### Q1: While flying slowly near stall with the left wing dropping, how can a full stall be avoided? ^t70q1 - A) Use rudder to the left, push the stick forward slightly, accelerate, then neutralise all controls - B) Lower the nose with elevator, maintain wings level using coordinated rudder and aileron - C) Deflect aileron to the right, push slightly forward on the stick, build speed, then neutralise controls - D) Apply aileron and rudder to the right, gain speed, push the stick forward slightly, then neutralise **Correct: B)** > **Explanation:** The correct stall recovery technique is to immediately reduce the angle of attack by lowering the nose with the elevator, while using coordinated rudder and aileron to keep the wings level. Option A applies rudder in the wrong direction (toward the dropping wing). Option C uses aileron alone without coordinated rudder, which near the stall can increase adverse yaw and potentially trigger a spin entry. Option D also prioritizes aileron over elevator, missing the critical first step of reducing the angle of attack. ### Q2: How is "flight time" defined? ^t70q2 - A) The total time from the first take-off until the last landing across one or more consecutive flights. - B) The time from engine start for take-off purposes until the pilot leaves the aircraft after engine shutdown. - C) The total time from the aircraft's first movement until it finally comes to rest after the flight. - D) The interval from the beginning of the take-off run to the final touchdown on landing. **Correct: C)** > **Explanation:** Under EASA regulations for gliders, flight time is defined as the total time from the aircraft's first movement for the purpose of flight until it finally comes to rest at the end of the flight. This includes ground handling and taxiing, not just airborne time. Option A only counts from takeoff to landing, excluding ground movement. Option B applies to powered aircraft with engines, not gliders. Option D is too narrow, covering only the takeoff run to touchdown and missing ground handling phases. ### Q3: What is a wind shear? ^t70q3 - A) A meteorological downslope wind event typical in alpine regions. - B) A gradual increase of wind speed at altitudes above 13000 ft. - C) A change in wind speed exceeding 15 kt. - D) A vertical or horizontal variation in wind speed and/or direction. **Correct: D)** > **Explanation:** Wind shear is defined as any change in wind speed and/or direction over a relatively short distance, which can occur in both the vertical and horizontal planes. It is not limited to any particular speed threshold (option C), altitude range (option B), or geographic setting (option A). Wind shear is particularly dangerous during takeoff and landing when the aircraft is close to the ground with limited recovery margins. ### Q4: Which weather phenomenon is most commonly linked to wind shear? ^t70q4 - A) Stable high-pressure systems. - B) Thunderstorms. - C) Fog. - D) Invernal warm fronts. **Correct: B)** > **Explanation:** Thunderstorms generate the most severe wind shear through their powerful updrafts, downdrafts, and microburst outflows, which can cause sudden wind reversals exceeding 50 knots within seconds. Stable high-pressure systems (option A) typically produce calm, uniform conditions. Fog (option C) is associated with light winds, not shear. Warm fronts (option D) can produce mild shear, but thunderstorms are by far the most common and dangerous source. ### Q5: Under what conditions should wind shear be expected? ^t70q5 - A) On a calm summer day with light winds - B) In cold weather with calm winds - C) During an inversion - D) When crossing a warm front **Correct: C)** > **Explanation:** A temperature inversion creates a stable boundary layer between two air masses that can move at different speeds and directions, producing wind shear at the inversion level. Inversions are common in the early morning and can significantly affect glider operations near the ground, particularly during approach and landing. Option A describes conditions with minimal shear risk. Option B and D can occasionally produce shear but are not the primary conditions associated with it. ### Q6: During approach, an aircraft encounters wind shear with decreasing headwind. Without pilot corrections, what happens to the flight path and indicated airspeed (IAS)? ^t70q6 - A) Flight path goes higher, IAS rises - B) Flight path goes lower, IAS rises - C) Flight path goes higher, IAS drops - D) Flight path goes lower, IAS drops **Correct: D)** > **Explanation:** When headwind suddenly decreases, the airflow over the wings drops, causing IAS to decrease and lift to reduce. With less lift, the aircraft sinks below the intended glide path. The aircraft's inertia maintains its groundspeed briefly, but the reduced relative airflow means less aerodynamic force. This is the most dangerous wind shear scenario on approach because both effects — lower path and lower airspeed — combine to reduce safety margins simultaneously. ### Q7: During approach, an aircraft encounters wind shear with increasing headwind. Without corrections, how are the flight path and IAS affected? ^t70q7 - A) Flight path drops, IAS drops - B) Flight path rises, IAS drops - C) Flight path drops, IAS rises - D) Flight path rises, IAS rises **Correct: D)** > **Explanation:** An increasing headwind temporarily increases the relative airflow over the wings, raising both IAS and lift. The additional lift pushes the aircraft above the intended glide path. Although initially this appears favorable, the pilot