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Gust lock

A gust lock is a mechanism installed on aircraft to secure the flight control surfaces, such as ailerons, elevators, and rudders, preventing damage from wind gusts while the aircraft is parked on the ground or water.^[1] These devices are particularly essential in protecting sensitive components like hinge points, brackets, and front spars from the forces of unexpected high winds, which could otherwise cause costly structural damage requiring extensive repairs or part replacements.^[2] In transport-category airplanes, gust locks are mandated by federal regulations to ensure they automatically disengage upon normal pilot operation of the primary flight controls or provide an unmistakable warning if they limit takeoff operations, while also incorporating safeguards to prevent inadvertent engagement during flight.^[1] Typically mechanical in design, gust locks may consist of straps, pins, handles, or latches that immobilize the control column or yoke, often rated to withstand gusts up to 65 knots,^[3] and are engaged as part of standard parking procedures to mitigate risks from environmental conditions like thunderstorms.^[4] Some systems include additional features, such as baulks to restrict engine power levers beyond idle when engaged, enhancing overall ground safety.^[5] Failure to properly engage or disengage gust locks has led to airworthiness directives and investigations, underscoring their role in preventing accidents; for instance, regulatory actions have addressed vulnerabilities in specific models where system components could fail under load, allowing unintended control inputs during attempted takeoffs.^[5] Overall, gust locks represent a critical intersection of aircraft design, certification standards, and operational protocols aimed at preserving airframe integrity in non-flight scenarios.^[1]

Overview

Definition and Function

A gust lock is a device or mechanism designed to secure an aircraft's primary control surfaces—such as ailerons, elevators, and rudders—against unintended movement caused by wind gusts while the aircraft is parked and non-operational.^[6]^[7] These locks may also secure secondary elements like tabs to prevent flapping or oscillation.^[6] In essence, a gust lock immobilizes the flight control system to safeguard its components during ground exposure to environmental forces.^[8] The primary function of a gust lock is to prevent structural damage to control surfaces, linkages, actuators, and associated cables by limiting deflection and absorbing or redirecting wind-induced loads.^[6] By restraining movement, it maintains the overall structural integrity of the flight control system, which could otherwise suffer fatigue, cracks, or complete failure under repeated gust stress.^[7] Gust locks can be internal cockpit mechanisms, such as levers or cams that engage the control quadrant, or external attachments that physically pin surfaces in place, ensuring comprehensive protection across various aircraft designs.^[8] Aircraft control surfaces are particularly vulnerable when parked because they are lightweight and aerodynamically shaped to respond to airflow in flight, making them prone to flapping or violent oscillation in strong winds, which can overload hinges, cables, and actuators leading to wear or breakage.^[6] Without restraint, these dynamic forces can propagate through the entire control linkage, causing progressive damage over time or sudden failures in severe gusts.^[7] In aviation practice, gust locks are a standard requirement on most fixed-wing aircraft equipped with mechanical flight controls, as mandated by manufacturers and regulatory standards to ensure safe ground handling and compliance with ground gust load criteria, such as those limiting hinge moments at 65-knot reference winds.^[6]^[9] This necessity underscores their role in preserving airworthiness between flights, particularly at exposed airfields.^[8]

Historical Development

Gust locks trace their origins to the early 20th century, coinciding with the widespread use of open-air storage for biplanes and early monoplanes in the 1920s and 1930s. During this period, simple mechanical restraints such as pins or fabric ties were commonly used to secure control surfaces like ailerons, elevators, and rudders against wind-induced movement, preventing structural damage to these lightweight components on fabric-covered aircraft. By the mid-1930s, more formalized gust lock mechanisms appeared on larger aircraft, as evidenced by their role in the 1935 crash of the Boeing Model 299 prototype, where failure to disengage the gust lock led to loss of control during takeoff and underscored the device's critical function in ground operations.^[10] Following World War II, the advent of commercial jet aviation in the 1950s drove advancements in gust lock design, shifting from ad hoc restraints to integrated, standardized mechanical latches suited for high-performance aircraft. This evolution supported the expansion of airline fleets, where reliable protection of hydraulic and cable-linked controls became essential during extended ground periods at airports.^[11] Regulatory milestones began in the 1960s with the U.S. Federal Aviation Administration's (FAA) establishment of Federal Aviation Regulations (FAR) Part 25 in 1965, which included § 25.679 mandating gust locks to safeguard control systems from ground gusts while preventing inadvertent engagement during flight.^[1] This requirement influenced international standards, with precursors to the European Union Aviation Safety Agency (EASA)—such as national authorities and later the Joint Aviation Authorities (JAA) from the 1970s—adopting similar airworthiness criteria emphasizing automated interlocking features in the jet age. Airworthiness directives (ADs) further refined these standards amid rising safety concerns.^[12] The transition to the modern era in the 1980s and 2000s saw a partial shift with the proliferation of fly-by-wire (FBW) technology, first implemented in production aircraft like the Airbus A320 in 1988, which eliminated mechanical linkages and reduced the need for traditional internal gust locks by relying on electronic safeguards against unintended inputs.^[13]^[14] Nonetheless, gust locks persisted for legacy mechanically controlled systems and as external devices to protect physical control surfaces from wind damage during parking, particularly in high-wind environments, ensuring compatibility across mixed fleets.

