircraft, with permanent metal generators suitable for both certified and experimental applications. These kits are designed for field installation without major airframe modifications. Costs for kits on small aircraft typically range from $750 to $3,245, excluding labor.^[74]^[75]^[76] Retrofitting vortex generators presents specific challenges, particularly regarding airframe stress analysis and certification compliance. Installers must conduct or reference engineering evaluations to verify that added components do not induce unintended aerodynamic loads or fatigue on aging structures, often requiring FAA Form 337 documentation for major alterations. Improper installation or use of non-STC kits can void manufacturer warranties and necessitate additional inspections to maintain airworthiness directives. Precise placement is critical to avoid interference with existing seams, rivets, or inspection panels, potentially complicating non-destructive testing if generators obstruct access points.^[77]^[73] Historical examples illustrate the application of retrofits to extend service life on aging fleets. In the late 1960s, Douglas Aircraft introduced vortilons—specialized leading-edge vortex generators—as an optional modification for DC-9 aircraft, aimed at improving high-speed stability and reducing vertical bounce during cruise; this modification was applied to existing fleets to enhance handling without full redesigns. Similar retrofits in the 1980s on DC-9 and MD-80 series helped prolong operational viability, providing measurable safety and efficiency gains for operators. Maintenance of retrofitted vortex generators follows FAA Advisory Circular (AC) 43.13-1B guidelines for aircraft inspections and repairs, emphasizing periodic visual checks for adhesion integrity, damage, or looseness. Pilots and mechanics should inspect the generators pre-flight and during routine 100-hour or annual inspections, looking for signs of delamination, corrosion, or aerodynamic wear, with repairs limited to replacing individual units using approved methods. Removal for non-destructive testing is feasible with non-destructive adhesives, allowing temporary detachment without residue or airframe damage, though certified installations require logging all actions in the aircraft maintenance records.^[78]

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[PDF] Wedged Vortex Generator Applications for Marine Vessels
Oct 29, 2025 · ABSTRACT. This thesis investigates the effectiveness of vortex generators (VGs) in reducing viscous drag in hydrodynamic applications.Missing: ground | Show results with:ground
[40]
[PDF] drag reduction using vortex generator - ijirset
One of the main causes of aerodynamic drag in vehicle is flow separation near the vehicle's rear end. To control the flow separation vortex generators are used.<|separator|>
[41]
Effect of aero-shaped vortex generators on NACA 4415 airfoil
Jan 1, 2024 · In general, counter-rotating and co-rotating are the most used positioning types to attach VGs. The effectiveness of counter rotating, that ...
[42]
Review of Research on Low-Profile Vortex Generators to Control ...
An in-depth review of boundary-layer flow-separation control by a passive method using low-profile vortex generators is presented.
[43]
[PDF] NACA RESEARCH MEMORANDUM
i-he changes in airplane drag caused by the vortex generators are shown in figures 19 and 20. Figure 19, the variation with Mach number of the drag ...
[44]
Prediction of the Effect of Vortex Generators on Airfoil Performance
Aug 10, 2025 · Using high fidelity CFD analysis, a parametric study regarding the optimum position of vortex generators is carried out using an in-house ...
[45]
[PDF] determining-an-optimum-vortex-generator-configuration-for-a-piper ...
These configurations did not increase the maximum lift. The drag reduction did, however, prove substantial enough to suggest this application. Proper spacing of ...
[46]
Stalling & Spinning – Introduction to Aerospace Flight Vehicles
These devices are known as vortex generators, or VGs. They are designed to create small vortices to energize the boundary layer flow and keep the flow attached ...
[47]
[PDF] NATIONAL ADVISORY COMMl1YIEE FOR AERONAUTICS
The application of vortex generators to shock- induced flow separation is discussed in references 3 and 4. Reference 5 presents results of flight tests of a ...
[48]
[PDF] effect of boundary layer thickness and passive vortex generators on ...
By comparing the devices with different height, they concluded that the vortex generator with h/δ ≈ 0.8 provided the largest pressure recovery but was ...
[49]
[PDF] Contributions of the Langley Research Center to U.S. Military Aircraft ...
Spin Recovery The YF-16 and F-16 configurations underwent extensive tests in the Langley Spin Tun- nel to determine spin and spin recovery characteristics ...
[50]
Micro Vortex Generator Kits For Beechcraft | Aircraft Spruce ®
Free delivery over $350 30-day returnsNov 16, 2013 · Micro Vortex Generators from Micro Aerodynamics, Inc. are available for a wide range of aircraft and can reduce stall speed, improve aileron ...
[51]
Cessna 414A - Micro Vortex Generators
MICRO Vortex Generator Kit for the Cessna 414A is FAA STC approved and ready for installation on your airplane. The Micro VG Kit includes the STC, VGs, ...Missing: DC- 9 retrofit
[52]
Vortex Generators: Band-Aids or Magic? - AVweb
Nov 13, 1997 · First used in England, VGs have been usedon transport jets for decades, and on bizjets since Bill Lear invented them.
[53]
Vortex Generators:High-Value Safety Enhancers - Aviation Consumer
Vortex generators appeared nearly 50 years ago, initially to channel localized areas of disturbed airflow over wings that lead to loss of control response. On ...Missing: invented | Show results with:invented
[54]
Micro AeroDynamics Inc: Micro Vortex Generators
Improve your aircraft's performance and control with our Micro Vortex Generators, manufactured under our FAA PMA from aircraft grade aluminum.FAQs · Catalog · Testimonials · Video Gallery<|control11|><|separator|>
[55]
eCFR :: 14 CFR 25.345 - High lift devices.
