Best practices, Hot Topics, Fleet issues, SB's CFM56-7 AES Handouts
**** Hidden Message ***** CFMI Proprietary Information. 1<BR>CFMI Proprietary Information:<BR>The information contained in this document is CFMI Proprietary Information and is disclosed in confidence.<BR>It is the property of CFMI and shall not be used, disclosed to others or reproduced without the express<BR>written consent of CFMI, including, but without limitation, it is not to be used in the creation, manufacture,<BR>development, or derivation of any repairs, modifications, spare parts, designs, or configuration changes or<BR>to obtain FAA or any other government or regulatory approval to do so. If consent is given for reproduction<BR>in whole or in part, this notice and the notice set forth on each page of this document shall appear in any<BR>such reproduction in whole or in part. The information contained in this document may also be controlled<BR>by U.S. export control laws. Unauthorized export or re-export is prohibited.<BR>For Training Purposes only!<BR>Best practices, Hot Topics, Fleet issues, SB's<BR>CFM56-7 AES Handouts<BR>CFMI Proprietary Information. 2<BR>Standard Day Sea Level CFM56-7B18 CFM56-7B20 CFM56-7B22 CFM56-7B24 CFM56-7B26 CFM56-7B27<BR>Aircraft Application 737-600 737-600 737-600<BR>Aircraft Application 737-700 737-700 737-700<BR>Aircraft Application 737-800 737-800 737-800<BR>Aircraft Application 737-900 737-900 737-900<BR>Aircraft Application Navys C40A<BR>Aircraft Application Boeing Business Jet<BR>Aircraft Application COMBI<BR>Engine Weight 5,205 pounds 5,205 pounds 5,205 pounds 5,205 pounds 5,205 pounds 5,205 pounds<BR>T/O Engine Thrust lbs. 19500 lbs 20,600 22,700 24,200 26,300 27,300<BR>T/O Engine Thrust daN 8,674 daN 9,163 daN 10,097 daN 10,765 daN 11,699 daN 12,144 daN<BR>Thrust Option Model B1 B1 Optional B1 Optional B1 Optional<BR>N1 RPM 100% 5,175 RPM 5,175 RPM 5,175 RPM 5,175 RPM 5,175 RPM 5,175 RPM<BR>N2 RPM 100% 14,460 14,460 14,460 14,460 14,460 14,460<BR>Max. N1 RPM 104% 5,380 RPM 5,380 RPM 5,380 RPM 5,380 RPM 5,380 RPM 5,380 RPM<BR>Max. N2 RPM 105% 15,183 15,183 15,183 15,183 15,183 15,183<BR>Ground Idle N2% 58.8% SDSL 58.8% SDSL 58.8% SDSL 58.8% SDSL 58.8% SDSL 58.8% SDSL<BR>Ground Idle N1% 19.7% SDSL 19.7% SDSL 19.7% SDSL 19.7% SDSL 19.7% SDSL 19.7% SDSL<BR>Maximum EGT Starting 725 degrees C 725 degrees C 725 degrees C 725 degrees C 725 degrees C 725 degrees C<BR>Maximum EGT T/O 950 degrees C 950 degrees C 950 degrees C 950 degrees C 950 degrees C 950 degrees C<BR>Appox. Normal EGT T/O 755 degrees C 744 degrees C 772 degrees C 773 degrees C 792 degrees C 811 degrees C<BR>Max. Continuous EGT 925 degrees C 925 degrees C 925 degrees C 925 degrees C 925 degrees C 925 degrees C<BR>Fuel flow lbs/per/hr 6,720 pph 7173 pph 8,008 pph 8,662 pph 9,616 pph 10,191 pph<BR>SFC 0.345 0.348 0.353 0.357 0.366 0.373<BR>Starting Fuel flow 500-600 pph 500-600 pph 500-600 pph 500-600 pph 500-600 pph 500-600 pph<BR>5th stage bleed air temp. T/O 600 degrees F. 613 degrees F. 637 degrees F. 654 degrees F. 679 degrees F. 694 degrees F.<BR>9th stage bleed air temp. T/O 888 degrees F. 906 degrees F. 936 degrees F. 959 degrees F. 991 degrees F. 1,010 degrees F.<BR>5th stage bleed psig. T/O 120 psig 126 psig 137 psig 145 psig 157 psig 164 psig<BR>9th stage bleed psig. T/O 275 psig 290 psig 314 psig 333 psig 360 psig 375 psig<BR>CFMI Proprietary Information. 3<BR>Standard Day Sea Level CFM56-7B18 CFM56-7B20 CFM56-7B22 CFM56-7B24 CFM56-7B26 CFM56-7B27<BR>Oil Pressure Max. 362.5 psid 362.5 psid 362.5 psid 362.5 psid 362.5 psid 362.5 psid<BR>Oil Pressure Cruise 50 psid 50 psid 50 psid 50 psid 50 psid 50 psid<BR>Oil Pressure Min. 13 psid 13 psid 13 psid 13 psid 13 psid 13 psid<BR>Oil Pressure Below Min. (10 seconds max. in a negative G operation only.)<BR>Transient Oil Temp. 160 C (320 F) 160 C (320 F) 160 C (320 F) 160 C (320 F) 160 C (320 F) 160 C (320 F)<BR>Max.Steady State Oil Temp. 155 C (311 F) 155 C (311 F) 155 C (311 F) 155 C (311 F) 155 C (311 F) 155 C (311 F)<BR>Idle Steady State Oil Temp. 150 C (302 F) 150 C (302 F) 150 C (302 F) 150 C (302 F) 150 C (302 F) 150 C (302 F)<BR>Steady State Oil Temp. 140 C (284 F) 140 C (284 F) 140 C (284 F) 140 C (284 F) 140 C (284 F) 140 C (284 F)<BR>Amber Indication (284 F) (284 F) (284 F) (284 F) (284 F) (284 F)<BR>Red Line Indication (311 F) (311 F) (311 F) (311 F) (311 F) (311 F)<BR>Oil Tank Volume 5 US Gallons 5 US Gallons 5 US Gallons 5 US Gallons 5 US Gallons 5 US Gallons<BR>.1 Gal/Hr. Normal All All All All All All<BR>.2 Gal/Hr. Still OK All All All All All All<BR>BBJ max. flight 16.32 hours .21 Gal/Hr.<BR>737ERmax. flight 13.62hrs. .25 Gal/Hr.<BR>ETOPS max. flight 12.13 hours N/A N/A N/A N/A .27 Gal./Hr<BR>.3 Gal/Hr. Investigate Investigate Investigate Investigate Investigate Investigate<BR>Max. Oil Consumption .4 Gal./Hr .4 Gal./Hr .4 Gal./Hr .4 Gal./Hr .4 Gal./Hr .4 Gal./Hr<BR>Min. Usable Oil Volume 2.72 US Gallons 2.72 US Gallons 2.72 US Gallons 2.72 US Gallons 2.72 US Gallons 2.72 US Gallons<BR>Min. Usable Oil Liters 2.72 10.3 Liters 2.72 10.3 Liters 2.72 10.3 Liters 2.72 10.3 Liters 2.72 10.3 Liters 2.72 10.3 Liters<BR>Approved Oils Reference Service Bulletin 79-001Service Bulletin 79-001 Service Bulletin 79-001 Service Bulletin 79-001 Service Bulletin 79-001 Service Bulletin 79-001<BR>CFMI Proprietary Information. 