********************************************************************** Pilot's Handling Notes for the Fiat G.12CR with Fiat A.74 RC42 engines ********************************************************************** The three 770hp Fiat A.74 RC42 engines drive constant speed airscrews. They have automated mixture controls and manually applied carb heat controls. Superchargers sustain that rated power up to 4200 metres. Each engine can deliver 820hp for up to two minutes for TOGA at sea level. Fiat engines cause swing to the left. The virtual flight engineer will operate the oil cooler shutters and select the appropriate supercharger gear ratio throughout the flight according to the engine RPM demanded, current altitude and weather. The engine cowl flaps are under pilot control in this simulation. AUTOMIXTURE - This engine has automixture in real life and in MSFS. The manifold pressure gauges of this aircraft are calibrated in Kg/Cm^2 abbreviated C. CARB HEAT - When C < 0.8 and OAT < +5C apply CARB HEAT for 30 seconds every few minutes to clear carb ice. Use of CARB HEAT CAUSES significant LOSS OF POWER. Maximum fuel load is 4,123lbs of 87 Octane AVGAS. This is loaded by default in FS9 to allow the longest routes flown in real life, but limits payload to four VIP passengers plus bags. Pre war and wartime design cruise altitude was 4000 metres despite lack of pressurisation or cabin oxygen supply in RA aircraft. CAUTION - these interim aircraft have NO airscrew or airframe DE-ICING capability. The landing gear is approved for use from unpaved (but not unprepared) surfaces. This aircraft has excellent STOL capability. Read 'How to fly the Fiat G.12' before flight. *************************************************************** Take Off: FLAP = STAGE 1 (one light) CARB HEAT = COLD COWLS = 40% ELEVATOR TRIM = 1 cabrata RUDDER TRIM = destra LINE UP TAILWHEEL LOCK = ON BRAKES = ON RPM = MAX THROTTLES = FULL BRAKES = OFF YOKE = FULL FORWARD to raise tail TAIL UP - wait 2 seconds - ROTATE FIRMLY POSITIVE RATE OF CLIMB GEAR = UP ACCELERATE = 170 KmIAS FLAP = UP ACCELERATE = 210 KmIAS Call for Climb power *************************** METO power - use only after engine failure: C = 1.0 RPM = 2400 COWLS = 40% **************************** Climb power: *DO NOT EXCEED 3.5 m/s* 210 KmIAS C <= 0.9 RESTRAIN C to achieve target + limit above RPM = 2300 COWLS = 40% On reaching 4000 metres Call for Econ cruise power **************************** Econ Cruise power: C = 0.8 RPM = 1850 COWLS = CLOSED Plan 700 PPH Note: Yields 171 KTAS at 4000M (FL131) **************************** Max Cruise: Use to battle headwinds C = 0.9 RPM = 2000 COWLS = 10% Plan 930 PPH Note: Yields 194 KTAS at 4000M (FL131) **************************** Descent: *DO NOT EXCEED -3.5 m/s* Retain CRUISE RPM Target prior cruise IAS DO NOT EXCEED 350 KmIAS *AVOID SHOCK COOLING* C reduce @ 0.1 per minute C => 0.5 (*MIN*) COWLS = CLOSED **************************** Holding: FLAP = UP RPM = 1850 C = as required to achieve 210 KmIAS COWLS = as required **************************** Approach Circuit and Landing: C => 0.5 until over boundary fence *Before Glidepath or Circuit*: C = 0.5 REDUCE = 170 KmIAS COWLS = 20% GEAR = DOWN FLAP = STAGE 1 & 2 (two lights) C as required to sustain 170 KmIAS Downwind: RPM = 2000 170 KmIAS Base Leg: C => 0.5 as required to Turn final @ 155 KmIAS Final: CARB HEAT = COLD In time to achieve Vref FLAP = STAGE 3 (four lights) Cross airfield boundary @ 135 KmIAS (all weights) C < 0.5 allowed FLARE After mainwheel contact CORRECT any drift PULL TAILWHEEL GENTLY INTO CONTACT YOKE FULL AFT COWLS = FULL OPEN FLAP = UP BRAKES = as required TAILWHEEL = UNLOCK before taxi RPM = MAX before taxi Nose engine = SHUT DOWN ****************************