Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 *USAF Declass/Release Instructions On File* TECHNICAL MANUA ORGANIZATIONAL MAINTE CE Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 UNCLASSIFIED -2-4 VOLIE COPY NO. TECHNICAL MANUAL ORGANIZATIONAL MAINTENANCE POWERPLANT (J75P-13) MODELS U-2C AND U-2F AIRCRAFT NOTICE THE DOCUMENT TO WHICH THIS A CHANGE (TMOM -2-4 VOL II) HAS SUPERSEDED TMOM -2-4 VOL II DATED 1 NOVEMBER 1964, CHANGED 8 JANUARY 1965; AND ONLY SECTION -2-4 VOL II OF TMOM -2 ( ) SERIES SUPPLEMENT, DATED 15 FEBRUARY 1965, CHANGED 21 SEPTEMBER 1965. DESTROY SUPERSEDED DATA IN ACCORDANCE WITH AFR 205-1. LATEST CHANGED PAGES SUPERSEDE THE SAME PAGES OF PREVIOUS DATE Insert changed pages into basic publication. Destroy superseded pages. UNCLASSIFIED 22 SEPTEMBER 1965 Approved For Release 2001/08/28 : CIA-RDP751300300R0061-130a5000?127November 1965 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 2-4 VOL II NOTE: The portico of the tent affected by the changes la bode. cased by a vertical line in the Mlle, tnarains of the pose. -1 LIST OF EFFECTIVE PAGES I- loser. Latest Cheesed Popes, Destroy Superseded Poses TOTAL NUMBER OF PAINS IN THIS PUILICATION IS 209 _Ease No. Issue *Title 22 Nov 65 *A 22 Nov 65 Original ii (Blank) Original iii Original iv Original Original vi (Blank) Original 1-1 thru 1-13 Original *1-14 22 Nov 65 1-15 thru 1-29 Original *1-30 22 Nov 65 1-31 thru 1-78 Original *1-79 22 Nov 65 1-80 Original 1-81 18 Oct 65 1-82 thru 1-88 Original *1-89 22 Nov 65 1-90 thru 1-97 Original 1-98 (Blank) Original 1-99 thru 1-195 Original 1 thru 9 Original CONSISTING OF TIN FOLLOWING, ? The asterisk indkates pages changed. added. or deleted by the current change. Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 A Changed 22 November 1965 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 NM NM I= I= MEI =O MN EM MI II= =I MI I I I I I I I I SECURITY CLASSIFICATION I I I I I I SPECIFIC INSTRUCTIONS FOR SAFEGUARDING I I THIS I I MILITARY INFORMATION I I I I I I This document is UNCLASSIFIED. Its dissemination and handling, I I however, will be on an established "need-to-know" basis. By I I direction of the Chief of Staff, USAF, the following policies will I I govern its use, dissemination and handling: I I I I I I This document may be issued to persons possessing I I an established need-to-know. I I I I Strict accountability will be maintained of all copies I issued. I I I I I This document will be controlled in a manner that I will prevent its loss, destruction or its falling into I I the hands of unauthorized persons. I I I I I In the event this document is lost or destroyed, the fact will be I reported to the office of issue and/or to the Commander respon- I I sible for the custody of the material. I I I I I I I I I I I I I I I I I I I I I I I I I I I I I m m m no mi um EN m mi um um gm me um im En nu me mi um ime mu on on NE m ow mumumi Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 INTRODUCTION U-2 This is one in a series of manuals which comprise the Technical Manual of Organizational Maintenance for U-2 aircraft. Each manual in. the series is a complete and separate book prepared in support of a particular system. (Some of these manuals, due to simi- larity or direct interrelation of system functions, contain added sections wherein the associated systems are covered.) c Ma data or anual, or each section within it, is broken down into four parts, cription, Operational Checkout, Trouble Shooting, and Thus, interested personnel are provided with all necessary ational Maintenance. In additi to include useful to qua ? icable, appendices are made part of these manuals, ling with bench adjustments, and other data ? NOTES, CAUTIONS, AND WARNINGS These adjuncts to the text are defined as follows: Note - An operation, procedure, condition, et cetera, which it is essential to emphasize. CAUTION - Operations, procedures, practices, et cetera, which if not strictly observed, will result in damage to or destruc- tion of equipment. LWARNING1 - Operations, procedures, practices, et cetera, which will result in personal injury or loss of life, if not correctly followed. iii Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 iv Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 LIST OF U-2 TECHNICAL MANUALS MANUAL NO. TITLE -2-1 -2-2, -2-3 -2-4 VOL I -2-4 VOL II -2-5 -2-6 -2-7 -2-8 -2-9 General Airplane, Airframe, Landing Gear Flight Controls and Instruments Air Conditioning and Pressurization Powerplant J57 Powerplant J75 Fuel System and Hydraulic System Oxygen System Electrical and Electronics Ground Handling Special Equipment -3-1 Structural Repair Instructions -6-i Inspection Requirements Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : CIR-At+751300300R000100050001-7 VOL II TABLE OF CONTENTS Page Security Classification i/ii Introduction 111 List of IJ-2 Technical Manuals iv POWERPLANT (J75) 1-1 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 v/vi Approved For Release 2001/08/28 : ClAfD4P751300300R000100050001-7 VOL II POWERPLANT J75 CONTENTS DESCRIPTION Page No. Engine 1-5 Intake Air System 1-17 Engine Instruments 1-18 Engine Mounting System 1-26 Engine Starting System 1-29 Throttle Control System 1-31 Fuel System 1-33 Ignition System 1-49 Exhaust System 1-58 Lubrication, Scavenge and Breather System 1-59 OPERATIONAL CHECKOUT Engine 1-75 Engine Instruments 1-82 Fuel System 1-88 Ignition System 1-95 TROUBLE SHOOTING Engine 1-99 Engine Instruments 1-111 Engine Starting System 1-113 Ignition System 1-115 MAINTENANCE Engine 1-117 Engine Pressure Ratio System 1-166 Engine Starting System 1-167 Throttle Control System 1-169 Fuel System 1-171 Ignition System 1-176 Exhaust System 1-180 Lubrication, Scavenge and Breather System 1-183 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-1 Contents Approved For Release 2001/0E/4 : CIA-RDP75600300R000100050001-7 VOL II LIST OF ILLUSTRATIONS Figure Title Page No, 1-1 Cutaway of J75 Engine 1-6 1-2 Major Engine Components (Typical) 1-7 1-3 Dual Rotor Type Engine Reference Stations 1-9 1-4 Engine Airflow (Typical) 1-11 1-5 Accessory Location 1-15 1-6 Engine Tachometer Indicating System 1-19 1-7 Exhaust Gas Temperature Indicating System 1-21 1-8 Engine Oil Pressure Indicating System 1-22 1-9 Engine Oil Temperature Indicating System 1-24 1-10 Engine Pressure Ratio Indicating System 1-25 L-11 Engine Mount Installation (Sheet 1) 1-27 1-11 Engine Mount Installation (Sheet 2) 1-28 1-12 Engine Pneumatic Starter 1-30 .L-13 Throttle Control System 1-32 1-14 Engine Fuel System 1-34 1-15 Engine Fuel Pump 1-37 1-16 Fuel Control (Sheet 1) 1-38 1-16 Fuel Control (Sheet 2) 1-39 1-17 Fuel Control Schematic (Normal System Operation) 1-41 1-18 Fuel Control Schematic (Emergency System Operation) ^ ? ? 