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REMOTE OPERATIONS. OBJECTIVES List the factors and their effects on aircraft performance. List the factors evaluated during a high and low recon. Describe a typical remote site traffic pattern.
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REMOTE OPERATIONS • OBJECTIVES • List the factors and their effects on aircraft performance. • List the factors evaluated during a high and low recon. • Describe a typical remote site traffic pattern. • List the altitude and airspeed minimums for the high and low recons as well as turning approaches. • List the restrictions on descent rates on an approach. • List the different types of confined area takeoffs. • Explain the effects remote site size and pilot technique have on power required. • Explain why OGE hover requires more power than IGE hover.
WHY STUDY REMOTE OPS? • Remote flying is what helicopter operations is all about. You can land or hover almost anywhere. • Remote operations are daily occurrences in the helicopter world. • Knowledge of procedures can prevent accidents and accomplish the mission successfully.
OVERVIEW I. Aircraft Performance and Situational Awareness • Factors Affecting Aircraft Performance • Effects of Factors on Aircraft Performance • Apprehension • Pinnacle Approach • Hovering • Types of Wind • Command Responsibility
OVERVIEW II. Remote Operations Procedures • Pre-mission Preparation • Power Available/Power Required Checks • High Recons • Low Recons • Remote Area Patterns • Confined Area Approaches, Landings and Takeoffs
Aircraft Performance and Situational Awareness 1. Factors Affecting Aircraft Performance • Pressure Altitude (PA). As PA increases the amount of air available to support the aircraft (lift) decreases. • Temperature. The density of the air is affected by the temperature. As temp increases the air becomes less dense; the lift generated by the rotor system decreases. • Relative Humidity. Moist air is less dense than dry air, thus reducing the lift capability
Aircraft Performance and Situational Awareness 2. Effects of Factors on Aircraft Performance • Pitch Setting. As altitude increases, a higher pitch setting is required in the rotor system to produce the required lift. • Tail Rotor Control. More left pedal is required for all maneuvers to compensate for the higher collective setting. • Torque available. Torque available (power available) decreases with altitude, and the power required increases slightly. • 90 KIAS. For a given indicated airspeed, say 90 KIAS, the aircraft will possess more inertia at higher altitudes that it would at lower altitudes. • Translational Lift. Since the rotor system has to work harder to draw air from the front during forward flight, you tend to lose translational lift earlier in the approach. Similarly, you will achieve translational lift at a later stage on a go-around or takeoff.
Aircraft Performance and Situational Awareness 3. Apprehension • It is quite normal to be apprehensive while flying remote operations, especially in the mountains. The key to overcoming this apprehension is realistic training. There is no substitute for experience.
Aircraft Performance and Situational Awareness 4. Uneven Terrain / Pinnacle Approach • During an approach, you must be aware that uneven terrain surrounding the landing site gives poor visual cues as to the actual aircraft altitude and the rate of closure. • Up-sloping Terrain • Down-sloping Terrain
Aircraft Performance and Situational Awareness 5. Hovering • Hovering against steeply sloping terrain can cause vertigo. When this is suspected, the copilot can assist by calling "wing level." You should shift your hover reference away from the slope toward more level terrain.
Aircraft Performance and Situational Awareness 6. Types of Wind • Prevailing Winds. This is the general flow of upper-level winds. • Surface Winds. This is the layer of air that lies close to the ground. • Local Winds. Sometimes called valley or canyon winds, they are present everywhere in the mountains and are unrelated to prevailing winds.
Aircraft Performance and Situational Awareness 7. Command Responsibility • Although the safe operation of the aircraft is the ultimate responsibility of the aircraft commander, it is also the responsibility of each crew member. • Any time there is confusion as to what is happening during the operation or to the aircraft, question it and get it clarified. • If the aircraft or crew are not performing correctly call "go around."
Remote Operations Procedures • Pre-mission Preparation • Power Available/Power Required Checks • High Recons • Low Recons • Remote Area Patterns • Confined Area Approaches, Landings and Takeoffs
Remote Operations Procedures 1. Pre-Mission Preparation • Acquire the landing site conditions, if available (elevation, temp, obstacles). • Accurate wind information is more difficult to obtain and more variable than other planning data. • Each crew member must know and understand their responsibilities throughout the flight and while at the remote site.
Remote Operations Procedures 2. Power Available / Power Required • Confirm current PA and Temperature has not increased by 500’/5 degrees respectively • Perform Power Available check (OGE +3) • Determine the power required for ALL aspects of the remote operation (takeoff and landing).