4<BR>Engine STA CG 207.4 inches 207.4 inches 207.4 inches 207.4 inches 207.4 inches 207.4 inches<BR>Engine CG WL 99.25 inches 99.25 inches 99.25 inches 99.25 inches 99.25 inches 99.25 inches<BR>Engine CG BL 99.17 inches 99.17 inches 99.17 inches 99.17 inches 99.17 inches 99.17 inches<BR>Engine Length 98.72 inches 98.72 inches 98.72 inches 98.72 inches 98.72 inches 98.72 inches<BR>Width 83.4 inches 83.4 inches 83.4 inches 83.4 inches 83.4 inches 83.4 inches<BR>Height 72 inches 72 inches 72 inches 72 inches 72 inches 72 inches<BR>Starting N2 Speed (25% N2 or max motoring)<BR>Starting Min. N2 Speed (20% N2) (20% N2) (20% N2) (20% N2) (20% N2) (20% N2)<BR>Starter Limits 2 Minutes 2 Minutes 2 Minutes 2 Minutes 2 Minutes 2 Minutes<BR>Starter engagement Flight 11% N2 Flight 11% N2 Flight 11% N2 Flight 11% N2 Flight 11% N2 Flight 11% N2<BR>Starter Reengagement 0< 55% N2 0< 55% N2 0< 55% N2 0< 55% N2 0< 55% N2 0< 55% N2<BR>Standard Day Sea Level CFM56-7B18 CFM56-7B20 CFM56-7B22 CFM56-7B24 CFM56-7B26 CFM56-7B27<BR>Engine warm-ups 2 Minutes 2 Minutes 2 Minutes 2 Minutes 2 Minutes 2 Minutes<BR>Engine Cool Downs 3 Minutes 3 Minutes 3 Minutes 3 Minutes 3 Minutes 3 Minutes<BR>Engine warm-ups 1st time 5 Minutes 5 Minutes 5 Minutes 5 Minutes 5 Minutes 5 Minutes<BR>AGB air pressure at idle 5 psi over ambient (15-17 psia) All CFM56-7B Models CFM56-7B Models CFM56-7B Models CFM56-7B Models<BR>AGB air pressure at T/O (27-28 psia) All CFM56-7B Models CFM56-7B Models CFM56-7B Models CFM56-7B Models<BR>Wind Milling Limits On Ground Max. 6 hours Max. 6 hours Max. 6 hours Max. 6 hours Max. 6 hours Max. 6 hours<BR>CFMI Proprietary Information. 5<BR>Performance based on no bleed or power extractions SLSD from Boeing.<BR>For Training purposes only!<BR>CFMI Proprietary Information. 6<BR>CFMI Proprietary Information. 7<BR>CFMI Proprietary Information. 8<BR>CFMI Proprietary Information. 9<BR>CFMI Proprietary Information. 10<BR>1. The ADIRU’s provide pressure total to the EEC switches and ALTN mode indication.<BR>2. 3 PITOT tubes and heaters – provides mach number<BR>3. 2 AOA sensors<BR>4. 1 TAT sensor 2 types aspirated and non-aspirated<BR>5. 4 ADM’s air data to digital is done 4 times per second<BR>6. 5 static ports<BR>FMC – used for:<BR>1. 1. Navigation – way points, radio, VHF, etc<BR>2. 2. Operation of thrust<BR>3. 3. Auto throttle interfaces: DFCA, ATC, safe minimum airspeeds, moves thrust levers.<BR>4. 4. Assists in efficient speeds and altitude by storing data of:<BR>a. a. Wf<BR>b. b. Thrust<BR>c. c. N1 limits<BR>d. d. Fuel Used<BR>e. e. FMC couple to the digital flight control systems<BR>f. f. EEC-DEU-ATC<BR>Thrust Modes – EEC switches<BR>1. 1. Normal<BR>2. 2. Soft – No change in thrust light ALTN illuminates<BR>3. 3. Hard – Happens what EEC switch is pushed or thrust lever is at idle position<BR>CDS – common display system is 6 screens that display flight data and engine system data using analog or digital data.<BR>RAM – random access memory or erasable memory<BR>NVM – non-volatile memory not erasable.<BR>CPU – Micro-processor that does calculations by using Ram.<BR>PDL – portable data loader down loads data history from the EEC or up loads software<BR>EEPROM – erasable programmable memory read only memory<BR>1. 1. Storage of control adjustments<BR>2. 2. Fault Data<BR>3. 3. Learning memory – engine cycles, peak N1, N2, EGT, etc.<BR>4. 4. Adjustment of control schedules<BR>5. 5. Vendor data<BR>6. 6. Hardware data<BR>7. 7. Check sum – checks data storage areas to see if they are corrupted or not. Also the calculated amount of storage and the sum of<BR>the stored. Improves the integrity of the data previously stored.<BR>CFMI Proprietary Information. 11<BR>On the DP0303 connector on the EEC pin FF identifies<BR>Eng 1. It goes through pin 27 of the DP0324 connector<BR>on the eng pylon. It loops back through pin 28 and<BR>returns to common pin X on the EEC.<BR>Eng 2 basically the same expect is comes out of EEC on<BR>pin HH to pylon connector pin 13 and back to the EEC<BR>ground.<BR>The EEC; DP0404 connector pin CC identifies the -800<BR>through pin 20 on the DP0460 connector on the eng<BR>pylon. It returns to ground through pin 36 (on the pylon<BR>connector) and pin FF on the EEC connector.<BR>The EEC; DP0404 connector pin BB identifies -700<BR>through pin 19 on the pylon DP0460 connector using the<BR>same common loop.<BR>The EEC; DP0404 connector pin HH identifies -600<BR>through pin35 on the pylon DP0460 connector using the<BR>same common loop. The electrical harness connector<BR>DP0303 and DP0404.<BR>The reference information comes from the systemschematics manual, 73-21-11<BR>CFMI Proprietary Information. 12<BR>CFMI Proprietary Information. 13<BR>Voltage<BR>. 06 Sine / Cosine 3.28<BR>. 06 Sine<BR>Cosine 3.28<BR>A<BR>B<BR>C<BR>Sine =<BR>Cosine =<BR>Tangent =<BR>A<BR>C<BR>B<BR>C<BR>A Sine<BR>B Cosine<BR>TRA calculated ratio<BR>Tangent<BR>CFMI Proprietary Information. 14<BR>1. Question: What is the regulator in input monitoring mean?<BR>Answer: Ref. ICD Appendix B -21 table shows the 0-16 levels called FMV<BR>regulator definition. It shows the power level schedules, N1 is maintained at all<BR>costs.<BR>2. Question: In the fail safe mode will TEO,PEO, EGT be displayed?<BR>Answer: TEO,PEO, EGT in fail safe mode will not be displayed.<BR>Ref .9-15, 9-21. 9-23 and 15-29 tables<BR>Fail safe 2 mode data tells us the system has failed and is a place holder.<BR>3. Question: NVM is completely erased when programming of the new software is<BR>done. The disk floppy is decoded with the disk for the software that CFM<BR>provides. Everything is erased from the memory and even if it is sent back to the<BR>repair shop it is gone forever none retrievable.<BR>4. Question: PS3, if it is disconnected will default to model engine runs normal.<BR>PS3, if it iced up inside engine runs can flameout.<BR>PS3, if it leaking the engine can flameout, goes to min. idle.<BR>Regulators<BR>CFMI Proprietary Information. 15<BR>Autothrottle computer and EEC interfaces<BR>Q. What are the parameters used by the autothrottle computer ?<BR>A. The autothrottle computer receives data from the FMC.<BR>Q. How is the thrust calculated ?<BR>A. The FMC calculates thrust from ADIRU parameters, aircraft type and engine model (program<BR>pins). Parameters are used from 1,2 or both ADIRU's. The FMC then transmits Nl target to<BR>EEC through the CDS/DEU, data to autothrottle and sets the Nl Bug to be displayed.<BR>Q. How does it manage with flex Take Off ? Does a reference table exist?