must be alert — if the headwind later decreases, the aircraft will experience the opposite effect and may sink rapidly below the desired path. Options involving decreased IAS or a lower flight path contradict the aerodynamic response to an increasing headwind. ### Q8: During approach, the aircraft experiences wind shear with a decreasing tailwind. Without corrections, what happens to the flight path and IAS? ^t70q8 - A) Flight path drops, IAS rises - B) Flight path rises, IAS rises - C) Flight path drops, IAS drops - D) Flight path rises, IAS drops **Correct: B)** > **Explanation:** When a tailwind decreases, the aircraft's forward momentum is maintained while the air mass effectively decelerates around it, increasing the relative airflow over the wings. This raises IAS and lift, pushing the aircraft above the glide path. A decreasing tailwind has the same aerodynamic effect as an increasing headwind. Options with decreased IAS or lower flight path misinterpret the relationship between tailwind changes and relative airflow. ### Q9: What is the best way to avoid encountering wind shear during flight? ^t70q9 - A) Avoid thermally active areas, especially in summer, or remain below them - B) Refrain from taking off and landing when heavy showers or thunderstorms are passing - C) Avoid precipitation areas, particularly in winter, and choose low flight altitudes - D) Avoid take-offs and landings in mountainous terrain and stay over flat terrain **Correct: B)** > **Explanation:** The most severe wind shear is associated with thunderstorms and heavy showers, which produce microbursts and gust fronts. Avoiding takeoffs and landings when such weather is passing through eliminates the most dangerous wind shear exposure during the most vulnerable flight phases. Option A addresses thermals, which cause turbulence but not dangerous shear. Option C targets winter precipitation, which is a lesser shear risk. Option D is overly restrictive and does not address the primary cause. ### Q10: During a cross-country flight, visual conditions begin to fall below minima. To maintain minimum visual conditions, the pilot decides to... ^t70q10 - A) Press on using radio navigation aids along the route - B) Continue based on sufficiently favourable forecasts - C) Request navigational assistance from ATC to continue - D) Turn back, since adequate VMC was confirmed along the previous track **Correct: D)** > **Explanation:** When VFR conditions deteriorate below minima, the safest action is to turn back to the area where adequate visual meteorological conditions (VMC) were confirmed. Continuing into worsening visibility is the leading cause of VFR-into-IMC accidents. Option A is inappropriate because gliders typically lack radio navigation equipment and VFR pilots should not rely on instrument navigation. Option B relies on forecasts rather than actual conditions, which is unsafe. Option C is not appropriate for gliders operating under VFR rules. ### Q11: Two identical aircraft at the same gross weight and configuration fly at different airspeeds. Which one produces stronger wake turbulence? ^t70q11 - A) The one at higher altitude - B) The one flying faster - C) The one flying slower - D) The one at lower altitude **Correct: C)** > **Explanation:** Wake turbulence intensity is directly related to the strength of wingtip vortices, which are strongest when the wing operates at high lift coefficients — that is, at low speeds and high angles of attack. The slower aircraft generates more intense vortices because it must produce the same lift at a lower speed, requiring a higher angle of attack and greater circulation around the wing. Altitude (options A and D) is not the determining factor. The faster aircraft (option B) produces weaker vortices at its lower lift coefficient. ### Q12: With only a light crosswind, what hazard exists when departing after a heavy aeroplane? ^t70q12 - A) Wake vortices are amplified and become distorted. - B) Wake vortices spin faster and climb higher. - C) Wake vortices remain on or near the runway. - D) Wake vortices twist across the runway transversely. **Correct: C)** > **Explanation:** In light crosswind conditions, wake vortices from a heavy aircraft tend to remain on or near the runway rather than being blown clear. With a strong crosswind, the vortices drift away from the runway centerline, but a light crosswind is insufficient to displace them, creating a lingering hazard for departing aircraft. Option A incorrectly states vortices are amplified. Option B is wrong because vortices sink, not climb. Option D is incorrect because light crosswinds do not cause significant lateral twisting of vortices across the runway. ### Q13: Which surface is most suitable for an emergency off-field landing? ^t70q13 - A) A ploughed field - B) A harvested cornfield - C) A glade with long dry grass - D) A village sports ground **Correct: B)** > **Explanation:** A harvested cornfield offers a firm, relatively flat surface with short stubble that provides good ground friction without excessive deceleration forces — ideal for an emergency landing. Option A (ploughed field) has soft, uneven furrows that can cause the glider to nose over or ground-loop. Option C (long dry grass) may conceal obstacles such as rocks, ditches, or fences. Option D (sports ground) is typically surrounded by buildings, fences, and spectators, creating collision hazards. ### Q14: What defines a precautionary landing? ^t70q14 - A) A landing performed without engine power. - B) A landing made to preserve flight safety before conditions