1-44 1-19 Fuel Pressurizing and Dump Valve 1-48 1-20 Normal and Continuous Ignition System Block Diagram ? ? 1-49 1-21 Normal and Continuous Ignition System Simplified Wiring Diagram 1-50 1-22 Normal and Continuous Ignition System Schematic .1-52 1-23 Normal System Sparkigniter 1-54 1-24 Continuous Duty Sparkigniter 1-57 1-25 Lubrication, Scavenge, and Breather System Schematic . ? ? 1-60 1-26 Main Oil Pump 1-63 1-27 Main Oil Strainer 1-65 1-28 Air-Oil Cooler Schematic, 14-Inch (Left-Hand Installation) 1-66 1-29 Thermostatic Temperature Control Valve 1-67 1-30 Thermostatic Temperature Control Valve Schematic 1-69 1-31 Air-Oil Cooler Schematic, 9-Inch (Right-Hand Installation) 1-70 1-32 Fuel-Oil Cooler 1-71 1-33 Fuel-Oil Cooler Schematic 1-72 1-34 Breather Pressurizing Valve Schematic 1-73 1-35 Temperature Measurement 1-85 1-2 Approved For Release 2001/08/28 : CIA-RDP75B00300R000100050001-7 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 VOL II LIST OF ILLUSTRATIONS (CONT'D) Contents Figure Title Page No. 1-36 Typical Trim Sheet 1-93 1-37 Engine Part Power Trim Curve 1-94 1-38 Removal of Flexible Preservation Container from Engine While Mounted on Transportation Trailer (Sheet 1) 1-128 1-38 Removal of Flexible Preservation Container from Engine While Mounted on Transportation Trailer (Sheet 2) 1-129 1-39 Engine Transportation Trailer 1-130 1-40 Engine Buildup (Sheet 1) 1-133 1-40 Engine Buildup (Sheet 2) 1-134 1-40 Engine Buildup (Sheet 3) 1-135 1-40 Engine Buildup (Sheet 4) 1-136 1-41 Transfer of Engine from Transportation Trailer to Installation Trailer 1-139 1-42 Engine Quick Disconnect Points (Sheet 1) 1-143 1-42 Engine Quick Disconnect Points (Sheet 2) 1-144 1-42 Engine Quick Disconnect Points (Sheet 3) 1-145 1-43 Removal of Engine from Airplane (Sheet 1) 1-146 1-43 Removal of Engine from Airplane (Sheet 2) 1-147 1-43 Removal of Engine from Airplane (Sheet 3) 1-148 1-43 Removal of Engine from Airplane (Sheet 4) 1-149 1-44 Installation of Engine in. Airplane (Sheet 1) 1-153 1-44 Installation of Engine in Airplane (Sheet 2) 1-154 1-44 Installation of Engine in Airplane (Sheet 3) 1-155 1-44 Installation of Engine in Airplane (Sheet 4) 1-156 1-45 Installation of Flexible Preservation Container on Engine While Mounted on Transportation Trailer (Sheet 1) 1-164 1-45 Installation of Flexible Preservation Container on. Engine While Mounted on Transportation Trailer (Sheet 2) 1-165 1-46 Inspection of Starter 1-169 1-47 Inspection of Sparkigniter 1-179 1-48 Tailpipe Installation 1-181 1-49 Servicing of Oil Tank 1-185 1-50 Cleaning of Main Oil Strainer 1-189 1-51 Oil Pressure Relief Valve 1-191 LIST OF TABLES Table Title Page No. 1-1 Generator Speed versus Engine Speed 1-16 1-2 Fuel System Components 1-35 1-3 Lubrication and Breather System Components 1-62 1-4 Engine Operational Check Limits 1-80 1-5 Engine Overtemperature and Overspeed Limits 1-81 1-6 Standard Alurn.el Chromel Voltage Scale 1-86 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-3 Contents Approved For Release 2001/08/24 : CIA-RDP75600300R000100050001-7 VOL II LIST OF TABLES (CONTrD) Table Title Page No. 1-7 Corrections for External Reference Junction Temperature 1-87 1-8 Torque Values for Nuts, Bolts, and Screws 1-119 1-9 Torque Values for Flexible Tube Connections 1-119 L-10 Torque Values for Hose, Tube and Threaded Connections 1-120 1-11 Torque Values for Crush Type Asbestos Filled Gaskets 1-121 :L-12 Torque Values for Steel Pipe Plugs in Aluminum or Magnesium 1-121 1-13 Special Torques 1-122 1-4 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : GIA-ROP751300300R000100050001-7 VOL II DESCRIPTION 1-1. ENGINE. 1-2. GENERAL. 1-3. The J75P-13 engine (See figures 1-1 and 1-2.) is a continuous flow, turbojet engine incorporating an axial flow compressor, an eight unit canannular combustion chamber and a split three stage reaction turbine. 1-4. The multistage axial flow split compressor consists of an eight stage low pressure unit, which is connected by a through-shaft to the second and third stage turbine wheels, and a seven stage high pressure, high speed unit, which is con- nected by a hollow shaft to the first stage turbine wheel. 1-5. The accessory section is located under the "wasp waist" of the compressor section. 1-6. The tailpipe assembly is attached to the turbine exhaust case and extends to the augmentor assembly. 1-7. SPLIT COMPRESSOR OPERATION. 1-8. Greater flexibility for starting and part load operation is achieved by splitting the compressor into two mechanically separated rotors. Each rotor is driven by separate turbines. The low pressure rotor being free to rotate at its best speed. 1-9. The starter drives but one section, thus reducing the size and weight of the starting system. 1-10. The high pressure rotor is geared to the starter drive because it is the smaller of the two and so requires the lesser torque for starting. 1-11. With the rear or high pressure compressor rotor turning at the governed speed, the front or low pressure compressor rotor is rotated by its turbine at the rpm ensuring optimum flow through the compressor. 1-12. JET ENGINE SYMBOLS AND THEIR MEANING. 1-13. The following list of jet engine symbols (See figure 1-3.) represents most of the more common everyday symbols that you will find used in this text as well as on the flight or maintenance line. Fn net jet thrust, lb N1 low pressure compressor rotational speed, rpm Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-5 L-1?00090001?000t100?0089/dC1U-VIO 8Z/80/1.00Z eseelet1 JOd PeA0AdV 1 COMPRESSOR INLET GUIDE VANES AND SHROUD 2 LOW-PRESSURE COMPRESSOR (EIGHT -STAGE) 3 HIGH-PRESSURE COMPRESSOR (SEVEN-STAGE) 4 COMBUSTION CHAMBER (8) 5 FUEL NOZZLE (6 IN EACH COMBUSTION CHAMBER) 6 TURBINE NOZZLE 7 TURBINE WHEEL, FRONT (ONE, DRIVES HIGH PRESSURE COMPRESSOR) 8 TUBRINE WHEEL, REAR (TWO, DRIVE LOW PRESSURE COMPRESSOR) 9 SWIRL STRAIGHTENER VANE (6.) 