<BR>A. The flex T/O is calculated by the FMC using the assumed temperature method. The calculated<BR>OAT greater than the corner point must be entered through the CDU T/O page. The FMC<BR>calculates the N 1 for flex T/O and sets the N 1 bug accordingly. The OAT entered for FLEX is<BR>displayed on CDU. The aircraft is also able to work in derated mode. The derate level is entered through the CDU<BR>and can be accumulated with flex T/O. For example: on 737-600 aircraft, max rating is<BR>22,000lbs.<BR>If 7-B22 engine is installed it is possible to choose full rated thrust or to select derated level at<BR>20,600 or 19500lbs thrust. Then enter an assumed temperature. The selected thrust level is used<BR>to calculate the flex T/O value.<BR>On this aircraft, there is not any detent on throttle lever. Only a line indicates the position of the<BR>throttle for T/O. When derate and/or flex is set, the FMC displays the Nl bug which corresponds<BR>to the thrust level for T/O on CDU in the Nl sector. In manual mode, the crew pushes the throttle<BR>lever until the Nl indicator aligns with the Nl bug. In autothrottle, once autothrottle is armed<BR>on the glareshield panel, it is possible to make it active by pressing one of the two push buttons<BR>located under the throttle lever handle. Then the auto throttle moves the levers so that the Nl<BR>indicator aligns with the N 1 bug. This way, T/O power is automatically set.<BR>Q. How does the system deal with the hard alternate mode ?<BR>A. The FMC is able to calculate the correct thrust using the ADIRU parameters. Unlike the EEC,<BR>the FMC can use parameters from ju.\,t ONE ADIRU. It mean.\' that when the EEC has a missing<BR>ADIRU parameter, it does not continue to u~.e parameters from the other ADIRU and switches<BR>to Alternate mode. Then the FMC still continues to calculate with just one ADIRU, setting the<BR>correct thrust.<BR>CFMI Proprietary Information. 16<BR>Engine water wash every 500 cycles<BR>about 10 degrees of EGT recovery each time.<BR>Benefits – SFC and TOW<BR>EGTM<BR>Time on wing<BR>Engine water wash<BR>CFMI Proprietary Information. 17<BR>CFMI Proprietary Information. 18<BR>CFMI Proprietary Information. 19<BR>CFMI Proprietary Information. 20<BR>DT std<BR>CFMI Proprietary Information. 21<BR>CFMI Proprietary Information. 22<BR>PO<BR>CFMI Proprietary Information. 23<BR>CFMI Proprietary Information. 24<BR>CFMI Proprietary Information. 25<BR>T25 CH A - Valid<BR>T25 CH B - Valid<BR>T25 SENSOR<BR>Average Selected<BR>T25 CH A – Valid<BR>T25 CH B – Valid<BR>Delta Difference beyond limits > 5 degrees approx.<BR>T25 CH A - Valid<BR>T25 CH B - Invalid Model Invalid - CH A selected<BR>T25 CH A - Valid<BR>T25 CH B - Invalid Model valid - CH A or model selected<BR>T25 CH A - Valid<BR>T25 CH B - Valid Average Selected<BR>Closest to model selected<BR>CFMI Proprietary Information. 26<BR>TEO - (Range – 30 C. to 170 C.) + 5 degrees<BR>TEO CH A = 100 C<BR>TEO CH B = 104 C Average Selected = 102 C selected<BR>TEO CH A = 100 C<BR>TEO CH B = 110 C Average Selected = 110 C selected F/S 1<BR>TEO CH A = 176 C<BR>TEO CH B = 180 C Average Selected = 170 C selected F/S 2<BR>CFMI Proprietary Information. 27<BR>Calculated Models<BR>1. PS3<BR>2. N1<BR>3. N2<BR>4. T3<BR>5. T25<BR>6. FMV<BR>7. VSV<BR>8. VBV<BR>CFMI Proprietary Information. 28<BR>Engine Static Balance and AVM Task Form<BR>CFMI Proprietary Information. 29<BR>CFM56-7B -- EEC Alternate Mode Light Versus Engine Control Light (01-12-7321-04)<BR>CFMI has received event reports suggesting that there may be some confusion over the difference between the cockpit ENGINE CONTROL light and the EEC<BR>Alternate Mode (EEC-ALTN) light. This article is intended to clarify the distinction between these two lights, both in terms of dispatch ramifications and the<BR>conditions under which these lights can illuminate. It is hoped that a better understanding of these distinctions will improve the troubleshooting, and reporting, of<BR>events related to the illumination of these lights.<BR>The figure below describes the dispatch limitations of the ENGINE CONTROL light and the EEC-ALTN light. Both lights are located in the flight compartment on<BR>the P5 Aft Overhead Panel.<BR>When ENGINE CONTROL light 1 or 2 is illuminated, the airplane is in a no-dispatch configuration and there is no MMEL relief for this condition. The ENGINE<BR>CONTROL light can be illuminated only when the airplane is on the ground.<BR>When EEC-ALTN light 1 or 2 is illuminated, both EECs must be placed into the alternate mode. Refer to the page 2-73-11.0 of the 737 Dispatch Deviations<BR>Procedures Guide (DDPG), dated June 1, 2001 for relief from the EEC-ALTN light. The EEC-ALTN light can be illuminated when the airplane is in flight or on<BR>the ground.<BR>CFMI Proprietary Information. 30<BR>• The EEC provides a ground to the light (pin 16) .<BR>If the wire between the light and the EEC is shorted to ground<BR>the light can go on when correlated maintenance messages<BR>do not show.<BR>• N1% = 10 degrees of EGT for 1%<BR>• EGT indication failure no display EEC uses 15 C.<BR>• N1 indication failure N2 model used.<BR>• PS3 leak flameout or goes to min. idle<BR>• PS3 blockage stall then flameout<BR>CFMI Proprietary Information. 31<BR>CFMI Proprietary Information. 32<BR>CFM56-7B LOW ALTITUDE VSV SCHEDULE (ALT<17.5K)<BR>-10<BR>-5<BR>0<BR>5<BR>10<BR>15<BR>20<BR>25<BR>30<BR>35<BR>40<BR>8000 8500 9000 9500 10000 10500 11000 11500 12000 12500 13000 13500<BR>N2K25 (RPM)<BR>VSV (DEGREES)<BR>LOWALTITUDETRANSIENT<BR>T2 > = 0 DEG C<BR>LOWALTITUDEBODIE<BR>LOWALTITUDETRANSIENT<BR>T2 < 0 DEG C<BR>LOWALTITUDESTEADY STATE<BR>DAC SAC<BR>CFMI Proprietary Information. 33<BR>CFM56-7B VSV SCHEDULES<BR>-4<BR>-3<BR>-2<BR>-1<BR>0<BR>1<BR>14200 14300 14400 14500 14600 14700 14800 14900 15000 15100 15200 15300 15400<BR>N2ACTSEL (RPM)<BR>VSV (DEGREES)<BR>VSV DEMAND = VSV(PART A) + VSV(PART B)<BR>CFMI Proprietary Information. 34<BR>CFM56-7B VBV SCHEDULE (SLS)<BR>0<BR>5<BR>10<BR>15<BR>20<BR>25<BR>30<BR>35<BR>40<BR>1000 1500 2000 2500 3000 3500 4000 4500 5000 5500<BR>N1K12 (RPM)<BR>VBV (DEGREES)<BR>CFMI Proprietary Information. 35<BR>CFMI Proprietary Information. 