deteriorate further. - C) A landing carried out with flaps retracted. - D) A landing forced by circumstances requiring the aircraft to land immediately. **Correct: B)** > **Explanation:** A precautionary landing is a proactive decision to land while options remain available, made to preserve flight safety before the situation worsens. It differs from a forced landing (option D), which is an immediate necessity with no alternative. Option A describes a normal glider landing or engine-out scenario, not specifically a precautionary landing. Option C describes a configuration choice, not a type of landing. The key distinction is that a precautionary landing involves foresight and planning. ### Q15: Which of these landing areas is best suited for an off-field landing? ^t70q15 - A) A lake with a smooth, undisturbed surface - B) A meadow free of livestock - C) A light brown field with short crops - D) A field with ripe, waving crops **Correct: C)** > **Explanation:** A light brown field with short crops indicates a harvested or nearly harvested surface that is firm and free of tall obstructions, making it suitable for a safe off-field landing. Option A (a lake) should only be considered as a last resort since water landings carry drowning risk. Option B (meadow without livestock) sounds safe but may have hidden obstacles; and option D (ripe, waving crops) indicates tall vegetation that could obscure hazards and cause the glider to nose over on landing. ### Q16: How does wet grass affect take-off and landing distances? ^t70q16 - A) Both take-off and landing distances decrease - B) Take-off distance increases while landing distance decreases - C) Take-off distance decreases while landing distance increases - D) Both take-off and landing distances increase **Correct: D)** > **Explanation:** Wet grass increases rolling resistance during the takeoff ground roll, requiring a longer distance to reach flying speed. On landing, wet grass reduces wheel braking friction (similar to aquaplaning), resulting in a longer stopping distance. Both phases are adversely affected. Option A reverses both effects. Option B correctly identifies the takeoff increase but incorrectly predicts a shorter landing roll. Option C reverses both effects entirely. ### Q17: What adverse effects can be expected when thermalling above industrial facilities? ^t70q17 - A) Extensive, strong downwind areas on the lee side of the plant - B) Very poor visibility of only a few hundred metres with heavy precipitation - C) Health hazards from pollutants, reduced visibility, and turbulence - D) Strong electrostatic charging and degraded radio communication **Correct: C)** > **Explanation:** Thermalling above industrial facilities exposes the pilot to harmful pollutants (smoke, chemical emissions), significantly reduced visibility from haze and particulates, and turbulence from the uneven heating of industrial structures. Option A describes a lee-side downdraft but not the full hazard picture. Option B exaggerates with "heavy precipitation," which is not caused by industrial plants. Option D describes electrostatic effects that are not typically associated with industrial thermal flying. ### Q18: When is an off-field landing most likely to result in an accident? ^t70q18 - A) When the approach uses distinct approach segments - B) When the decision to land off-field is taken too late - C) When the approach is made onto a harvested corn field - D) When the decision is made above the minimum safe altitude **Correct: B)** > **Explanation:** The most common cause of off-field landing accidents is delaying the decision too long, leaving insufficient altitude for proper field selection, a stabilized approach, and obstacle avoidance. Late decisions force rushed approaches, poor field choices, and inadequate speed management. Option A (distinct segments) is standard good practice. Option C (harvested cornfield) is actually a good surface choice. Option D (deciding above minimum safe altitude) is the correct time to decide, not a risk factor. ### Q19: How can mid-air collisions be avoided when circling in thermals? ^t70q19 - A) Enter the updraft quickly and pull back sharply to slow down - B) Circle in alternating directions at different altitudes - C) Mimic the movements of the glider ahead - D) Coordinate turns with other aircraft sharing the same thermal **Correct: D)** > **Explanation:** When sharing a thermal, all gliders should circle in the same direction and coordinate their turns to maintain consistent spacing and predictable flight paths. This minimizes the risk of convergence. Option A (entering quickly and pulling back sharply) can surprise other pilots and create a collision hazard. Option B (alternating directions) creates head-on crossing situations within the thermal. Option C (mimicking the glider ahead) could lead to following too closely without maintaining safe separation. ### Q20: How can danger be avoided when a glider's altitude nears circuit height during a cross-country flight? ^t70q20 - A) Seek thermals on the lee side of a chosen landing field - B) Regardless of the planned route, commit to an off-field landing - C) Maintain radio contact until fully stopped after an off-field landing - D) Aim for cumulus clouds visible on the distant horizon and use their thermals **Correct: B)** > **Explanation:** When altitude drops to circuit height, the pilot must commit to landing — continuing to search for lift at this altitude is dangerous and leaves no margin for error. Option A is hazardous because lee-side air typically