Types and Mechanisms

Mechanical Gust Locks

Mechanical gust locks are physical devices designed to restrain aircraft control surfaces and mechanisms when the aircraft is parked, preventing damage from wind gusts. These locks typically consist of pins, levers, cables, latches, hooks, and springs that secure the primary flight controls, such as ailerons, elevators, rudders, and control columns. In many implementations, a cockpit-mounted handle, often a T-shaped lever, connects via cables and pulleys to multiple locking points, engaging latches that hold surfaces in place. For instance, in Gulfstream business jets, the gust lock system includes a 3/32-inch diameter 7x7 cable linking the handle to aileron locks at fuselage station (FS) 283 and elevator/rudder locks at FS 775, incorporating bungee rods and springs for tension and release.^[15] External variants may use straps with tensioners and hooks to secure yokes or pedals, as seen in Learjet models where a simple strap assembly (part number 12645-144-015) loops around the control column.^[2] Design principles emphasize positioning controls in a neutral or low-stress configuration to minimize structural strain during engagement, such as holding ailerons and rudders neutral while allowing elevators to deflect slightly downward (e.g., 13° in Gulfstream systems) to balance aerodynamic loads. Materials are selected for weather resistance and durability, including rigid metals or composites for plates and frames, woven nylon for straps, and stainless steel cables to withstand corrosion from environmental exposure. Attachment points are strategically located on control yokes, rudder pedals, and surface hinges, with rotatable elements like strap locks and capture pieces enabling flexible installation across seams without impeding access. These designs ensure the lock engages only when controls are properly aligned, often using cammed lead-ins and spring-loaded mechanisms to prevent partial or ineffective securing. Compliance with Federal Aviation Administration (FAA) regulations under 14 CFR § 25.679 requires that mechanical gust locks automatically disengage upon normal pilot input or provide clear warnings against in-flight operation, verified through testing and analysis.^[16]^[15]^[6] Variations in mechanical gust locks adapt to aircraft size and complexity, with small general aviation (GA) fixed-wing planes often employing simple, external pins or straps that directly secure the control column or yoke to adjacent structures, allowing quick installation in seconds. In contrast, larger jets like the Hawker 800 use integrated systems with a cockpit lever operating a clamp for ailerons and elevators alongside a separate bar for the rudder, linking multiple surfaces through cables for coordinated restraint. These multi-surface locks interface with control columns via tensioned rods and hooks, ensuring simultaneous securing of lateral, longitudinal, and directional controls, while external options like plate-and-strap assemblies provide portable alternatives for varied parking conditions.^[14]^[2] Maintenance for mechanical gust locks focuses on periodic inspections to detect corrosion on metal components, particularly cables and latches exposed to moisture, with lubrication applied to moving parts like pulleys and springs to ensure smooth operation. Replacement intervals follow manufacturer guidelines in the aircraft maintenance manual, such as checking Gulfstream springs during preflight in the aft equipment compartment and verifying full engagement up to 60-knot winds. The FAA's Instructions for Continued Airworthiness (14 CFR Appendix H to Part 25) mandate documentation for these systems as part of type design, emphasizing pilot verification of lock functionality before flight to avoid inadvertent engagement.^[15]^[6]^[14]