36<BR>CFM56-7B HPTACC System<BR>HPTACC support HPTACC Air Inlet Ports, 19°& 199°ALF<BR>(4th, 9th, low 9th or mixed 4th/9th air supplied by HPT valve)<BR>• The T3 sensor is currently used in -7B HPTACC logic<BR>(T3 sensor will remain, used in other areas of control logic)<BR>• -7B DAC HPTACC logic will remain unchanged (DAC is more marginal on cold starting)<BR>CFMI Proprietary Information. 37<BR>Current HPTACC Logic<BR>• CFM56-7B has an active HPT blade tip clearance control system<BR> Goal of HPTACC system is to minimize blade tip rub, minimize take-off EGT<BR>and to provide a tight clearance at altitude cruise for optimum SFC.<BR> 4th stage HPC air, 9th stage HPC air or mixed 4th/9th can be impinged on to<BR>the HPT shroud support to control HPT blade tip clearance<BR> Current logic calculates a demand shroud support ring ratio (support TC<BR>temperature divided by T3) as a function of N2, altitude and time. FADEC<BR>converts the demand ring ratio into a demand shroud support temperature by<BR>multiplying by T3. The demand HPT valve position is set by comparing the<BR>calculated demand support temperature to the measured shroud support<BR>temperature, T3 and a calculated 4th stage air temperature<BR> Current logic has a failsafe schedule which is used when either the support T3<BR>sensor are declared invalid (outside -60°C to 855°C range)<BR> Failsafe logic calculates demand HPT valve position as a function of N2 and<BR>time. Schedules mixed mode or 9th stage air to HPT shroud. Conservative<BR>from a blade tip rub standpoint but leads to increased take-off EGT and fuel<BR>burn.<BR>CFMI Proprietary Information. 38<BR>• Current ring ratio schedules are a function on N2 and HPRTEMP<BR> Ring ratio is the support TC temperature / T3<BR> HPRTEMP is the nondimensional thermal state of the HPT rotor. HPRTEMP is a<BR>function of N2 and time. The N2 component is related to the thermal growth of the<BR>HPT rotor. The time component is related to the thermal time constant of the HPT<BR>disk<BR>Current -7B SAC Ring Ratio Schedules<BR>-0.5<BR>0<BR>0.5<BR>1<BR>1.5<BR>2<BR>2.5<BR>8000 9000 10000 11000 12000 13000 14000 15000 16000<BR>Core Speed (RPM)<BR>HPTACC Ring Ratio<BR>HPRTEMP = -1<BR>Ground Below 23K ft<BR>Altitude 23-33 K ft<BR>Altitude 41 K ft<BR>HPRTEMP = +1<BR>Cold Rotor, HPRTEMP = -1<BR>Hot Rotor, HPRTEMP = +1<BR>Steady State Schedules<BR>HPRTEMP = 0<BR>CFMI Proprietary Information. 39<BR>• Valve position is a function of N2, altitude and time<BR>• No change to HPRTEMP calculation except initial value at ECU power up will be 0.4 (rub protection)<BR>• Cold rotor schedule set to match current warm start transition from 4th stage air to mixed mode<BR>during accels (calculated demand positions > 100% are set to 100% (full 4th))<BR>• Hot rotor schedule set to low flow 9th valve position (8%) to protect against re-accel rubs.<BR>Proposed -7B SAC HPT Valve Position Schedules<BR>0<BR>50<BR>100<BR>150<BR>200<BR>250<BR>8000 9000 10000 11000 12000 13000 14000 15000 16000<BR>Core Speed (RPM)<BR>HPT Valve Position Demand (%)<BR>HPRTEMP = -1<BR>Steady State Ground<BR>Steady State Altitude<BR>HPRTEMP > .05<BR>100% Stroke : Full 4th<BR>38-99% Stroke : Mixed Mode<BR>37% Stroke : Full 9th<BR>8% Stroke : Low Flow 9th<BR>Steady State Altitude<BR>(23K ft & Above)<BR>Steady State Ground<BR>(18K ft & Below)<BR>Cold Rotor, HPRTEMP = -1<BR>Hot Rotor, HPRTEMP > 0.05<BR>CFMI Proprietary Information. 40<BR>HPT Valve Position Comparison for Typical Flight Profile<BR>• Start to idle : Current logic schedules 9th stage air to improve stall margin<BR> Start mode will remain 9th stage with new logic<BR>• Idle : Current HPTACC air mode is initially 4th on cold starts (transitions to 9th as HPT<BR>rotor heats up), 9th on warm starts<BR> Logic at idle air mode will be 9th on all starts to protect against blade tip rub during<BR>take-off<BR>• Take-off : Current air mode is 4th to minimize EGT<BR> Transient schedule defined so that air mode w/o T/Cs will remain 4th<BR>• Climb : Current air mode is initially 4th then mixed as HPT rotor heats up<BR> Cold rotor schedule set so transition from 4th will be the same as current warm<BR>engine starts.<BR> Steady state schedule defined to give same average valve positions (clearances) as<BR>current logic. Based on analysis of existing engine data, on HPT blade tip<BR>clearance will increase by 0.4 mils. Existing measured flight test climb clearance<BR>probe data indicates this increased variation is too small to cause additional blade<BR>tip rub.<BR>• Cruise : Current air mode is 4th.<BR>• Descent : Current air mode is low flow 9th to protect against re-accel rubs.<BR> Hot rotor schedule defined so that air mode will remain low flow 9th.<BR>CFMI Proprietary Information. 41<BR>CFMI Proprietary Information. 42<BR>VBV Door Assembly<BR>CFMI Proprietary Information. 43<BR>VBV Door Assembly<BR>CFMI Proprietary Information. 44<BR>CONTROL LOOP EXAMPLE<BR>EEC HMU Actuator<BR>Channel A<BR>Channel B<BR>CCDL Torque<BR>Motor<BR>Pilot<BR>Valve<BR>EEC Active Channel A<BR>- Channel A wiring harness and torque motor coil used to drive HMU<BR>- HMU fuel pressures used to drive Actuator<BR>- Both channels of feedback used to evaluate Actuator position<BR>Electric<BR>Hydraulic<BR>Active<BR>CFMI Proprietary Information. 45<BR>CONTROL LOOP EXAMPLE<BR>Control Loop Fault:: THE HMU CURRENT IS OUT OF RANGE<BR>EEC HMU Actuator<BR>Channel A<BR>Channel B<BR>CCDL Torque<BR>Motor<BR>Pilot<BR>Valve<BR>The EEC senses that the control current delivered to the HMU torque motor coil is different than the<BR>current returned from the circuit (indicates open or short circuit).<BR>The EEC recognizes that it cannot drive the actuator with this channel and may change to the<BR>standby channel (if it has more capability).<BR>This is an electrical fault and indicates that the problem is in the EEC or HMU or the Wiring.<BR>(NOTE: CFM56 wiring is very reliable, with MTBUR over 2 MEFH)<BR>Electric<BR>Hydraulic<BR>CFMI Proprietary Information. 