contains sink, not thermals. Option C describes a good post-landing practice but does not address the immediate danger of low altitude. Option D risks flying into sink between thermals with no altitude reserve, potentially resulting in a crash rather than a controlled off-field landing. ### Q21: What must a pilot consider before entering a steep turn? ^t70q21 - A) Reduce speed in accordance with the target bank angle before starting the turn - B) Once the bank angle is achieved, push forward to increase speed - C) After reaching the bank angle, apply opposite rudder to reduce yaw - D) Build up sufficient speed for the intended bank angle before initiating the turn **Correct: D)** > **Explanation:** In a steep turn, the load factor increases (n = 1/cos(bank angle)), which raises the stall speed. The pilot must have adequate speed before entering the turn to maintain a safe margin above the increased stall speed. Option A (reducing speed before a steep turn) would dangerously bring the aircraft closer to stall. Option B (pushing forward during the turn) would cause altitude loss and nose-down pitch. Option C (opposite rudder) is not the primary concern — speed margin is the critical safety factor. ### Q22: A glider is about to stall and pitch down. Which control input prevents a nose-dive and spin? ^t70q22 - A) Hold ailerons neutral, apply strong rudder toward the lower wing - B) Maintain level flight using the rudder pedals - C) Pull the stick back slightly, deflect ailerons opposite to the lower wing - D) Release back pressure on the elevator, apply rudder opposite to the dropping wing **Correct: D)** > **Explanation:** The correct response to an incipient stall with wing drop is to release back pressure on the elevator (reducing angle of attack) and apply opposite rudder to prevent the yaw that would develop into a spin. Option A applies rudder toward the dropping wing, which would accelerate spin entry. Option B attempts to maintain level flight with rudder alone, which is ineffective near the stall. Option C pulls back on the elevator, which deepens the stall, and uses ailerons which can worsen the situation near the critical angle of attack. ### Q23: When aerotowing with a side-mounted release hook, the glider tends to... ^t70q23 - A) Display an increased pitch-up moment. - B) Exhibit particularly stable flight characteristics. - C) Turn rapidly about its longitudinal axis. - D) Yaw toward the side where the hook is mounted. **Correct: A)** > **Explanation:** A side-mounted (belly or CG) release hook creates a tow force that acts below and possibly offset from the aircraft's center of gravity. The cable pull from below the CG generates a nose-up pitching moment, which the pilot must actively counter with forward stick pressure. Option B is incorrect — side-mounted hooks do not improve stability. Option C (rapid roll) is not characteristic of this configuration. Option D describes yaw, which would occur with an asymmetric attachment but is not the primary effect. ### Q24: During aerotow, the glider has climbed excessively high behind the tug. What should the glider pilot do to prevent further danger? ^t70q24 - A) Initiate a sideslip to lose the excess height - B) Push firmly forward to bring the glider back to the normal position - C) Pull strongly, then release the cable - D) Gently extend the spoilers and steer the glider back to the correct tow position **Correct: D)** > **Explanation:** The safest correction for being too high behind the tug is to gently deploy spoilers to increase drag and lose excess height while steering back to the correct tow position. Option A (sideslip) would create erratic lateral movements that could endanger both aircraft. Option B (pushing firmly forward) could put the tug into a dangerous nose-down attitude by pulling its tail up via the cable. Option C (pulling then releasing) is dangerous — pulling when high compounds the problem, potentially lifting the tug's tail catastrophically. ### Q25: After a cable break during winch launch, what is the correct sequence of actions? ^t70q25 - A) Hold the stick back, stabilise at minimum speed, and land on the remaining field length - B) Push the nose down firmly, release the cable, then decide based on altitude and terrain whether to land ahead or fly a short circuit - C) Perform a 180-degree turn and land in the opposite direction, releasing the cable before touchdown - D) Release the cable first, then push the nose down; below 150 m AGL land straight ahead at increased speed **Correct: B)** > **Explanation:** After a cable break during winch launch, the immediate priority is to lower the nose to maintain flying speed (preventing a stall from the steep climb attitude), then release the cable to prevent it from snagging during landing. After establishing safe flight, the pilot decides whether to land straight ahead or fly a modified circuit based on available altitude and terrain. Option A (holding the stick back) risks a stall. Option C (180° turn) is extremely dangerous at low altitude. Option D gets the sequence backward — nose down first, then release. ### Q26: During the initial ground roll of a winch launch, one wing touches the ground. What must the glider pilot do? ^t70q26 - A) Deflect ailerons in the opposite direction - B) Apply opposite rudder - C) Release the cable immediately - D) Pull back on the elevator **Correct: C)** > **Explanation:** If a wing touches the ground during the winch launch ground roll, the situation is uncontrollable and the launch must be immediately aborted by releasing the