Remote Operations Procedures 3. High Reconnaissance Pattern • Dictated by terrain, wind, obstacles, and emergency landing areas. • The remote site should remain within visual range throughout the recon so recon assessment can be efficiently completed. • Maintain minimum 50 KIAS and approximately 300 feet AGL during the high recon. • Dependent upon the size, shape and surrounding terrain, the recon pattern may be rectangular, racetrack (oval), or orbital.
Remote Operations Procedures Wide open area (200’x300’=HUGE)
Remote Operations Procedures Wide open area = Rectangular pattern
Remote Operations Procedures Confined Area (100’x150’=VERY SMALL LZ)
Remote Operations Procedures Confined Area = Circular/Orbital Pattern
Remote Operations Procedures 4. High Reconnaissance Items to Evaluate W--Wind direction E -- Elevation of the site (29.92 to find the PA / confirms TOLD) T -- Temperature of site (ambient temp also confirms TOLD) P -- Power Available / Power Required / margin A --Approach and departure routes S -- Size, shape, slope and suitability T -- Touchdown point E -- Escape route / go-no-go point
Go/No-Go Option? At what point could the aircraft have sufficient power to stop its descent and/or go-around?
Go/No-Go Option? At what point could the aircraft have sufficient power to stop its descent and/or go-around?
Go/No-Go Option? At what point could the aircraft have sufficient power to stop its descent and/or go-around?
Go/No-Go Option? At what point could the aircraft have sufficient power to stop its descent and/or go-around? A Once you pass the tree-line, you’ll most likely be committed for the approach. B
Remote Operations Procedures 5. Low Recon Pattern • Low Recon Approach. Initiated from 300 feet AGL. Use the same approach angle intended for the actual approach. Descend no lower than 50 feet AHO (along both approach and departure path) and decelerate no slower than 50 KIAS. • Evaluate. During the low recon, confirm the following high recon items: (1) Size, Slope, Suitability (2) Winds, to include turbulence (3) Entry, Exit, and Abort Routes (4) Elevation (5) Touchdown Point. • Re-Evaluate High Recon. If a discrepancy or change is noted on the low recon, re-evaluate the applicable high recon items.
Remote Operations Procedures 6. Confined Area Pattern. • After the low recon is completed, climb back to traffic pattern altitude (300 AGL) and complete the Before Landing checklist. • Ideally the pattern flown for the final approach should be no larger than the high recon pattern. • Use other crewmembers if needed to keep remote site in visual range.
Remote Operations Procedures 7. Confined Area Approach. • Ensure that sufficient power is available above computed requirements to safely complete the approach or hover. • Consider the weight of survivors or equipment to be picked up on computing power for a hover and/or takeoff.
Remote Operations Procedures 8. Approach Planning Factors. • Abort Route • Settling with Power • Power Required • Engine Lag • Wind Shifts. Rotor Droop • Null Areas
Remote Operations Procedures 9. Turning Approaches • These approaches may be used when terrain and obstacles will not allow a normal traffic pattern, or if you are completing successive approaches to a landing site. • Minimum entry altitudes is 300 feet AGL with a safe airspeed, not less than 50 KIAS. • By varying the rate of turn, airspeed and the descent rate, you can maneuver your aircraft to a point on final that allows for a normal approach to the touchdown area without aggravated flares or excessive control movements.
Remote Operations Procedures 10. Confined Area Landings • Hovering. It is recommended that you terminate confined area approaches at a hover. • Landing. Lower the helicopter gently to the ground. When the helicopter contacts the surface, maintain rotor RPM and slowly decrease the collective. • Slopes. Slopes are naturally inherent to remote operations. The biggest danger is the phenomena known as dynamic rollover.
Remote Operations Procedures 11. Confined Area Takeoff • TOLD • Maximum Performance Takeoff • Null Areas • Crosswind Takeoffs • Plan Ahead
Remote Operations Conclusion I. Aircraft Performance and Situational Awareness • Factors Affecting Aircraft Performance • Effects of Factors on Aircraft Performance • Apprehension • Pinnacle Approach • Hovering • Types of Wind • Command Responsibility
Remote Operations Conclusion II. Remote Operations Procedures • Pre-mission Preparation • Power Available/Power Required Checks • High Recons • Low Recons • Remote Area Patterns • Confined Area Approaches, Landings and Takeoffs
QUESTIONS? • Remote exam questions will be taken from: • This fine lecture • Remote CAI • AETCI 11-358 Attch 3 • Applicable SOP areas • Sorry, but due to copyright infringements, transcripts of this lecture and power point presentation are unavailable at this time.