10 EXHAUST CONE 11 EXHAUST TAILPIPE (NOT PART OF ENGINE) 10 11 23 22 21 20 19 18 17 16 15 12 EXHAUST GAS TEMPERATURE PROBE 13 TURBINE EXHAUST CASE 14 TURBINE NOZZLE CASE 15 COMBUSTION CHAMBER CASE 16 FUEL MANIFOLD AND NOZZLES 17 DIFFUSER CASE 18 COMPRESSOR INTERMEDIATE CASE 19 ENGINE MOUNT (BALL BAT) 20 ACCESSORY CASE (N2) 21 OIL TANK 22 FRONT COMPRESSOR CASE 23 ACCESSORY CASE (N1) Figure 1-1. Cutaway of J75 Engine uopdTapsoa L-1?00090001.000t100?0089/dati-VIO 9Z/90/1?Oirebseeieu JOd peACLIddV L-1?00090001?000t100?0089/dC1U-VIO 8Z/80/1.00Z eseeleu JOd peAwddv 1 COMPRESSOR INLET GUIDE VANE AND SHROUD 2 FRONT COMPRESSOR CASE 3 COMPRESSOR INTERMEDIATE CASE 4 DIFFUSER CASE 5 COMBUSTION CHAMBERS 6 SPLIT TYPE FUEL MANIFOLD 7 REAR COMPRESSOR ROTOR (Ne) 8 REAR COMPRESSOR CASE 9 FRONT COMPRESSOR ROTOR (Ni) 10 NO.1 BEARING SUPPORT 11 COMBUSTION CHAMBER OUTER CASE 12 TURBINE NOZZLE CASE 13 TURBINE EXHAUST CASE 14 REAR COMPRESSOR TURBINE ROTOR (Ne) 15 FRONT COMPRESSOR TURBINE ROTOR (N1) 16 COMBUSTION CHAMBER OUTLET DUCT 1 2 A 10 Figure 1-2. Major Engine Components (Typical) 15 14 uo TIAT..1 s aa Des cription Approved For Release 200133428 : CIA-RDP75600300R000100050001-7 VOL II N2 high pressure compressor rotational speed, rpm P am ambient absolute pressure Ptl Pt2 Pt3 Pt4 Pt7 total pressure at entrance to inlet duct total pressure at low pressure inlet total pressure at low pressure discharge total pressure at high compressor discharge total pressure at low pressure turbine outlet tam ambient temperature, ?F tt2 temperature at low compressor inlet, ?F Tt2 total temperature at low compressor inlet 111:7 total temperature at low pressure turbine inlet tsfc thrust specific fuel consumption, pound of fuel hour per pound of thrust Wf engine fuel flow, lb/hr 1-14. SYMBOL SUBSCRIPTS. Example - Pt4: Means pressure, but what pressure and where? 4 Means total pressure as differentiated from static pressure Means engine reference station No. 4 (See figure 1-3.) Thus Pt4 means total pressure existing at the discharge of the high compressor. The engine reference station numbers will be among the most common subscripts used. Some more of the common ones are as follows: 1-15. SUBSCRIPTS. am n ambient (tam) burner, combustion chamber (Pb) compressor (77c) exhaust, exit fuel (Wf) static (Ps) total (pt); turbine (77 t) 1-8 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : ClAmINE1751300300R000100050001-7 VOL II Description ? I ; rx1 LOW PRESSURE COMPRESSOR BURNER TAIL- PIPE am 2 3 4 5 6 8 REFERENCE STATIONS It is customary in the jet engine field to utilize engine reference stations when wishing to indicate the characteristics of the many aerodynamic or thermodynamic variables at a specific point in the air's progress through the engine. The standard location of these reference stations, for dual rotor type axial flow compressor jet engines, are shown above. Figure 1-3. Dual Rotor Type Engine Reference Stations Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-9 Description Approved For Release 20011081/28 : CIA-RDP75600300R000100050001-7 VOL II 1-16. ENGINE AIRFLOW. 1-17. Air enters the engine (See figure 1-4.) through the compressor inlet guide vane and shroud assembly (1). Air from this source enters the front compressor (2), which consists of eight rotor stages and seven vane stages. The gas path of this compressor has an increasing inside diameter and a decreasing outside diameter. The front compressor provides initial compression of air. 1-18. The compressor intermediate case (4) separates the front compressor (2) from the rear compressor (3). Inlet vanes (8th stage) direct compressed air from the front compressor (2) to the rear compressor(3). 1-19. The rear compressor (3) has seven rotor stages and six vane stages. The gas path of this compressor has an increasing inside diameter, and a constant outside diameter. As the air passes through, it increases from low velocity to high velocity. 1-20. The diffuser case (5) serves to diffuse the air flow discharged by the rear compressor and adapt it for entry into the combustion chambers. The exit guide vanes, mounted in the air stream in the forward part of the case, accomplish diffusion and widening of the air passage formed by the inner inlet duct. The inner diameter of the case diverts the air to the combustion chambers for burning. 1-21. Most of the highly compressed air discharged from the front and rear com- pressors passes into the combustion section, there it combines with fuel from the nozzles to form a combustible fuel-air mixture. When the fuel-air mixture is ignited, the exhaust-gases are heated and accelerated, then discharged into the turbine section. As the gases leave the turbine, their pressure forces them at very high speeds through the Jet nozzles at the rear of the engine producing reactive thrust. 1-22. From the combustion chambers (7), the gases enter the turbines, producing power to drive the front and rear compressors, and fuel pump and accessories. After the gases leave the turbines, their pressure forces them at very high speeds through the Jet nozzle at the rear of the engine. The engines thrust comes from taking a large mass of air in at the front end and pushing it out the jet nozzle at a much higher speed than it had when it entered the front compressor. 1-23. ENGINE BLEED AIR SYSTEM. 1-24. GENERAL. 1-25, Air is bled from the engine primarily for cabin pressurization. Two high pressure bleed ports on the engine are used for this purpose. A high pressure line for hydraulic tank pressurization and fuel tank pressurization is taken off the cabin pressurization line. The maximum pressure available at the high pressure port is 160 psig. 1-40 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 L-1.00090001.000t100?0089/dCIU-VI3 : 8Z/80/1?00Z eseeieu Jod peAwddv 15 A8TH STAGE COOLING AIR 14 13 12 1 COMPRESSOR INLET GUIDE VANE AND SHROUD 9 FRONT COMPRESSOR TURBINE ROTOR 2 FRONT COMPRESSOR ROTOR 10 TURBINE EXHAUST CASE 3 REAR COMPRESSOR ROTOR 11 EXHAUST CONE 4 COMPRESSOR INTERMEDIATE CASE 12 TURBINE NOZZLE CASE 5 DIFFUSER CASE 13 COMBUSTION CHAMBER OUTER CASE 6 FUEL MANIFOLD AND NOZZLES 14 ACCESSORY SECTION ( N Z) 7 COMBUSTION CHAMBERS 15 FRONT COMPRESSOR CASE 8 REAR COMPRESSOR TURBINE ROTOR Figure 1-4. Engine Airflow (Typical) uopdTzosa a Description Approved For Release 2001/0ta8 : CIA-RDP75600300R000100050001-7 VOL II 1-26. ENGINE BLEED AIR MANIFOLD. An engine bleed air manifold, con- structed of corrosion resistant steel tubing is bolted to the engine. The manifold connects to two high pressure bleed air ports on the top right-hand side of the engine diffuser case. These ports come equipped with Pratt and Whitney short bolts, covers, and gaskets. Note To install the bleed air manifold longer bolts must be used. (Refer to Engine Buildup.) 