cable. Continuing the launch with a wing on the ground risks a violent ground loop or cartwheel. Option A (opposite aileron) may be insufficient at low speed and could worsen the situation under cable tension. Option B (opposite rudder) cannot correct a wing-down condition. Option D (pulling back) would try to lift off prematurely in an uncontrolled state. ### Q27: During aerotow, the glider exceeds its maximum permissible speed. What should the glider pilot do? ^t70q27 - A) Pull back on the elevator to reduce speed - B) Notify the airfield controller by radio - C) Release the towrope immediately - D) Deploy the spoilers **Correct: C)** > **Explanation:** If the glider exceeds VNE (never-exceed speed) during aerotow, the pilot must immediately release the towrope to remove the pulling force causing the excessive speed and avoid structural failure. Option A (pulling back) increases the load factor on an already over-stressed airframe. Option B (radio call) wastes critical time during a structural emergency. Option D (deploying spoilers) while still attached to the tow aircraft could cause dangerous pitch and speed oscillations. ### Q28: After a cable break during aerotow, a long section of cable remains attached to the glider. What should the pilot do? ^t70q28 - A) Fly a low approach and ask the airfield controller to assess the cable length, then release if needed - B) Once at a safe height, drop the cable over empty terrain or over the airfield - C) Fly a normal approach and release the cable immediately after touchdown - D) Release immediately and continue the flight with the coupling unlatched **Correct: B)** > **Explanation:** A trailing cable is a serious hazard — it can snag on obstacles, trees, or power lines during approach and landing. The safest action is to climb to a safe height and release the cable over empty terrain or the airfield where it can be recovered safely. Option A (low approach for assessment) risks snagging the trailing cable on obstacles. Option C (releasing after touchdown) means flying the entire approach with a dangerous trailing cable. Option D (releasing immediately regardless) may drop the cable in an unsafe location. ### Q29: During aerotow, the tug aircraft disappears from the glider pilot's view. What should the pilot do? ^t70q29 - A) Deploy the spoilers and return to a normal attitude - B) Alternate between pushing and pulling on the elevator - C) Release the cable immediately - D) Alternate turns left and right to search for the tug **Correct: C)** > **Explanation:** If the glider pilot loses sight of the tug during aerotow, the cable must be released immediately. Continued towing without visual contact with the tug is extremely dangerous because the glider pilot cannot anticipate the tug's movements, risking a mid-air collision or being pulled into an unexpected attitude. Option A (spoilers) does not address the fundamental problem. Option B (alternating elevator) creates dangerous oscillations. Option D (searching turns) could tangle the cable or fly into the tug's path. ### Q30: During aerotow in a turn, the glider drifts to an outward offset position. How should the glider pilot correct this? ^t70q30 - A) Use a sideslip so that increased drag pushes the glider back behind the tug - B) Steer back using coordinated rudder and aileron inputs, then deploy spoilers to reduce speed - C) Return behind the tug by using a tighter radius with strong rudder pedal inputs - D) Match the tug's bank angle and use rudder to gently reduce the radius back to the correct position **Correct: D)** > **Explanation:** The correct technique is to match the tug's bank angle to maintain the same turn radius, then use gentle rudder input to slightly tighten the radius and drift back behind the tug. This is a smooth, controlled correction. Option A (sideslip) creates lateral instability and unpredictable cable tensions. Option B (deploying spoilers) would cause the glider to drop below the tug's level. Option C (strong rudder) risks over-correction and could cause the glider to swing to the opposite side or create dangerous cable loads. ### Q31: During a winch launch, cable tension suddenly disappears just after reaching the full climb attitude. What should the pilot do? ^t70q31 - A) Inform the winch driver by alternating aileron inputs - B) Pull on the elevator to restore cable tension - C) Push firmly forward and release the cable immediately - D) Push slightly and wait for the cable tension to return **Correct: C)** > **Explanation:** Loss of cable tension during the steep climbing phase means a cable break or winch failure has occurred. The pilot must immediately push forward to lower the nose and prevent a stall (since the glider is at a high pitch angle with rapidly decaying speed), then release the cable. Option A wastes critical time on communication. Option B (pulling) would increase the pitch angle further, guaranteeing a stall. Option D (waiting) is dangerous because speed is decaying rapidly in the climb attitude. ### Q32: Before launching with a parallel-cable winch, the pilot notices the second cable lying close to the glider. What should be done? ^t70q32 - A) Keep watching the second cable and release after take-off if needed - B) Release the cable immediately and inform the airfield controller by radio - C) Continue with the normal take-off and inform the controller after landing - D) Proceed with the launch using opposite rudder to steer away from the second cable **Correct: B)** > **Explanation:** A second cable lying close to the glider poses a