Integrated and Alternative Systems

Many modern commercial aircraft, including the Boeing 737 and Airbus A320, do not incorporate dedicated internal mechanical gust locks but instead rely on portable external gust locks and the aircraft's structural design to withstand ground winds up to 65 knots, as required by 14 CFR §25.415. When powered on the ground, hydraulic or pneumatic actuators in these aircraft provide some damping to control surfaces, but primary parked protection uses external devices such as straps or pins to secure yokes, pedals, and surfaces.^[17]^[6] Electrical variants appear in some fly-by-wire designs, where solenoid-operated locks may integrate with electronic control units for ground use, automatically disengaging upon pilot input. However, systems like the Boeing 787's sensor-based gust suppression primarily address in-flight turbulence alleviation rather than parked gust protection; for ground operations, the 787 employs mechanical or external locks similar to other widebody jets.^[14]^[18] Alternative methods supplement or replace traditional locks in specialized applications, such as ground crew ties that secure control surfaces to the airframe using adjustable straps or cables for temporary protection during maintenance. In helicopters, adaptations include pin-based locks through the cyclic and collective controls to immobilize the swashplate, while unmanned aerial vehicles (UAVs) employ software-imposed limits in their digital flight controllers to cap servo deflection when grounded and powered.^[14] These alternatives prioritize simplicity and portability, often used when integrated systems are unavailable or during power-off states. Such systems offer advantages like minimized human error through automation and seamless integration with existing avionics, enhancing efficiency in high-wind environments. However, they introduce limitations, including reliance on electrical or hydraulic power sources that require robust fail-safes to prevent lock failures during outages. Regulatory approvals for retrofitting these on older aircraft typically involve supplemental type certificates (STCs) from authorities like the FAA, ensuring compliance with strength and disengagement standards under 14 CFR §25.679.^[6]

Operational Procedures

Installation and Engagement

Before installing a gust lock, pilots must conduct pre-installation checks to evaluate environmental conditions and aircraft readiness. This includes assessing current and forecasted wind speeds and directions, as strong or gusty winds can exert significant forces on control surfaces; gust locks are recommended when extreme winds are anticipated or during extended parking periods to prevent damage. The appropriate lock type should be selected based on the aircraft model, such as a simple mechanical pin for general aviation aircraft or a cockpit-integrated system for business jets, ensuring compatibility with the specific control surfaces. Additionally, the aircraft should be parked heading into the prevailing wind to minimize aerodynamic loads, and wheels chocked if necessary.^[14]^[19] For mechanical gust locks commonly used on small general aviation aircraft, engagement follows a straightforward step-by-step process. First, position the control surfaces in their neutral or designated safe position—typically ailerons neutral and elevators with trailing edge down—to align with the lock mechanism. Insert the shaped steel rod or pin into the pilot's control wheel shaft and collar, securing the ailerons and elevators against movement; this is achieved by aligning the hole in the top of the lock with the shaft for a firm fit. For the rudder, attach an external surface control lock over the vertical stabilizer and rudder assembly, often using straps or pins to hold it in place, particularly in high-wind conditions. Verify the lock's engagement by attempting gentle movement of the controls, ensuring no play exists, and store any removable components securely.^[19]^[14] In aircraft equipped with integrated gust lock systems, such as certain business jets, engagement is performed from the cockpit via a dedicated lever or handle. For example, on the Hawker 800 series, pilots use a clamp on the yoke to lock the ailerons and elevators in neutral, followed by securing the rudder using a bar on the rudder pedals; visual indicators or detents confirm full engagement. This multi-step sequence ensures all primary flight controls are immobilized, often with the throttles partially advanced to prevent inadvertent movement. Always cross-check the system's status using cockpit annunciators if available before leaving the aircraft.^[14] Aircraft-specific protocols vary to account for design differences. On the Cessna 172 Skyhawk, a common general aviation example, the process involves installing the standard control wheel lock post-landing to secure the yoke, combined with a rudder gust lock if equipped, typically a simple pin inserted into the rudder assembly for added protection in gusty conditions. In contrast, commercial jets like the Boeing 737 rely primarily on powered flight controls with inherent damping, typically not requiring manual gust locks for primary flight surfaces, though ground crew may apply external protections for specific components during parking on exposed ramps. These procedures emphasize model-specific checklists from the pilot's operating handbook to ensure proper application.^[19]^[14] Environmental considerations play a key role in effective gust lock use. When securing an aircraft in a hangar, locks may suffice alone due to shelter from wind, but on open ramps or tie-down areas, they should be combined with wheel chocks and tie-down ropes or chains (minimum 700 pounds tensile strength) attached to wing, tail, and nose fittings for comprehensive protection against severe weather. In all cases, orient the aircraft into the wind and monitor local forecasts to proactively engage locks, avoiding reliance on locks in hurricane-force conditions where evacuation or additional mooring is required.^[19]^[17]