46<BR>CONTROL LOOP EXAMPLE<BR>Control Loop Fault:: THE POSITION SIGNAL IS OUT OF RANGE<BR>EEC HMU Actuator<BR>Cannel A<BR>Cannel B<BR>CCDL Torque<BR>Motor<BR>Pilot<BR>Valve<BR>The EEC senses that the Feedback from one (or both) channels is not in the valid range. Typically<BR>the system can be operated properly using feedback from the other channel.<BR>There is no reason to change active channels since valid feedback is obtained from the other<BR>channel through the CCDL.<BR>This is an electrical fault and indicates that the problem is in the EEC, the Actuator or the Wiring.<BR>Electric<BR>Hydraulic<BR>CFMI Proprietary Information. 47<BR>CONTROL LOOP EXAMPLE<BR>Control Loop Fault:: THE DEMAND AND POSITION SIGNALS DISAGREE<BR>EEC HMU Actuator<BR>Cannel A<BR>Cannel B<BR>CCDL Torque<BR>Motor<BR>Pilot<BR>Valve<BR>The EEC senses that the Actuator did not move when commanded. There is no “CONTROL CURRENT<BR>OUT OF RANGE” fault and the feedback signal from the actuator is valid.<BR>Since there is no “CONTROL CURRENT OUT OF RANGE” fault, the EEC does not consider this an<BR>electrical problem and will not change channels. The only exception would be a short between the two wires<BR>in the control current (maintaining the current in this loop, but bypassing the torque motor coil).<BR>This is a mechanical fault and indicates that the problem is in the HMU, the Actuator or the fuel lines.<BR>Electric<BR>Hydraulic<BR>CFMI Proprietary Information. 48<BR>CFMI Proprietary Information. 49<BR>VSV LVDT Example 1<BR>CFMI Proprietary Information. 50<BR>VSV LVDT Example 2<BR>CFMI Proprietary Information. 51<BR>VSV LVDT Example 3<BR>CFMI Proprietary Information. 52<BR>VSV LVDT Example 4<BR>CFMI Proprietary Information. 53<BR>SUBTASK 12-13-11-970-002<BR>(1)<BR>Find the minimum oil level necessary to dispatch the airplane with these recommendations:<BR>(a)<BR>Before each flight, the indicated engine oil level in the flight compartment with the engine not in<BR>operation must be 60% full or 12.00 U.S. quarts (11.40 liters) or more.<BR>1)<BR>If the airplane has more than one flight between oil servicing, make sure there is enough oil in the tank so<BR>the indicated level is always greater than 60% before each flight.<BR>2)<BR>There must be 7 quarts (6.65 liters) or more of oil remaining in the tank by the end of the scheduled flights<BR>for possible takeoff and go-around (TOGA) operation.<BR>(b)<BR>Calculate the oil usage from the flight(s) duration and the specific engine oil consumption.<BR>(c)<BR>Normal consumption is less than 0.4 US quart/hour or 0.1 US gallon/hour (0.38 liters/hour).<BR>The consumption shows a gradual increase or sudden step increase.<BR>The consumption is more than 0.8 US quart/hour or 0.2 US gallon/hour (0.76 liters/hour).<BR>Engine Oil Consumption Limitations<BR>CFMI Proprietary Information. 54<BR> Background<BR> Previous engine oil consumption limitations were common for all 737 minor models.<BR>» Commercial 737NG oil consumption limited to 0.25 gallons per hour.<BR>» 737 Boeing Business Jets limited to 0.22 gallons per hour<BR>» Limitation contained in AMM section 71-00-00<BR> The FAA has changed position on engine oil consumption limitations.<BR>» Required limitation in Section 9 of the Maintenance Planning Document<BR>during certification of new minor models.<BR>> 737-900<BR>> 737-800 w/ winglets<BR>» The FAA has indicated they may initiate an AD to require coverage of all<BR>models in the MPD.<BR>MODEL 737- WINGLET INSTALLED FUEL ENDURANCE (HOURS) OIL CONSUMPTION GUIDELINE US GAL/HR (LITER/HR)<BR>600 NO 12.09 0.29 (1.098)<BR>CFMI Proprietary Information. 55<BR>No 9 0.22<BR>737-900 No 0 0.34<BR>Yes 0 0.31<BR>737-800 No 0 0.33<BR>Yes 9 0.22<BR>737-700BBJ<BR>737-700, -700C No 0 0.30<BR>737-600 No 0 0.29<BR>Oil Endurance<BR>(gal/hours)<BR>Number of Auxiliary<BR>Tanks<BR>737 Minor Model Winglet Equipped<BR>Airplane Maintenance Manual Revision.<BR>» Revised minor-model specific oil consumption limitations will be published in AMM section 71-00-00<BR> Maintenance Planning Document Revision<BR>» Revised MPD Section 9 text will allow use of minor-model specific limits for 737-900 model & 737-800<BR>model with winglets.<BR>CFMI Proprietary Information. 56<BR>Debris<BR>Monitoring<BR>System<BR>CFMI Proprietary Information. 57<BR>Debris<BR>Monitoring<BR>System<BR>CFMI Proprietary Information. 58<BR>Debris<BR>Monitoring<BR>System<BR>CFMI Proprietary Information. 59<BR>CFMI Proprietary Information. 60<BR>Oil Cover<BR>Oil Supply<BR>CFMI Proprietary Information. 61<BR>Bleed Air Issues<BR>CFMI Proprietary Information. 62<BR>Questions from Airlines class, on the Boeing side, dealing with bleed air systems.<BR>1. When the 220 psi over pressure switch is activated due to an over pressurization problem and the PSROV is<BR>stuck in the open position, where does the air bleed to?<BR>The multiple failure situation stated would be most unfortunate! However, should there be an overpressure<BR>fault, and the PRSOV remain open (note duct pressure indication) after the BLEED TRIP OFF light illuminates,<BR>the excess pressure would go straight to the pneumatic system. There are no pressure relief valves in the<BR>pneumatic system except for the APU bleed valve and high stage valve pressure relief valve. Note: For the APU<BR>bleed valve to relieve pressure on the pneumatic system, with the APU not running, would also require the<BR>additional failure of the APU bleed check valve. The pneumatic system ducts are designed to contain an air<BR>pressure of 250 psi. The remaining pressure relief is the relief valve for the high stage valve. This valve opens at<BR>160 psi and its primary purpose is to protect the inner high stage valve mechanism. Due to the volume of air<BR>present in the interstage duct, it is not designed to relieve all the excess pressure in the interstage duct.<BR>2. How can we regulate engine pressure if this occurs at the Top Of Descent?