1-27. HYDRAULIC TANK PRESSURIZATION. The high pressure bleed air system of the engine is used to pressurize the hydraulic tank. A quarter inch tee is plumbed into the high pressure line taken off the cabin pressurization line. From the tee a corrosion resistant steel tube is plumbed to a pressure regulator in the fuselage. For additional information, refer to -2-5 Maintenance Manual. 1-28. FUEL TANK PRESSURIZATION. The fuel tanks are pressurized by engine bleed air through the pressure regulator for level flight and descent conditions, and by air expansion during a climb. The tank pressurization air is taken off the engine compressor bleed line above and aft of the sump tank by a one-half inch steel line. For additional information, refer to -2-5 Maintenance Manual. 1-29. ENGINE COOLING AIR SYSTEM, 1-30. COMPRESSOR AIR. (See figure 1-4.) 1-31. FRONT COMPRESSOR AIR. Cooling air for the rear face of the third stage turbine disc is furnished by the front compressor. Leakage at the rear of the eighth stage compressor blade platform enters the front compressor rotor assembly through holes in the front compressor rear hub. The air then enters the front end of the front compressor drive turbine shaft and passes rearward through the hollow shaft. Cooling air leaves the shaft through holes in the front compressor drive turbine hub. Some of the air is directed past the double air seal on the hub, along the rear face of the third stage turbine disc and mixes with the exhaust gases. The remaining air passes rearward through holes in the No. .6 bearing seal housing flange, the bearing support, and the No. 6 bearing oil suction pump cover flange to the annulus formed by the cover and the No. 6 bearing rear heatshield. Air leaving the rear of the heatshield passes outward to enter holes at the inner end of the No. 6 bearing oil pressure, oil scavenge and breather inner tubes and flows outward along the tubes, leaving by means of holes in the tube heatshields to mix with the exhaust gases. 1-12 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : Clig-BpP751300300R000100050001-7 VOL II Description 1-32. REAR COMPRESSOR AIR. Rear compressor cooling air passes through drilled holes in the twelfth stage compressor stator outer shroud and enters the passage formed by the inner diameter of the necked down portion of the diffuser case and the rear compressor stator outer shrouds. The air then enters holes in the outer ends of the diffuser case struts and flows inward to leave by means of holes at the inner ends of the struts. The cooling air then passes rearward between the combustion chamber inner case and the turbine shafts heatshield. From there it passes through holes in the rear flange of the combustion chamber inner case to the air space between the turbine front bearing seal housing and the turbine seal support. Cooling air for the front face of the first stage turbine disc leaks past the double air seal of the seal support and flows outward along the disc face to mix with the exhaust gases. 1-33. Cooling air for the rear face of the first stage turbine disc and the front and rear face of the second stage disc and the front face of the third stage disc passes between the low compressor shaft and the inner diameter of the first and second stage turbine disc. After the air passes the first stage disc it flows outward past the single air seal of the second stage turbine nozzle to cool the rear face of the first stage disc and past the double air seal on the front face of the second stage disc to cool the front face of the second stage disc. After the air passes the second stage turbine disc, the air flows through the holes in the inner seal between the second and third stage disc. After serving to cool the rear face of the second stage turbine disc and the front face of the third stage turbine disc the air passes outward to mix with the exhaust gases. 1-34. EXTERNAL COOLING AIR. 1-35. ENGINE COMPARTMENT AND AFT SECTION COOLING. The engine compartment and aft fuselage section are cooled by means of flush scoops. a. On U-2C airplanes the flush scoops are located as follows: top engine hoist cover, and left and right-hand engine mount access covers. b. On TJ-2F airplanes the flush scoops are located as follows: upper left and right fairing covers (F.S. 420) and left and right engine mount access covers. 1-36. Additional cooling for the portion aft of the engine burner section is obtained from the oil cooler air scoop on the left-hand side and the hydraulic and oil cooler air scoop on the right-hand side. 1-37. All cooling air is exhausted at the aft end of the airplane, between the augmentor and the tailpipe. 1-38. Heat shields in the upper half of the airplane in the area of the hot section of the engine protect the structure from radiated heat. Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-13 Description Approved For Release 20QVI8128 : CIA-RDP75600300R000100050001-7 VOL II 1-39. AUGMENTOR ASSEMBLY. The augmentor assembly/Part No. 75P1, is located in the aft section of the airplane. 1-40. It is fabricated from corrosion resistant steel and is supported on a bulkhead at the forward end and eight spring clips at the aft end. 1-41. The augmentor is designed to provide pumping of cooling air for aft section as well as cooling for the air-oil cooler during ground running of the engine. 1-42. ENGINE MOUNTED ACCESSORIES. 1-43. GENERAL. 1-44. Engine mounted accessories (see figure 1-5.) are located on the N1 and N2 accessory sections. 1-45. AC GENERATOR. The ac generator is a 208 volts, 400 cps, at 6000 rpm, 3 phase, 30 kva unit, Bendix type 28B54-14A. It is a class C, high temperature, salient pole, brushless generator. 1-46. The ac generator is mounted on an adapter on the centerline of the front accessory section. It is directly coupled to the N1 rotor and is driven at N1 rotor speed. This engine pad gear ratio is 1:1 (N1). Note When installing the generator, no gasket is used between the generator adapter flange and engine pad. 1-47. The ac generator is air-cooled and receives the air through the left-hand boundary layer scoop. A two inch diameter aluminum tube ducts the air aft to the blast cap of the generator. Refer to -2-7 Maintenance Manual for details. I1-48. STARTER. The engine starter is an air turbine type, Model ATS140-29-1, Airesearch Part No. 350520 or Model ATS140-16-1, Airesearch Part No. 210250. 