serious entanglement hazard during the ground roll and climb-out. The launch must be aborted immediately by releasing the cable, and the airfield controller must be notified to correct the situation before any further launches. Option A risks snagging the loose cable during takeoff. Option C ignores a clear safety hazard. Option D cannot prevent entanglement with a cable on the ground during the critical ground roll phase. ### Q33: What is the function of the weak link (breaking point) on a winch cable? ^t70q33 - A) It limits the rate of climb during the winch launch - B) It prevents the glider airframe from being overstressed - C) It provides automatic cable release after the winch launch - D) It protects the winch from being overrun by the glider **Correct: B)** > **Explanation:** The weak link is calibrated to break before the cable tension exceeds the glider's structural limits, protecting the airframe from being overstressed by excessive winch pull. Its breaking strength is matched to the maximum permitted towing load for the specific glider type. Option A is incorrect — the rate of climb depends on winch power and speed, not the weak link. Option C is wrong because the weak link is a safety device, not a release mechanism. Option D describes a concern unrelated to the weak link's purpose. ### Q34: During the final phase of a winch launch, the pilot keeps pulling back on the elevator. The automatic release trips under high wing loading. What are the consequences? ^t70q34 - A) Only this sudden jerk ensures the cable releases properly - B) This technique compensates for insufficient wind correction - C) Extreme structural stress is placed on the glider airframe - D) A higher launch altitude can be achieved using this technique **Correct: C)** > **Explanation:** Continuing to pull back during the final phase of a winch launch places extreme structural stress on the airframe because the combination of cable tension, aerodynamic loads, and the centripetal force from the curved flight path can exceed design limits. The automatic release tripping is a safety mechanism activating because the load factor is dangerously high. Option A mischaracterizes a dangerous overload as normal procedure. Option B has nothing to do with wind correction. Option D prioritizes altitude gain over structural safety. ### Q35: An off-field landing in mountainous terrain is necessary and the only available site is steeply inclined. How should the approach be flown? ^t70q35 - A) Fly the approach at minimum speed with a careful flare upon reaching the landing site - B) Approach with extra speed, then make a quick flare to match the slope gradient - C) Approach parallel to the ridge with headwind, according to the prevailing wind - D) Approach down the ridge at increased speed, adjusting pitch to follow the ground **Correct: B)** > **Explanation:** Landing uphill on a steep slope requires extra approach speed to account for the rapid deceleration that occurs when the aircraft's momentum encounters the rising terrain. A quick, decisive flare matches the aircraft's flight path to the slope angle, minimizing impact forces. Option A (minimum speed) leaves no energy reserve for the flare on a steep slope. Option C (parallel to ridge) does not utilize the slope for deceleration. Option D (downhill) dramatically increases groundspeed and stopping distance, making it extremely dangerous. ### Q36: At 6000 m MSL, the pilot realises that the oxygen supply will run out within minutes. What should be done? ^t70q36 - A) After oxygen runs out, remain at this altitude for no more than 30 minutes - B) Reduce oxygen consumption by breathing slowly - C) Deploy spoilers and descend at the maximum permissible speed - D) At the first sign of hypoxia, begin descending at the maximum allowed speed **Correct: C)** > **Explanation:** At 6000 m without supplemental oxygen, the time of useful consciousness is very short — hypoxia can impair judgment within minutes. The pilot must descend immediately at maximum permissible speed using spoilers, before oxygen runs out, rather than waiting for symptoms to appear. Option A is extremely dangerous — remaining at 6000 m without oxygen for 30 minutes would cause incapacitation. Option B cannot meaningfully extend oxygen supply. Option D waits for hypoxia symptoms, by which point cognitive function may already be too impaired for safe decision-making. ### Q37: What colour is the emergency canopy release handle? ^t70q37 - A) Blue - B) Yellow - C) Red - D) Green **Correct: C)** > **Explanation:** Emergency canopy release handles are standardized as red to ensure immediate recognition in a crisis. Red is the universal color for emergency controls in aviation, including canopy jettison handles, fire extinguisher handles, and fuel shutoff valves. Options A (blue), B (yellow), and D (green) are incorrect — these colors are reserved for other functions such as trim (green), normal canopy latch, or non-emergency systems. ### Q38: Why must trim masses or lead ballast be firmly secured in a glider? ^t70q38 - A) To ensure the maximum allowed mass is not exceeded - B) To prevent them from jamming controls or causing a centre-of-gravity shift - C) To guarantee a comfortable seating position for the pilot - D) To protect the pilot from injury during turbulent thermal flight **Correct: B)** > **Explanation:** Unsecured trim masses or ballast can shift during flight, particularly in turbulence or during maneuvers, potentially jamming control linkages (elevator, rudder, or aileron cables) or causing an unplanned shift