Disengagement and Pre-Flight Verification

Disengagement of gust locks typically involves reversing the engagement process to ensure all components are fully released before flight operations commence. For mechanical gust locks, pilots or ground crew begin by accessing the locking mechanisms, such as releasing spring-loaded handles on control yokes or removing cotter pins and cables that secure ailerons, elevators, and rudder pedals. Visual and tactile confirmation follows, where personnel verify that control surfaces move freely without binding or resistance, often by manually sweeping the yoke, pedals, and trim wheels through their full range of motion. This step is critical to prevent residual locking that could compromise aircraft control during takeoff.^[14] Pre-flight verification integrates gust lock disengagement into standardized checklists, as outlined in Federal Aviation Administration (FAA) guidelines, to confirm operational readiness. According to the FAA's Airplane Flying Handbook, pilots must remove control locks as part of the preflight inspection sequence and perform full control surface checks before engine start, ensuring ailerons, elevators, and rudders deflect correctly in all directions without obstruction. These checks align with FAA standards under 14 CFR Part 91, where the aircraft's Airplane Flight Manual (AFM) or Pilot's Operating Handbook (POH) specifies inclusion in the "before start" or "before takeoff" procedures, often involving a second crew member for cross-verification in multi-pilot operations. Tools like mirrors may be used for external inspections of hard-to-see areas, such as tail surfaces, to affirm complete freedom of movement.^[20] Common errors in disengagement include incomplete removal of pins or oversight during rushed preflights, which have led to incidents where locked controls prevented proper aircraft response. To mitigate these, aviation authorities recommend using placards or warning flags on the instrument panel as visual reminders, alongside verbal crew briefings in multi-pilot environments to enforce positive confirmation of lock removal. The National Transportation Safety Board (NTSB) emphasizes disciplined checklist adherence and independent dual inspections to catch such oversights, reducing the risk of takeoff attempts with engaged locks.^[21] Following disengagement, gust locks must be properly stowed to avoid becoming foreign object debris (FOD) that could damage engines or control systems during subsequent operations. Manufacturer guidelines, as referenced in FAA Advisory Circular 20-106, direct storage in designated onboard compartments or secured external bags, ensuring locks are tethered or contained to prevent loose parts from entering air intakes or walkways. Documentation of the disengagement and storage in the aircraft maintenance logbook completes the process, providing an audit trail for airworthiness compliance.^[8]

Safety Implications

Prevention of Damage

Gust locks play a critical role in mitigating wind-induced threats to aircraft structures and systems when the aircraft is parked or stationary. Strong gusts can induce aerodynamic flutter in control surfaces such as ailerons, elevators, and rudders, resulting in hinge wear, cable fraying, or permanent deformation of surfaces and linkages. These effects arise from repeated oscillations that amplify stresses over time, particularly in unlocked systems exposed to crosswinds. For instance, certification standards require aircraft to withstand peak ground gusts up to 65 knots without structural failure, where such winds can generate limit loads equivalent to thousands of pounds of force on control surfaces depending on aircraft size and surface area.^[22]^[23] Even moderate winds exceeding 30 knots pose risks by causing excessive flapping, which can accelerate fatigue in components if not restrained.^[24] By securing control surfaces in a neutral position, gust locks limit deflection and absorb wind loads at designated points, preventing the dynamic movements that lead to damage. This restriction typically confines surface motion to minimal levels, protecting against the peak excursions that would otherwise strain hinges and actuators. Over the long term, consistent use of gust locks extends the service life of flight control components by reducing cumulative wear and the incidence of hidden cracks or misalignments.^[22]^[6] Beyond basic parking, gust locks provide essential protection during maintenance activities, prolonged storage, or exposure to severe weather events, where aircraft may remain unattended for extended periods. They are often integrated with complementary ground restraints, such as wheel chocks, to enhance overall stability and minimize leverage from wind forces acting on the tail or wings.^[25]^[17] Studies and regulatory guidance underscore the effectiveness of gust locks in reducing damage incidents. Federal Aviation Administration advisories highlight that proper application of gust locks mitigates the risks of ground gust loads, with design requirements ensuring no interference during normal operations while providing robust protection, emphasizing their role in preserving airworthiness and operational safety.^[22]