1-49. The starter is mounted on six studs provided on the center pad of the oil pump and accessory drive gearbox. The engine pad gear ratio is 0.823:1 (N2). 1-50. DC GENERATOR. The dc generator installed in J75 equipped airplanes is a Bendix 30B26-21A. It is a 400 ampere generator and is derated at altitude to a maximum of 225 amperes. 1-14 Approved For Release 2001/08/28 : CIA-RDP75B00300R000100050001-7 hanged 22 November 1965 Approved For Release 2001/08/28 : GIARDP751300300R000100050001-7Description VOL II 12 7 8 11 BOTTOM VIEW 10 1. AC GENERATOR 2. STARTER 3. DC GENERATOR 4. GENERATOR ADAPTER 5. ENGINE OIL PUMP ASSEMBLY 6. OIL PUMP AND ACCESSORY DRIVES GEARBOX (N2) 7. TACHOMETER GENERATOR 8. FUEL CONTROL 9. FUEL PRESSURIZING AND DUMP VALVE 10. FUEL PUMP 11. HYDRAULIC PUMP 9 12. FRONT ACCESSORY SECTION (N1) Figure 1-5. Accessory Location Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-15 Description Approved For Release 20011(18/38 : CIA-RDP75600300R000100050001-7 VOL II 1-51. The generator is mounted on a gearbox which is mounted on the left-hand (forward) side of the oil pump and accessory drive gearbox. The mounted gear- box, Part No. 75P29, is used to change the engine pad ratio of 0.433:1 (N2) to 0.866:1 (N2). This provides the necessary step-up in rpm to run the generator. 1-52. There are three Allen head plugs in the engine accessory pad, one in the mounting face, which is the oil supply hole and mates with a hole in the gearbox. The other two are located in the accessory pad recess and are oil return holes which drain into the accessory gear case of the engine. Note Be sure the Allen plugs in the accessory pad oil holes have been removed before installing the gearbox. 1-53. As noted on the nameplate of the gearbox, use only the designated pad gasket between the gearbox and engine accessory pad. This is to ensure that oil will pass from the engine oil system into the gearbox. 1-54. The dc generator is air-cooled and receives the air through a scoop on the bottom just forward of the generator. A two inch diameter aluminum tube ducts the air aft to a flame proof flexible duct which connects to a special blast cap bolted to the generator. 1-55. The generator speed versus the engine speed is given in table 1-1. Table 1-1. Generator Speed versus Engine Speed GENERATOR RPM ENGINE RPM (N2) % RPM (APPROX) 3500 4265 49 4500 5485 63 6200 7560 87 1-56. FUEL CONTROL. The fuel control is a hydromechanical unit manufactured by Hamilton Standard, Model No. JFC-25-15. 1-57. The fuel control is mounted on six studs on the left-hand (aft side) pad of the oil pump and accessory drive gearbox. The engine pad gear ratio is 0.433:1 (N2). Refer to Engine Fuel System for details,' 1-16 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : Cd94DP751300300R000100050001-7 VOL II Description 1-58. FUEL PRESSURIZING AND DUMP VALVE. The fuel pressurizing and dump valve is a pressure operated check valve, manufactured by Pratt and Whitney Aircraft. 1-59. It is mounted with two bolts on the outside of the engine diffuser case at its rear bottom center. Three lines connect to the fuel pressurizing and dump valve and must be disconnected at the time that the valve is being removed. 1-60. ENGINE FUEL PUMP. The fuel pump is a single gear type unit with booster manufactured by Pesco Products, Inc. 1-61, The fuel pump is mounted on six studs on the right-hand (aft) side of the oil pump and accessory drive gearbox. The engine pad gear ratio is 0.433:1 (N2). 1-62. HYDRAULIC PUMP. The hydraulic pump is a variable delivery type with integral flow regulation, controlled by system pressure. 1-63. The hydraulic pump is mounted on six studs on the right-hand forward side of the oil pump and accessory drive gearbox. The engine pad gear ratio is 0.433:1 (N2). The pressure, suction, and bypass connections are made through flexible hoses and disconnect at the pump for engine removal. 1-64, TACHOMETER GENERATOR. The tachometer generator is a two pole alternating current generator, Part No. AN5544-3. 1-65. The tachometer generator is mounted on the left-hand aft side of the oil pump and accessory drive gearbox. The engine pad gear ratio is 0.481:1 (N2) and indicates only the speed of the high pressure compressor rotor. 1-66. INTAKE AIR SYSTEM. 1-67. GENERAL. 1-68. The engine intake air system consists of two branches of air ducting ex- tending from intakes at the sides of the airplane from fuselage station 267 to fuselage station 365 where they converge to form a cylindrical inlet to the engine. 1-69. The interior of the intake ducts is zinc chromated from the aft end of the leading edge to the aft end of the duct. 1-70. COMPONENTS. 1-71. The intake air system is composed of the scoop nose, fuselage station 267 to fuselage station 319, and the duct from fuselage station 319 to fuselage station 365. Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-17 Description Approved For Release 200401428 : CIA-RDP75600300R000100050001-7 VOL II 1-72. The essential differences between the scoop and the duct is one of location; the scoop is outside the airplane and the duct is inside. 1-73. Fuselage station 319 bulkhead is the member which effects the scoop to duct transition. The scoop, being external, has an outside skin which provides fairing over the structural rings in addition to an inside skin which forms an air duct wall. The duct is a simple sheet metal part encircled by rings at a six inch spacing. 1-74. ENGINE INSTRUMENTS. 1-75. GENERAL. 1-76. The engine instruments consist of the tachometer, exhaust gas temperature, engine oil pressure, engine oil temperature, and engine pressure ratio indicating systems. 1-77. TACHOMETER INDICATING SYSTEM. 1-78. The tachometer system (See figure 1-6.) provides a visual indication in the cockpit of the high pressure compressor rotor (N2) rpm in percent of cruise. 1-79. The tachometer generator is engine-driven and supplies the indicator with a continuous signal during engine operation. The strength of the signal varies with rpm, enabling the tachometer indicator to indicate rpm to the pilot. 1-80. Refer to -2-7 Maintenance Manual for electrical circuit wiring diagram. 