in the center of gravity that could make the aircraft uncontrollable. Option A addresses weight limits, which is a separate concern from securing ballast. Option C and D are secondary considerations — the primary danger is control jamming and CG displacement. ### Q39: During a winch launch, the airspeed indicator fails after reaching the full climb attitude. What should the pilot do? ^t70q39 - A) Push the stick forward, release the cable, and fly a short circuit at minimum speed - B) Continue the launch to normal altitude, then use the horizon and airstream noise for an immediate circuit and landing - C) Continue to normal altitude, then use visual and audio cues to proceed with the planned flight - D) Try to restore the ASI by making abrupt speed changes during the launch **Correct: B)** > **Explanation:** With a failed ASI, the pilot should continue the launch to normal release altitude (since the launch is already established and stable), then release and fly an immediate circuit using the horizon for pitch reference and wind noise for approximate speed estimation. An immediate landing minimizes exposure to the instrument failure. Option A (aborting the launch) is unnecessarily risky at climb attitude. Option C (continuing the planned flight) is unsafe without airspeed indication. Option D (abrupt speed changes) could overstress the airframe during the launch. ### Q40: Why is launching with the centre of gravity beyond the aft limit prohibited? ^t70q40 - A) Because the maximum permissible speed would be significantly reduced - B) Because the increased nose-down moment could not be compensated - C) Because structural limits might be exceeded - D) Because elevator authority may be insufficient to control the flight attitude **Correct: D)** > **Explanation:** When the CG is too far aft, the moment arm between the CG and the tail becomes too short, reducing the elevator's ability to generate sufficient nose-down pitching moment. This can make the aircraft uncontrollable, particularly during the launch phase when pitch control is critical. Option A is incorrect — aft CG does not directly reduce VNE. Option B is backward — an aft CG reduces the nose-down moment, but the problem is insufficient elevator authority to correct nose-up tendencies. Option C addresses structural limits, which is a separate concern. ### Q41: What effect does ice accumulation on the wings have? ^t70q41 - A) It reduces friction drag - B) It improves slow-flight performance - C) It lowers the stall speed - D) It raises the stall speed **Correct: D)** > **Explanation:** Ice accumulation on the wing disrupts the smooth airflow over the aerofoil surface, reducing the maximum lift coefficient (CL_max) and increasing drag. Since stall speed is inversely proportional to the square root of CL_max, a lower CL_max means a higher stall speed. The aircraft must fly faster to maintain safe flight. Option A is wrong because ice roughness increases friction drag. Options B and C are incorrect because ice degrades aerodynamic performance in every respect. ### Q42: The landing gear extends but will not lock despite several attempts. How should the landing be performed? ^t70q42 - A) Retract the gear and perform a belly landing at increased speed - B) Keep the gear extended but unlocked and land normally - C) Retract the gear and perform a belly landing at minimum speed - D) Hold the gear handle firmly during a normal landing **Correct: C)** > **Explanation:** If the gear will not lock, it must be retracted and a belly (gear-up) landing performed at minimum speed to minimize impact forces and structural damage. An unlocked gear (option B) could collapse asymmetrically on touchdown, causing a violent ground loop or cartwheel. Option A (belly landing at increased speed) unnecessarily increases impact energy. Option D (holding the handle) provides no mechanical lock and the gear could still collapse under landing loads. ### Q43: When flying into heavy snowfall, what is the greatest immediate danger? ^t70q43 - A) Rapid increase in airframe icing - B) Sudden blockage of the pitot-static system - C) Sudden loss of visibility - D) Sudden increase in aircraft mass **Correct: C)** > **Explanation:** The greatest immediate danger when encountering heavy snowfall is the sudden and complete loss of forward visibility, which can disorient the pilot and make terrain avoidance impossible within seconds. While icing (option A) and pitot blockage (option B) are real concerns, they develop more gradually. Option D (mass increase) is negligible in the short term. Loss of visibility is immediate, disorienting, and can lead to controlled flight into terrain. ### Q44: A tailwind off-field landing is unavoidable. How should it be executed? ^t70q44 - A) Approach at increased speed without using spoilers - B) Normal approach, then extend spoilers and push the nose down upon reaching the landing site - C) Approach at reduced speed, expecting shorter flare and ground roll - D) Approach at normal speed, expecting a longer flare and ground roll **Correct: D)** > **Explanation:** With a tailwind, the groundspeed is higher than normal for the same indicated airspeed, resulting in a longer flare and longer ground roll. The pilot should maintain normal approach speed (not reduced, which would risk stalling) and prepare for the extended landing distance. Option A (increased speed without spoilers) would make the landing even longer. Option B (pushing the nose down at the field) would cause a hard landing. Option C (reduced speed) risks stalling at the higher