<BR>To answer the question, the only way for a pilot to regulate the engine bleed pressure should both the high stage<BR>valve and the PRSOV fail open is to reduce power on the affected engine. Unregulated pressure of the 9th stage<BR>of the HPC at idle, at sea level, is approximately 18 psi. Unregulated 9th stage pressure at takeoff power is<BR>approximately 350 psi. Unregulated pressure of the 5th stage of the HPC at idle, at sea level, is approximately 7<BR>psi. Unregulated 5th stage pressure at takeoff power is approximately 160 psi. For an ETOPS flight, if this<BR>condition occurs before reaching equal distance point (EDP) the pilots would air turnback. If the condition<BR>occurred after EDP, the pilots would have to continue on with one engine power reduced to near idle speed.<BR>Boeing 737 Operations Manual, Checklist Introduction, Chapter C1, Non-Normal Checklists, Section 2: “Non-<BR>Normal checklist Operation:…While every attempt is made to establish necessary non-normal checklists, it is<BR>not possible to develop checklists for all conceivable situations, especially those involving multiple failures. In<BR>certain unrelated multiple failure situations, the flight crew may have to combine elements of more than one<BR>checklist and/or exercise judgment to determine the safest course of action. The captain must assess the<BR>situation and use sound judgment to determine the safest course of action.”<BR>CFMI Proprietary Information. 63<BR>3. What components can cause an overpressure on the ground while on T/O roll?<BR>Example: moving the throttle from idle to T/O power.<BR>• A fast engine acceleration where a slower reacting high stage valve could cause high 9th stage<BR>pressure to activate the over pressure switch before the high stage valve fully closes. Note: There is<BR>always a slight lag between pressure changes at the 9th stage of the HPC, relative to N2 speed<BR>changes, and reaction by the high stage valve. This lag can increase with an older, more warn out<BR>valve.<BR>• Mx inadvertently installs a 180-psi overpressure switch on the bleed air regulator instead of the<BR>220-psi overpressure switch preferred for AQs –7B26 engines. Note: Using a 180 psi overpressure<BR>switch on –7B26 and –7B27 engines can possibly cause nuisance bleed trip conditions.<BR>• A failure (crack or break) of the high stage valve downstream sense line. Note: This line provides<BR>interstage duct pressure reference to the high stage valve for pressure regulation.<BR>• A failure to the full-open position of the high stage valve.<BR>• Failure of the overpressure switch on the bleed air regulator.<BR>• Failure of the K8 relay in the air conditioning accessory unit (ACAU).<BR>4. When the lower display unit is showing the systems page (display of FLT CTRL Pos, Hyd Qty), when<BR>an engine alert comes up (Lo oil Qty), will the message come up automatically on the displays or do<BR>you have to return to the engine primary page to see the message alert?<BR>If the lower DU is in MFD and is currently showing Systems, any abnormal secondary engine<BR>indication alert will automatically activate the upper center display to show a compacted secondary<BR>engine display. The alert will now be visible on the upper center DU while the lower center DU will<BR>continue to show Systems information.<BR>CFMI Proprietary Information. 64<BR>Maintenance Tips on bleed trip problems and duct split problems.<BR>• Check for proper function of the two duct pressure transmitters.<BR>• Check for proper function of the duct pressure indicator.<BR>• Check for proper function of the pre-cooler control valve sensor.<BR>• Check for proper function of the 450F thermostat for the PRSOV.<BR>• Check to ensure the sense line from the 450F thermostat to the PRSOV is intact, not leaking, no loose<BR>connections.<BR>• Check to ensure the PRSOV downstream sense line is intact, not leaking, no loose connections.<BR>• Check for proper and smooth operation of the PRSOV.<BR>• Check to ensure there are no internal leaks in the PRSOV.<BR>• Check for proper operation of the 490F over-temp switch.<BR>• Check for proper operation of the 180/220 psi. overpressure switch, whichever one is installed.<BR>• Check to make sure the high stage valve closes completely.<BR>• Check for proper operation of the pre-cooler control valve.<BR>• Check the pre-cooler for obstructions, debris, clogging, damage.<BR>• Check to ensure the seal between the pre-cooler control valve and pre-cooler is intact, not damaged,<BR>and in the correct position.<BR>• Check the inlet to the pre-cooler control valve, on the left side of the 12:00 fan support strut is not<BR>obstructed by dirt or debris, is not damaged.<BR>Note: The last four items are particularly important after the flight crew reports of bird ingestion by an engine.<BR>CFMI Proprietary Information. 65<BR>Couple of basics:<BR>It could also be as simple as a gauge. To check this, open the Isolation Valve<BR>and see if the needles match up. If they do, you have eliminated the gauge.<BR>(Many people forget this step).<BR>8-10 psi is the pressure that is generated by the engine at IDLE from the<BR>5th stage, 18-22 psi from the 9th stage at IDLE. 40 psi is within the range<BR>of pressures for the engine operating IN FLIGHT (42 +/- 8 psi) once PRSOV<BR>has begun to modulate and regulate pressure. (For the entire operation of<BR>the system, please call). All major valves in the engine pneumatics area<BR>are pneumatically operated, which means they have reasonably wide tolerances<BR>(i.e. 42 +/- 8 psi) and are relatively slow (compared to electrically<BR>operated valves) to function.<BR>The PRSOV (Pressure Regulating and Shutoff Valve) has three functions -<BR>ON/OFF, Pressure Regulation, Temperature Regulation. The Precooler Control<BR>Valve regulates the amount of cooling air to the Precooler to normally<BR>regulate bleed air temperature. If the Precooler Control Valve fails to<BR>provide the proper amount of cooling air or the the Precooler is<BR>blocked or dirty, then the temperature would rise above the designed<BR>390-440F/199-227C. Once the bleed air temperature rises above 450F/232C, the<BR>450F thermostat will open to bleed control pressure to the PRSOV causing it<BR>to modulate toward the closed position (thereby decreasing the amount of hot<BR>air). At this point the PRSOV is favoring temperature rather than pressure.