The airplane must be designed for a maneuvering load factor of 1.5 g at the maximum take-off weight with the wing-flaps and similar high lift devices in the ...Missing: vortex generators certification
[56]
Why "Vortilons" on DC-9, MD-80, B717? - PPRuNe Forums
Nov 20, 2008 · Why "Vortilons" on DC-9, MD-80, B717? ... The vortilon solution had less drag than the wing fence and required fewer vortex generators.Missing: retrofit MTOW
[57]
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Summary of each segment:
[58]
Airframe Noise Reduction of Flap Side-edge Using Vortex Generators
In this study, a practical noise reduction concept using vortex generators is proposed to reduce airframe noise from flap side-edge.
[59]
[PDF] Airframe Noise Studies – Review and Future Direction
Jun 1, 2005 · By reducing the slat gap by one percent of the stowed wing chord, it is shown that 5 dB noise reduction can be achieved in the peak radiation ...
[60]
Airframe Noise Reduction of Flap Side-edge Using Vortex Generators
Although the noise reduction in the baseline configuration was approximately 1.5 dB ... noise generation of the flap-edge and the slat. One of the most ...
[61]
[PDF] AC 36-4D - Noise Standards - Federal Aviation Administration
Dec 10, 2017 · It is applicable for noise certification of normal, utility, acrobatic, commuter and transport category airplanes and normal and transport.
[62]
Active noise control: Condor's Airbus fleet upgraded with Vortex ...
Dec 1, 2015 · Vortex generators are aerodynamic devices that are attached to the wings to aid in reducing the Airbus-typical whistling noise created during ...<|separator|>
[63]
[PDF] Vortex Generator Installation Studies on Steady State and Dynamic ...
Therefore, the use of vortex generators as a "global' method of secondary flow control allows for the formal application of. CFD and numerical optimization.
[64]
[PDF] Design Optimization of Vortex Generator Array to Delay Pitch-up on ...
This paper optimizes vortex generators (VGs) to delay pitch-up on tailless aircraft by suppressing flow separation, using a mathematical model for VGs.
[65]
Micro Vortex Generator Kits For Maule | Aircraft Spruce ®
The generators are manufactured under FAA/PMA from 6063T6 aluminum and are curved to fit the contour of the wing. Included in the kits are installation tools, ...
[66]
What does "Vortex Generator" mean? - GlobeAir
A Vortex Generator is a small aerodynamic device installed on an aircraft's wings or other parts. Its primary function is to control the airflow over the wing.Missing: definition | Show results with:definition
[67]
Effect of vortex generator spanwise height distribution pattern on ...
Feb 2, 2023 · The concept of vortex generator (VG) was first proposed by Taylor in 1947 ... aerodynamics and performance of a smart vortex generator system.
[68]
(PDF) Analysis of the Effect of Vortex Generator Spacing on ...
Oct 16, 2025 · When the VG spacing was λ/H = 5, the maximum lift coefficient of the airfoil with VGs increased by 48.77% compared to that of the airfoil ...Missing: penalties tuning
[69]
[PDF] Recent Applications of CFD to the Design of Boeing Commercial ...
Apr 13, 2010 · Timely, robust, and repeatable modeling of configurations with control deflections including spoilers, vortex generators, etc. 787-9 in yaw.
[70]
[PDF] NACA Conference on Aircraft Loads, Flutter, and Structures - DTIC
May 1, 2025 · This document contains reproductions of technical papers on some of the most recent research results on aircraft loads, flutter, and struc-.
[71]
[PDF] MIL-STD-810H, Method 514.8 - CVG Strategy
Such a vortex is highly structured with a sharply peaked frequency distribution. (b) Vortex generators (small "wings") are often seen on airplane wings. The ...
[72]
Installing Stolspeed VGs
If you wish to paint your VGs, it is best done before they are installed on the wing. Even on a new aircraft it's much better to first paint the wing without ...
[73]
Vortex Generator Installation | Pilots of America
Nov 9, 2012 · I'm installing Micro AeroDynamics VGs on my Cardinal, and one of the wing VGs will sit right on top of a skin seam.Missing: CNC machined molded
[74]
Cessna 150, 150A-E - Micro Vortex Generators
In stockCessna 150, 150A-E. $750. plus shipping. MICRO Vortex Generator Kit for the Cessna ...
[75]
Vortex Generators - BLR Aerospace
“The BLR Vortex Generators make a completely different aircraft out of the Duke. ... FAA and EASA STC Approvals Wednesday, March 19, 2025; BLR Aerospace AS355 ...Missing: MTOW | Show results with:MTOW
[76]
Vortex Generators - D'Shannon Aviation
Vortex Generators · A lower stall speed, for safer landings and maneuvering flight. · Increased aileron authority at lower speeds for better control.Missing: prevention | Show results with:prevention
[77]
AC 43.13-2B - Acceptable Methods, Techniques, and Practices
Document Information ; Number: 43.13-2B ; Title: Acceptable Methods, Techniques, and Practices - Aircraft Alterations ; Status: Active ; Date issued: 2008-03-03 ...
[78]
What are these four little things between the horizontal and vertical ...
Jun 29, 2025 · It's Called Aft Vortex Generator. Vortex generators became an optional retrofit in November 1968 to reduce “vertical bounce” during cruise ...
[79]
[PDF] AC 43.13-1B - Acceptable Methods, Techniques, and Practices ...
Sep 8, 1998 · The repairs identified in this AC may only be used as a basis for FAA approval for major repairs. The repair data may also be used as approved ...