1-81. TACHOMETER INDICATOR. This indicator is located on the upper right- hand corner of the center instrument panel. It receives a signal from the tach- ometer generator. The signal strength varies as a function of rpm. Indicator calibration is based on the tachometer generator turning at 4200 rpm at 100 per- cent. One hundred (100) percent on the indicator is equivalent to 8730 rpm of (Nz). 1-82. The indicator is composed of a mechanism which gives percentage indi- cations of high pressure compressor rotor speed. The mechanism is enclosed in a hermetically sealed case. 1-83. The instrument has a range of 0 to 110 percent and is driven by a three phase permanent magnet rotor. Electrical connections to the indicator are made at a single mating plug on the unit. 1-84. TACHOMETER GENERATOR. The tachometer generator, AN5544-3 (MIL-G-6027), is a two pole alternating current generator driven by the engine at a maximum speed of 4200 rpm during military operation. The generator supplies a signal to the indicator, enabling the indicator to indicate rpm. It is mounted on the accessory case pad located on the left-hand aft side of the engine. Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-18 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 -2 -4 Description TACHOMETER DETAIL A CENT ER INSTRUMENT PANEL RIGHT SIDE FS 211 FS 252 VOL II i 11 ,,.....".?..... / , -..,... , , , r) , ---? ) .,. -.....,, N.-.. j---............ ., -. , ...2 F:-.'.....%..' .,,''''''''''' ? FS 365 '..--" S 319 \ INSTRUMENT INSTRUMENT PANEL PANEL ml A TACHOMETER GENERATOR C TACHOMETER INDICATOR AppiaVetrFoi-14,1eaFt40.20104/060281PCLA4141BPJZSB00.100R A ''DI>rYrd TACHOMETER GENERATOR (ENGINE) dA01150001-7 1 - 1 9 Description Approved For Release 2001p8428 : CIA-RDP75600300R000100050001-7 VOL II 1-85. The pad gear ratio is 0.481:1 (Nz) high pressure compressor rotor. 1-86. EXHAUST GAS TEMPERATURE INDICATING SYSTEM. 1-87. The thermocouples used in the exhaust gas temperature system (See figure 1-7.) supply a signal to a temperature indicator on the center instrument panel. 1-88. THERMOCOUPLE PROBES. Thermocouple probes (6) are located in the turbine frame just aft of the turbine wheel and are supplied on the engine. A read- ing is obtained of the average temperature of all the thermocouples. The basic system is chromel-alurnel and leads are supplied on the engine to a disconnect point at the lower right-hand side of the main engine access panel, fuselage station 405. From fuselage station 405 disconnect the chromel-alumel leads go forward to fuselage station 252 disconnect and then to the indicator amplifier in the cockpit. 1-89. Refer to -2-7 Maintenance Manual for electrical circuit wiring diagram. 1-90. EXHAUST GAS TEMPERATURE INDICATOR/AMPLIFIER. The indicator/ amplifier is located in the lower right-hand corner of the center instrument panel. The unit provides a means of reading exhaust gas temperature and is calibrated in degrees centigrade times 100 with a range from 0 to 10 . It is a transistorized? servo driven, hermetically sealed unit. A cannon plug on the back of the instru- ment provides connections for chromel and alumel leads. It is a Howell indicator, Part No. BH185R-11B. 1-91. ENGINE OIL PRESSURE INDICATING SYSTEM. 1-92. The engine oil pressure system (See figure 1-8.) consists of a pressure transmitter, Edison Part No. 318-100, and an indicator, Edison Part No. 290-100K. 1-93. OIL PRESSURE TRANSMITTER. The transmitter is mounted on the left side of the engine at approximately fuselage station 419. A flexible line connects the transmitter with the vent port on the Nz case. 1-94. Identification of the vent port is shown on the engine accessory case. 1-95. Refer to -2-7 Maintenance Manual for electrical circuit wiring diagram. 1-96. OIL PRESSURE INDICATOR. The oil pressure indicator, Edison Part No. 290-100K, is located on the right-hand side of the center instrument panel. The range of the indicator is from 0 psi to 100 psi. 1-20 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : CA-RpP751300300R000100050001-7 VOL II DETAR A CENTER INSTRUMENT PANEL RIGHT SIDE FS 211 INSTRUMENT PANEL N 3 9 FS FS 252 FS 365 TO POWER EXHAUST GAS TEMPERATURE FS 508 Des cription ENGINE DISCONNECT TO B/W SYSTEM C-26 FS 252 EGT INDICATOR/AMPLIFIER D-.3 CH AL ,? THERMOCOUPLES Z:\ (EXHAUST GAS TEMP) INVERTER CO BUS 1/2 A C> F E. G. T. TEST (INSTRUMENT PANEL) FS 319 F-2 CH AL E.G. T. THERMO- COUPLES (ENGINE) NOTE E.G. T. THERMOCOUPLES TYPICAL 6 PLACES Figure 1-7. Exhaust Gas Temperature Indicating System Approved For Release 2001/08/28 : CIA-RDP75B00300R000100050001-7 1-.21 Description Approved For Release 2001)8428 : CIA-RDP75600300R000100050001-7 VOL II DETAIL CENTER INSTRUMENT PANEL RIGHT SIDE FS 252 FS 365 7 - FS \\1\ 319 il ) A INSTRUMENT PANEL ? INSTRUMENT TRANSFORMER CIRCUIT BREAKER (EQUIPMENT BAY) Z- 2A CND 1-22 LV 26V AC OIL PRESSURE TRANSMITTER OIL PRESSURE INDICATOR (COCKPIT) INSTRUMENT/ ISOLATION TRANSFORMER (EQUIPMENT BAY) 1 /2A 0B Figure 1-8. Engine Oil Pressure Indicating System OIL PRESSURE TRANSMITTER (ON ENGINE) Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : CIA-4DP751300300R000100050001-7 VOL II Description 1-97. The normal operating pressure range (green arc) is 40 to 55 psi and indicates oil pressure pump discharge pressure. The indicator has red marks at the 35 psi and 60 psi limits. 1-98. ENGINE OIL TEMPERATURE INDICATING SYSTEM. 1-99. The engine oil temperature system (See figure 1-9.) includes an electrical resistance temperature bulb, MS28034-1, (MIL-B-7990) and an indicator, Lewis Engineering Part No. 163B2 (MIL-I-7749). 1-100. OIL TEMPERATURE BULB. The oil temperature bulb is installed in an adapter, Part No. 75P69, which is installed on the right-hand (forward) side of the oil pump and accessory drive gearbox adjacent to the starter. 1-101. Refer to -2-7 Maintenance Manual for electrical circuit wiring diagram. 1-102. OIL TEMPERATURE INDICATOR. The oil temperature indicator, Lewis Engineering Part No. 163B2, is located on the right-hand side of the center instru- ment panel. 1-103. The range of the indicator is from -70?C to +150?C and registers the temperature of the oil entering the engine. The maximum oil temperature (red mark) is 125?C. 1-104. ENGINE PRESSURE RATIO INDICATING SYSTEM. 1-105. The engine pressure ratio system (See figure 1-10.) is designed to give the pilot an indication of power or thrust for all the throttle settings. The system consists of a transmitter and an indicator. The transmitter senses a pressure ratio between engine inlet pressure (Pt2) and exhaust pressure (Pt7) and transmits the ratio of these pressures to an indicator on the center instrument panel. 