<BR>So for the same throttle position, the pressures would be different. How<BR>much different is dependent on the amount of blockage/failure. If the over<BR>temperature condition continues to worsen and decreasing pressure (and air<BR>flow) through the PRSOV does not decrease the temperature, the 490F/254C<BR>switch comes into play and causes a Bleed Trip Off.<BR>If this pressure split comes from a precooler being dirty, usually the onset<BR>of this comes over a period of time. So if a crew runs up and engine and<BR>the maximum pressure they can get is 38 psi, this is within limits but may<BR>need to be monitored. If the Precooler continues to accumulate dirt, over<BR>the next couple of days/weeks the pressure will continue to decrease when<BR>the throttles are in the same original position. Since few spend a lot of<BR>time looking up at the gauge on the P5 panels, this subtle decrease in<BR>pressure is rarely noticed until the duct pressure split is sizable.<BR>If this is a Precooler Control Valve stuck closed the onset should be quicker.<BR>1. Ram Air light is on at 35k or greater heat<BR>exchangers are dirty.<BR>2. No bleed air at T/O but bleed trips too much<BR>pressure the high stage valve is stuck open.<BR>3. Precooler dirty it doesn’t cool, good pressure,<BR>then clean Precooler and monitor. Pressures<BR>should be at idle:<BR>9th 8-20 psi<BR>5th 8-10 psi<BR>4. Data Info.<BR>400 F = 200 C<BR>42 psi + 8 psi is normal<BR>Engine 9th 340 psi<BR>Engine 5th 160 psi<BR>(Regulated lower)<BR>5. APU check valve failure a dual air bleed light<BR>indication. Result may be an APU failure.<BR>6. Bleed trip Light off Temp. Problem<BR>7. Bleed trip Light on pressure Problem<BR>8. Bleed trip Light on after 5-6 SECONDS<BR>9. Push Reset – TLA<BR>10. Move TLA slowly to see plateau pressure of<BR>the 9th about 80% N2 or N1 47%<BR>Couple of basics hints:<BR>CFMI Proprietary Information. 66<BR>Questions from AES class follow-up.<BR>Answers from PSE rewritten by Ted<BR>Q1. Why is there a large difference between the actions of maintenance technicians and pilots in<BR>regards to the starter remaining engaged due to the air start valve not closing?<BR>Answer PSE – The pilots must consider in their situation if the starter remaining engaged, due to<BR>the air start valve has not closed, are they in flight or on the ground. The technician is responding<BR>on the ground only. A checklist must be followed by the pilot, which causes a longer time in most<BR>cases to respond to this situation.<BR>Q2. The EEC alternator failure occurred on one of our aircraft and the ALTN light came on<BR>generating a fault code label of 172. How is this possible to have these two signals linked and<BR>why did this happen?<BR>Answer PSE – The EEC reset feature during start of the FADEC 3 during initialization started in<BR>the soft ALTN mode. The EEC reset then would switch back to normal mode if everything<BR>returned to a normal condition. This situation was corrected with a software change to the<BR>FADEC 3.<BR>Q3. Why is the EEC cooled in flight and not on the ground?<BR>Answer PSE – The EEC is cooled on the ground by the ram air duct. The airplane is normally<BR>turned into the wind for engine runs still allowing for cooling also. In flight we do not need the<BR>extra cooling as on the ground. It has been working well so far, except one situation of an EEC<BR>overheat caused by a CTAI valve clamp loose or possible crack in the valve that blew hot air onto<BR>the EEC.<BR>CFMI Proprietary Information. 67<BR>ETOPS - Extended Range 180 minutes<BR>CFMI Proprietary Information. 68<BR>Extended-range twin-engine operations (ETOPS) have become common practice in<BR>commercial aviation over the last 15 years. Maintenance and operational programs<BR>for the twinjets used in these operations have received special emphasis, and<BR>reliability improvements have been made in certain airplane systems. Many<BR>operators are now considering the merits of the ETOPS maintenance program for<BR>use with non-ETOPS airplanes.<BR>In 1953, the United States developed regulations that prohibited two-engine<BR>airplanes from routes more than 60 min (single-engine flying time) from an<BR>adequate airport. These regulations were later formalized in U.S. Federal Aviation<BR>Administration (FAA) Federal Aviation Regulation 121.161. The ETOPS program,<BR>as outlined in FAA Advisory Circular (AC) 120-42A, allows operators to deviate from<BR>this rule under certain conditions. By incorporating specific hardware improvements<BR>and establishing specific maintenance and operational procedures, operators can<BR>fly extended distances up to 180 min from the alternate airport. These hardware<BR>improvements were designed into Boeing 737-600/-700/ -800/-900 and 777<BR>airplanes.<BR>ETOPS - Extended Range 180 minutes<BR>CFMI Proprietary Information. 69<BR>1. ENGINE HEALTH MONITORING<BR>ETOPS maintenance procedures were created to ensure the safety and reliability of<BR>flights operating at extended distances from alternate airports and to prevent or<BR>reduce the probability of a diversion or turn back with one engine out. These<BR>maintenance procedures are equally effective for any commercial airplane with any<BR>number of engines. Most traditional maintenance programs are based on regularly<BR>scheduled preventive maintenance and on the ability to predict or anticipate<BR>maintenance problems by studying failure rates, removal rates, and other reliability<BR>data. However, the ETOPS philosophy is a real-time approach to maintenance and<BR>includes continual monitoring of conditions to identify problems before they threaten<BR>airplane operation or safety.<BR>ETOPS<BR>CFMI Proprietary Information. 70<BR>Two items in the ETOPS maintenance program that best illustrate this real-time<BR>approach are oil consumption monitoring and engine condition monitoring.<BR>Oil consumption monitoring.