Notable Incidents and Lessons Learned

One of the most significant incidents involving a gust lock failure occurred on May 31, 2014, when a Gulfstream Aerospace G-IV (N121JM) overran the runway during a rejected takeoff at Laurence G. Hanscom Field in Bedford, Massachusetts, resulting in a post-crash fire that killed all seven people on board. The National Transportation Safety Board (NTSB) determined that the probable cause was the flight crew's failure to disengage the gust lock system during engine start and their delayed decision to reject the takeoff after reaching rotation speed, compounded by the system's design not adequately limiting throttle advance to prevent high-speed acceleration with controls locked. Post-accident examination revealed the gust lock handle in the "on" position and the lock pin engaged, despite the crew's routine of skipping the flight control check on 98 percent of their previous 175 takeoffs together.^[26] Earlier incidents highlighted similar risks in general aviation aircraft. In May 2000, a Beechcraft Baron 58 crashed shortly after takeoff when the pilot failed to remove the installed gust lock, leading to loss of control; this was one of several such accidents involving Beech models that prompted Raytheon (now Textron Aviation) to issue Service Bulletin SB-27-3205 in November 1998, recommending replacement of gust locks with improved designs that provide clearer visual and tactile warnings to prevent inadvertent engagement during flight.^[27] Another fatal Beech-related case in the early 2000s involved three fatalities when the gust lock remained secured, contributing to a series of events that underscored vulnerabilities in older mechanical systems. More recent general aviation examples include an August 2013 Aeronca 7AC crash during takeoff at Taunton, Massachusetts, where a rudder gust lock was overlooked, killing both occupants, and a May 2015 Cessna 172M incident in Georgia where an improvised bolt as a control lock caused the aircraft to strike trees.^[28]^[21] These accidents often stemmed from human factors, such as omissions in preflight checklists due to haste, fatigue, or habitual deviations from standard operating procedures (SOPs), as well as design limitations in legacy systems that allowed partial engagement or insufficient feedback, like gust locks that could bind under aerodynamic loads or fail to restrict throttle movement effectively. In the Gulfstream case, the interlock mechanism permitted nearly full throttle advance despite the engaged lock, enabling the aircraft to accelerate beyond safe abort speeds. Improvised or non-standard locks in smaller aircraft exacerbated risks by lacking standardized removal cues.^[26]^[21] Key lessons from these events have driven safety enhancements, including the NTSB's 2015 Safety Alert SA-048, which urged pilots to strictly adhere to checklists, perform tactile flight control checks before takeoff, and abort immediately upon detecting anomalies, emphasizing that deviations normalize unsafe practices over time. In response to the Gulfstream accident, the Federal Aviation Administration (FAA) issued Airworthiness Directive (AD) 2017-13-11 in June 2017, mandating modifications to the G-IV gust lock system, including retrofit of the throttle interlock and incorporation of functional tests into maintenance programs to ensure reliable disengagement.^[29] For Beech aircraft, while no mandatory AD followed the 1998 incidents, updated service bulletins like SB-27-3459 (revised 2007) reinforced inspections and replacements, alongside broader industry calls for enhanced pilot training on SOPs and verification procedures to mitigate human error. These reforms have reduced recurrence by promoting redundant checks and improved hardware reliability.^[21]^[28]