groundspeed, and the ground roll will be longer, not shorter. ### Q45: When landing with a tailwind, what must the pilot do? ^t70q45 - A) Retract the landing gear to shorten the ground roll - B) Increase the approach speed - C) Approach at normal speed with a shallow angle - D) Compensate for the tailwind by sideslipping **Correct: C)** > **Explanation:** With a tailwind, the pilot should maintain normal indicated approach speed (since the wing sees the same airflow regardless of wind) and fly a shallower approach angle to account for the increased groundspeed and reduced obstacle clearance gradient. Option A (retracting gear) would cause a belly landing, not shorten the roll. Option B (increasing speed) would extend the ground roll further. Option D (sideslipping) addresses crosswind, not tailwind, and would not be effective compensation. ### Q46: Tower reports: "Wind 15 knots, gusts 25 knots." How should the approach and landing be conducted? ^t70q46 - A) Approach at increased speed, but avoid using spoilers - B) Approach at normal speed, controlling speed with spoilers - C) Approach at minimum speed, making gentle control corrections - D) Approach at increased speed with firm control inputs to correct attitude changes **Correct: D)** > **Explanation:** In gusty conditions (10 kt gust factor), the pilot must add speed margin to the approach speed (typically half the gust factor, so about 5 kt extra) and make firm, positive control inputs to maintain attitude through the turbulent air. Option A avoids spoilers, which may be needed for path control. Option B uses normal speed with no gust margin, leaving the aircraft vulnerable to speed drops in gusts. Option C (minimum speed) is extremely dangerous in gusts — a momentary speed loss could cause a stall. ### Q47: A glider pilot encounters strong sink while ridge soaring. What is the recommended action? ^t70q47 - A) Increase speed and head away from the ridge - B) Continue flying, as mountain downdrafts are typically brief - C) Increase speed and move closer to the ridge - D) Increase speed and land parallel to the ridge **Correct: A)** > **Explanation:** In strong sink near a ridge, the pilot must increase speed (to improve penetration through the sink) and fly away from the ridge into the valley where conditions may be more benign and landing options exist. Option B is dangerously complacent — mountain downdrafts can be sustained and severe. Option C (moving closer to the ridge) could trap the pilot against the terrain in strong sink. Option D (landing parallel to the ridge) may not be feasible on mountainous terrain and reduces options. ### Q48: A glider flying beneath an expanding cumulus that is developing into a thunderstorm rapidly approaches cloud base. What should the pilot do? ^t70q48 - A) Slow to minimum speed and exit the thermal area in a gentle turn - B) Tighten harness and be prepared for severe gusts while continuing to thermal - C) Enter the thunderstorm cloud and continue using instruments - D) Deploy spoilers within speed limits and leave the thermal area at maximum permissible speed **Correct: D)** > **Explanation:** When a cumulus develops into a cumulonimbus, the updrafts intensify dramatically and can suck the glider into the cloud against the pilot's wishes. The pilot must deploy full spoilers and fly at maximum permissible speed (VNE or the spoiler-extended limit) to escape the rapidly increasing updraft. Option A (minimum speed) would maximize the time in the updraft and the risk of being drawn in. Option B (continuing to thermal) is extremely dangerous near a thunderstorm. Option C (entering the cloud) violates VFR rules and exposes the aircraft to severe turbulence, hail, and lightning. ### Q49: After landing, you discover that a pen may have fallen into the cockpit. What must be considered? ^t70q49 - A) Other pilots due to fly the glider should be informed about the missing pen - B) A flight without a writing instrument on board is not permitted - C) Small, light loose items in the fuselage can be regarded as uncritical - D) The cockpit must be thoroughly checked for loose objects before the next flight **Correct: D)** > **Explanation:** Any loose object in a cockpit — even something as small as a pen — can jam flight controls by lodging in the control linkages, pushrods, or cable runs. The cockpit must be thoroughly inspected before the next flight to locate and remove the object. Option A merely passes the problem along without solving it. Option B is irrelevant — the concern is not having a pen but having a loose object. Option C is dangerously wrong — even small objects can jam critical controls and have caused fatal accidents. ### Q50: Flying near the aerodrome at about 250 m AGL, you encounter strong sink and decide on a safety landing. At what speed should you fly toward the airfield? ^t70q50 - A) Maximum manoeuvring speed VA - B) Best glide speed - C) Minimum sink rate speed - D) Best glide speed plus allowances for downdrafts and wind **Correct: D)** > **Explanation:** When encountering strong sink near the aerodrome, the pilot needs maximum range to reach the field. Best glide speed gives maximum range in still air, but additional speed is needed to compensate for the downdraft (which steepens the glide path) and any headwind component. Option A (VA) may be too fast and waste altitude. Option B (best glide speed alone) does not account for the sink and wind. Option C (minimum sink speed) maximizes time aloft but minimizes distance covered, which is counterproductive when trying to reach the field.