1-106. ENGINE INLET PRESSURE SENSING (P)*A pressure sensing probe (Pt2), Pratt & Whitney Part No. 533039, is installed in the right side of the corn- pressor inlet case at the 7 o'clock position. A quarter inch steel line is routed aft to the forward side of the N2 accessory case where it crosses over to the left side. At this point a short length of hose (1/4") connects to the airplane portion of the Engine Pressure Ratio System taking it forward to the pressure ratio trans- mitter located on the upper right side of the main wheel well. 1-107. ENGINE EXHAUST PRESSURE SENSING (Pt7). An exhaust pressure sensing manifold containing four probes is located on the outer perimeter of the exhaust case. A five-eighth inch steel line connects to the manifold at the 9 o'clock position and goes forward to the left trunnion (ball bat) position. At this point a short length of hose (3/8") connects to th9 airplane portion of the Engine Pressure Ratio System taking it forward to the pressure ratio transmitter located in the main wheel well. Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-23 Description Approved For Release/2141/08/28 : CIA-RDP75600300R000100050001-7 VOL II OIL TEMPERATURE INDICATOR DETAIL A CENTER INSTRUMENT PANEL RIGHT SIDE N.ss INSTRUMENT PANEL FS 252 FS 65 FS 319 / [OIL TEMPERATURE INDICATOR (COCKPIT) 1-24 FS 211 A ...=?=1????=1M111?Mill OIL TEMPERATURE ? BULB ? LOWER INS T RUMENT PANEL 5A 28V DC Figure 1-9. Engine Oil Temperature Indicating System A OIL TEMPERATURE BULB (ON ENGINE) Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : Ct1-RIDP75B00300R000100050001-7 VOL II Description PRESSURE RATIO INDICATOR DETAIL A CENTER INSTRUMENT PANEL RIGHT SIDE "MAIN I DIAL SYNCHRO 1 ISDUIABL ISYNCHRO A A FS 252 FS FS 365 319 FS 211 PRESSURE RA TIO INDICA TOR (INS TR TJME NT PANEL) D31 TRANSMITTER 6"*.o 115 VAC 400., BQ) IA ENG. PRESS. RATIO 2 S 252 F 1 0 X FS 3 9 TO ENG TO ENG INLET PRESS. EXHAUST PITOT PITOT r 41r1 L _I I_ _i 5- 3- K 4.1????? L 26V4 --J TRANSMIT TER (R SIDE MAIN WHEEL WELL) ApproveAti7elle;g :Pcinbisf56,6660hafittdowayoern 1-25 Description Approved For Release 2004198428 : CIA-RDP75600300R000100050001-7 VOL II 1-108. ENGINE PRESSURE RATIO TRANSMITTER. The pressure ratio trans- mitter, Honey-well Part No. DLG80D1 or FLG80D1, is installed in an insulated container and is mounted on the upper right-hand side of the main wheel well. The transmitter consists of a bellows actuated servoed-ratio-computer, a cam and gear train, an amplifier, a two-phase motor, and a transmitting synchro. The mounting rack has vibration isolators and pressure and electrical connections. 1-109. ENGINE PRESSURE RATIO INDICATOR. The indicator, Honeywell Part No. JG151A6, is mounted on the right-hand side of the center instrument panel. It contains two synchro receivers, a main dial pointer and a subdial pointer. The subdial increases the readability and accuracy capability of the indicator. 1-110. ENGINE MOUNTING SYSTEM. 1-111. GENERAL. 1-112. The engine has mounting provisions (see figure 1-11.) on the compressor intermediate case, turbine case, and the exhaust tailpipe, which consist of side mounts, aft top mount, and tailpipe side mounts. 1-113. COMPONENTS DESCRIPTION. 1-114. SIDE MOUNTS. These are the main load carrying mounts and utilize the socket-type fittings at the left and right sides of the compressor intermediate case. A trunnion (ball bat) is inserted in each socket-type fitting when the engine is mounted in the airplane. The trunnions attach to the airplane at fittings at fuselage station 425. The attachment of each fitting is by means of two clamp- type caps which are held closed by eyebolts. 1-115. These side mounts take inertial and side loads. Provisions for engine expansion (axial load) is also provided in the right side trunnion. 1-116. AFT TOP MOUNT. The aft support consists of a yoke suspended from a fitting fastened to the fuselage ring at fuselage station 509 (top centerline of fuselage). The yoke, in turn, is attached by truss type links to the engine. 1-117. This type mount facilitates engine removal and installation. Vertical adjustment of engine position is made by loosening a locknut and adjusting the position of a rod end fitting in the yoke. The truss type links are attached to this rod end fitting. 1-118. The top mount is capable of takihg only side and vertical loads and also allows for engine expansion rearward. 1-26 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/28 : ClAfr751300300R0001000500017 Description VOL II / / Figure 1-11. Engine Mount Installation (Sheet 1) Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1 -27 Description Approved For Release 200148/28 : CIA-RDP75600300R000100050001-7 VOL II 2 F. S. SECTION D-D LH SHOWN - RH OPPOSITE 509 DETAIL A SIDE MOUNT LH SHOWN - RH OPPOSITE EXCEPT AS SHOWNIN DETAIL E 15 17 18 DETAIL E RH SIDE MOUNT 1-28 19 DETAIL C TAILPIPE MOUNT LH SHOWN - RH OPPOSITE 14 16A 15 DETAIL TOP REAR MOUNT 1 SUPPORT FITTING 2 ENGINE 3 FRONT MOUNT SOCKET 4 3/4-16 BOLT 5 ADJUSTING BOLT 6 EYEBOLT 150 LB IN. TORQUE 7 ENGINE MOUNT CAP 8 LH TRUNNION (BALL BAT) 9 LINK 10 LH REAR ENGINE MOUNT FITTING 11 SUPPORT FITTING 12 REAR ENGINE MOUNT ROD END 13 REAR ENGINE MOUNT YOKE 14 RH REAR ENGINE MOUNT FITTING 15 EYEBOLT (75 LB IN. TORQUE) 16 RH TRUNNION (BALL BAT) 17 TAILPIPE 18 TAILPIPE TRACK NOTE 19 TAILPIPE MOUNT ROLLER A TIGHTEN ADJUSTING BOLTS SUFFICIENTLY TO CREATE ENOUGH FRICTION TO SUPPORT WEIGHT OF TRUNNION AT ANY POSITION TO WHICH IT IS SWUNG MANUALLY. NO SPECIFIC TORQUE REQUIRED. A\ AFTER PROPER ADJUSTMENT HAS BEEN OBTAINED, LOCK SOCKET AND BOLT IN PLACE. (TYPICAL 2 PLACES) /3\ CENTER TRUNNION BETWEEN ENGINE MOUNT LUGS. AFTER ENGINE IS INSTALLED, ROTATE LINKS OUTBOARD AND DOWN TO CLEAR CONTROL CABLES. Figure 1-11. Engine Mount Installation (Sheet 2) Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 Approved For Release 2001/08/284V4-RDP751300300R000100050001-7 VOL II Description 1-119. TAILPIPE SIDE MOUNTS. The tailpipe is supported by the engine and by two rollers at approximately fuselage station 636. 1-120. Due to the long overhang of the tailpipe, a flexible joint is built into it to prevent load pickup from fuselage deflection. As the engine expands due to temperature rise, the rollers move aft in the aft fuselage section support tracks. 