References

[1]
14 CFR § 25.679 - Control system gust locks. - Law.Cornell.Edu
Gust locks must prevent damage from gusts on ground/water, disengage normally or limit operation with warning at takeoff, and prevent inadvertent engagement in ...
[2]
Learjet Gust Locks Prevent Unnecessary Surface Damage
Gust locks lock the control column in place, preventing random movement and possible damage to the surface from wind while an aircraft is parked.
[3]
[PDF] Gust Lock System - Accident Data
The gust lock system manually protects flight controls from wind gusts up to 60 knots using a handle and mechanical latches. Hydraulic pressure must be ...<|control11|><|separator|>
[4]
[PDF] AIRWORTHINESS DIRECTIVE - Civil Aviation Authority
Aug 3, 2021 · The gust-lock system is designed to lock and prevent damage to the control surfaces when the aircraft is parked during gusting wind conditions.
[5]
[PDF] AC 25-21 - Advisory Circular - Federal Aviation Administration
Sep 1, 1999 · conditions and to prevent the gust lock system from interfering with the normal operation of the airplane. c. Background. This rule was ...
[6]
Aircraft control surface gust lock - US8641106B2 - Google Patents
Jan 28, 2010 · A gust lock is used to keep the control surfaces and linkages from damage due to wind. Many gust locks on commercial aircraft are internal to ...Missing: function | Show results with:function
[7]
[PDF] AC 20-106 - Aircraft Inspection for the General Aviation Aircraft Owner
Block ·type gust lock. ing must clear the holes through the structure, satisfactory installation. Examine for cor and must be secured to prevent distortion ...
[8]
https://www.faa.gov/documentLibrary/media/Advisory_Circular/AC_20-106.pdf
[9]
One thing at a time: a brief history of the checklist
Nov 12, 2018 · Whether it was Major Ployer 'Pete' Hill or co-pilot Donald L. Putt who failed to disengage the Boeing Model 299's gust locks is not clear. One ...
[10]
Boeing 707 Turbojet Airliner - HistoryLink.org
Jul 3, 2002 · The 707, based on the prototype Dash-80 (1954), was the first truly successful jet airliner in service that was built in large numbers.Missing: gust | Show results with:gust
[11]
[PDF] FAA Historical Chronology, 1926-1996
Promulgated under provisions of the Air Commerce Act of 1926, these regulations resulted from many conferences between the Aeronautics Branch and pilots, ...
[12]
airworthiness directives final rules: 77-19-07
77-19-07 BEECH: Amendment 39-3042. Applies to all Beech 18 series airplanes, including all military counterparts thereof and those Beech 18 series airplanes ...<|separator|>
[13]
[PDF] Computers Take Flight - NASA Technical Reports Server (NTRS)
1960s, all of these had evolved enough to be useful in a fly-by-wire airplane. ... The design objectives included aircraft-maneuver load control and gust-load.
[14]
Flight Control Locks | SKYbrary Aviation Safety
A Flight Control Lock (sometimes referred to as a Gust Lock) is a means by which control surfaces on an aircraft not in flight can be prevented from random ...
[15]
Flight Control System — G450/G550/G500/G600/G650/G700 User's ...
Feb 5, 2021 · The flight controls gust lock secures the aircraft moveable surfaces ... Each gust lock consists of a mechanical latch, springs and a bungee rod.
[16]
Aircraft Control Surface Gust Lock - Google Patents
The basic elements of the gust lock 10 include a top plate 12, a bottom plate 14, and a strap 16. The use of “top” and “bottom” is not meant to limit the usage ...
[17]
[PDF] POH-Cessna-172S.pdf
Rudder Gust Lock (if installed) -- REMOVE. 2. Tail Tie-Down -- DISCONNECT. 3. Control Surfaces -- CHECK freedom of movement and security. 4. Trim Tab ...
[18]
Flight Control Protection from Damage by Strong Winds - SKYbrary
Aircraft use gust damping, control locks, and mechanical locks to protect flight controls from strong winds. Aircraft are certified to withstand 65 knots wind. ...
[19]
[PDF] Airplane Flying Handbook (FAA-H-8083-3C) - Chapter 2
The preflight assessment ensures that any aircraft flown meets regulatory airworthiness standards and is in a safe mechanical condition prior to flight. Per ...
[20]
[PDF] Flight Control Locks: Overlooking the Obvious - NTSB
Accidents have occurred after pilots omitted seemingly obvious procedures, such as removing flight control locks and performing flight control checks before ...
[21]
None
### Summary of Wind-Induced Threats to Parked Aircraft from AC 25.415-1
[22]
Easy Access Rules for Large Aeroplanes (CS-25) - EASA
Jan 30, 2023 · The ground gust requirements take into account the conditions of the aeroplane parked with controls locked, and taxying with controls either ...
[23]
[PDF] Secure Your Aircraft - SKYbrary
Generally, in winds above 30 knots, it is safer to park the aircraft into wind and dig around the mainwheels. This will lower the aircraft and reduce the angle ...
[24]
[PDF] Chapter 6: Preflight & Ground Operations
When securing the glider for an extended period, gust locks on the control surfaces prevent them from banging against their stops. Pitot tube and total ...
[25]
Reducing the Cost of Flying - AOPA
The chance of damage to the aircraft from wind or storms is minimized. Aircraft insurance companies might offer a lower rate. Keeping the aircraft in a ...
[26]
[PDF] Accident Report - NTSB/AAR-15/03 PB2015-105492
Sep 14, 2015 · The airplane's mechanical gust lock system is used to lock the primary flight control surfaces (elevators, ailerons, and rudder) while the ...
[27]
[PDF] Raytheon (Beech) Propeller Airplanes except for Model 17 ... - AOPA
Aug 13, 2001 · An installed gust lock is also suspected in another accident, which resulted in 3 fatalities. Reportedly, a large number of these accidents, ...Missing: function | Show results with:function
[28]
[PDF] sb-27-3459---flight-controls---flight-control ... - SERVICE BULLETIN
control gust lock prior to attempted takeoff. A review of the records from ... An Airworthiness Directive has been requested on the matter covered by this Service ...