<BR>A typical maintenance program requires checking engine oil before every flight (but only<BR>once each day on the 737, as approved by the FAA) and the auxiliary power unit (APU)<BR>oil less frequently (such as every 100 hr). The quantity of oil added and flight hours for<BR>each leg should be noted in the maintenance logbook.<BR>The oil consumption rate, the amount of oil used per hour of operation on the previous<BR>flight leg, should be calculated for both engines and the APU during ETOPS before<BR>dispatch. The resulting number provides a better indication of oil usage or loss than the<BR>quantity of oil added. If the rate is acceptable, the flight can be released; if not, the cause<BR>of the increased usage must be addressed before dispatching the airplane on an<BR>ETOPS flight. This increase can frequently be caused by an oil leak, which is easy to<BR>detect and repair.<BR>The consumption rate data is also logged to track long-term variations in consumption<BR>rates (fig. 1). This allows the operator to determine if problems are developing so they<BR>can identify and implement solutions before serious engine or APU degradation occurs.<BR>ETOPS<BR>CFMI Proprietary Information. 71<BR>Engine condition monitoring (ECM).<BR>For many years, ECM computer programs have been available for all engines used on<BR>Boeing airplanes. The engine manufacturer supplies ECMs to help operators assess the<BR>general health of their engines. The programs allow for monitoring of such parameters<BR>as N1, N2, exhaust gas temperature, fuel and oil pressures, and vibration (fig. 2). Most<BR>operators use an ECM program regardless of whether they fly ETOPS routes. ETOPS<BR>operators are required to use ECMs to monitor adverse trends in engine performance<BR>and execute maintenance to avoid serious failures. These failures could cause in-flight<BR>shutdowns, diversions, or turn backs. In some cases, oil consumption data and ECM<BR>data can be correlated to define certain problems.<BR>ETOPS<BR>CFMI Proprietary Information. 72<BR>2. PRE-DEPARTURE SERVICE CHECK<BR>FAA AC 120-42A requires certain ETOPS systems to be checked before each flight.<BR>Boeing determined that the transit check in the maintenance planning data document<BR>was sufficient to meet the AC requirement. This is because certain systems relating to<BR>ETOPS were redesigned for greater reliability and dispatch requirements were altered<BR>for ETOPS (e.g., minimum equipment list requirements). However, because of the oil<BR>consumption monitoring requirements for ETOPS, the APU check interval on the 737,<BR>757, and 767 was changed to the transit check for ETOPS airplanes. The engine oil<BR>servicing interval changed only on the 737. These two changes and the calculation of<BR>consumption rate are the only changes necessary to the standard transit check to form<BR>the ETOPS predeparture service check.<BR>ETOPS<BR>CFMI Proprietary Information. 73<BR>3. BASIC AND MULTIPLE-SYSTEM MAINTENANCE PRACTICES<BR>Two programs -- resolution of discrepancies and avoidance of multiple similar system<BR>maintenance -- are outlined in AC 120-42A.<BR>Resolution of discrepancies.<BR>This program requires items that are repaired or replaced to be checked for proper<BR>installation and operation before the work is signed off on the maintenance log. This<BR>ensures that the item is actually fixed and that no new problems were introduced during<BR>maintenance. This maintenance practice is applicable to all airplanes. Avoidance of<BR>multiple similar systems maintenance.<BR>Maintenance practices for the multiple similar systems requirement were designed to<BR>eliminate the possibility of introducing problems into both systems of a dual installation<BR>(e.g., engines and fuel systems) that could ultimately result in failure of both systems.<BR>The basic philosophy is that two similar systems should not be maintained or repaired<BR>during the same maintenance visit. Some operators may find this difficult to implement<BR>because all maintenance must be done at their home base.<BR>However, methods exist for avoiding the problems that may be introduced by working on<BR>two similar systems simultaneously. For example, different personnel can perform the<BR>required work on the similar systems, or they can ask each other to review the work<BR>done on each system. If the systems are checked after performing maintenance<BR>according to the resolution of discrepancies program, any problems introduced during<BR>maintenance should be identified and corrected before releasing the airplane for flight.<BR>CFMI Proprietary Information. 74<BR>4. EVENT-ORIENTED RELIABILITY PROGRAM<BR>An event-oriented reliability program associated with ETOPS differs from conventional<BR>reliability programs, which rely on historical data or alert levels to determine when an<BR>item should be investigated for possible corrective action.<BR>In an event-oriented reliability program, each event on an ETOPS-significant system is<BR>investigated to determine if a problem could be reduced or eliminated by changing the<BR>maintenance program. Examples of events include a failure, removal, or pilot report.<BR>Events can also be monitored to detect long-term trends or repeat items. Not all events<BR>warrant such detailed investigations; continual monitoring and awareness of problem<BR>areas reflects the ETOPS real-time maintenance philosophy.<BR>SUMMARY<BR>Although three- and four-engine Boeing airplanes (as well as some earlier 737s) are not<BR>specifically designed or improved for ETOPS, the ETOPS maintenance approach can be<BR>applied to those airplanes and offer operators significant improvements in reliability,<BR>performance, and dispatch rates. The approach can be applied at minimal cost, which<BR>can later be offset by reduced maintenance costs and other costs associated with<BR>diversions or turn backs..<BR>ETOPS<BR>CFMI Proprietary Information. 75 :victory: :victory: Best practices, Hot Topics, Fleet issues, SB's CFM56-7 AES Handouts 有更详细的资料吗 学习学习!!!! 希望有我需要的东西快快快快快
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