1-121. ENGINE STARTING SYSTEM. 1-122. GENERAL. 1-123. The engine starting system (see figure 1-12.) is manually controlled and pneumatically operated. The pneumatic starter is installed on the center accessory pad on the N2 case. An air adapter is attached to the starter inlet port for con- nection of the ground starting equipment. The air from the ground starting equip- ment passes through the nozzle causing the turbine wheel assembly to rotate. An exducer which is a part of the turbine wheel assembly helps exhaust expended air through the outlet port on the forward side of the starter. 1-124. There is an access to the starter area at the underside of the airplane. 1-125. STARTER. 1-126. The pneumatic starter operates on compressed air from a ground source. 1-127. It is mounted on six studs provided on the center accessory pad on the Nz case. The engine pad gear ratio is 0.823:1 (Nz). 1-128. Air is introduced at the bottom of the starter and is directed against the turbine wheel which drives a reduction gear assembly. The starter incorporates an internal - engaging mechanism. This mechanism is composed of a ratchet driven by the reduction gear assembly and a set of spring-loaded pawls attached to the splined starter output shaft. This shaft engages a mating input drive shaft on the engine and rotates when the engine is turning. 1-129. Leading particulars of Airesearch penumatic starter, Part No. 350520, Model No. ATS140-29-1, are as follows: Turbine Type Reduction Gearing Output Shaft Assembly Speed Supply Air Requirements Air Inlet Total Pressure Air Inlet Total Temperature Air Outlet Static Pressure Inward - radial - flow Helical and spur mesh 3300 rpm (min) to 3550 rpm (max) at cutoff speed 45 psi abs (nominal) 288?C (550?F) (nominal) 14.7 psi abs Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-29 Description Approved For Release 2001/4/28 : CIA-RDP75600300R000100050001-7 VOL II Rated Performance of 2840 rpm Output Torque (min) Air Flow (max) Operating Limitations Air Inlet Total Pressure Air Inlet Temperature System Lubrication Oil Capacity Operating Level Operating Temperature Weight 182.5 lb ft. 110.0 lb per min. 60 psi abs (max) 371?C (700?F) (max) Specification MIL-L-23699A or MIL-L-7808 600 cc (Max - approximately) 300 cc (min) 177?C (350?F) (max) 27.5 lb (max) Note Airesearch starter, Part No. 210250, Model No. ATS140-16-1, is Interchangeable with Aires earch starter, Part No. 350520. 1 STARTER NAMEPLATE 5 OUTPUT SHAFT ASSY 2 AIR OUTLET PORT 6 OIL FILLER PLUG 3 BALANCE LINE PORT 7 OIL DRAIN PLUG 4 ELECTRICAL RECEPTACLE (NOT ILLUSTRATED) (NOT USED ON THIS AIRPLANE) 8 AIR INLET PORT 2 1 8 7 6 Figure 1-12. Engine Pneu.matic Starter Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-30 Changed 22 November 1965 Approved For Release 2001/08/28 : CIA-4DR751300300R000100050001-7 VOL II 1-130. OPERATION. Description 1-131. At the beginning of the starting cycle, the ratchet commences rotation, engaging the pawls and transmitting torque to the engine. While the starter, is exerting torque on the engine the pawl and ratchet mechanism will remain in the engaged position. After the engine reaches ignition speed, the starter continues to assist the engine to accelerate until the cutoff speed of the starter is reached. At this speed, the engine overruns the starter and the engaging mechanism ratchets without transmission of torque. When the output shaft reaches pawl throwout speed, the engaging mechanism is completely disengaged, the pawls being thrown outward by centrifugal force so as to clear the ratchet without contact. Note Refer to Operational Checkout Section for starter operational limits. 1-132., THROTTLE CONTROL SYSTEM. 1-133, GENERAL. 1-134. The throttle control system (see figure 1-13.) provides the mechanical motion necessary to operate the throttle arm on the fuel control. It is cable oper- ated by means of a drive pulley below the throttle in the left console in the cockpit. A torque shaft connected to the throttle lever moves the drive pulley. The cables are routed aft along the left side of the fuselage to the power control lever. A short adjustable pushrod connects between the cable system termination and the power control lever. The power control lever operates the throttle arm on the fuel control. 1-135. COMPONENTS. 1-136. THROTTLE LEVER QUADRANT. The throttle lever quadrant is mounted at the forward end of the left console. It is attached to the console and airplane structure by screws and nuts and may be removed and replaced. 1-137. The flap control is also mounted in the quadrant. 1-138. The throttle lever is spring-loaded in the inboard direction so that the forward motion, from OFF will cause it to drop into IDLE without forcing. Throttle lever travel from IDLE to FULL is accomplished by straight forward movement. 1-139. A gate type throttle stop is provided to serve as a limit on takeoff power. This stop will be adjusted to give approximately 93 to 94 percent rpm. In order to go past this stop, the throttle lever must be moved outboard. The device will automatically reset when the throttle is retarded. Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-31 L-1.00090001.000t100?0089/dCIU-VI3 : 8Z/80/1?00Z eseeieu Jod peAwddv FULL 78? OFF FS 252 .0 1.88 @ FULL POWER OFF FUEL CONTROL LEVER ARM 1 5 0 IDLE 10030' --Ai 4) 310 " 9 0 ? FULL POWER 22? 30' VERTICAL CABLE TRAVEL - 3.82 INCHES QUICK DISCONNECTS NOMINAL CABLE TENSION 60 (j.- 5)LB AT 70?F COMPENSATION FOR TEMPERATURE CHANGE a. IF AMBIENT TEMPERATURE IS ABOVE 70?F; ADD 0.35 LB TO 60 LB TENSION FOR EACH DEGREE ABOVE 70. b. IF AMBIENT TEMPERATURE IS BELOW 70?F, SUBTRACT 0.35 LB FROM 60 LB TENSION FOR EACH DEGREE BELOW 70. EXAMPLE: AMBIENT TEMPERATURE = 50?F (20?F LESS THAN 70?-w) 20 x 0.35 = 7 LB. CABLE TENSION AT 50?F = 53 LB Figure 1-13. Throttle Control System uopd-FaDsou Approved For Release 2001/08/28 :_9A4RDP75B00300R000100050001-7 VOL II Description 1-140. THROTTLE LEVER. The throttle lever is mounted in the quadrant on the left side of the cockpit. It actuates the throttle cable system by moving the quadrant torque shaft that, in turn, moves a drive pulley. 1-141. A vernier wheel is installed just inboard of the throttle lever and pro- vides for very small movements of the lever for power adjustment at high altitude. 1-142. Throttle friction may be regulated by a knob located in the center of the vernier wheel on the left side console. 1-143. A toggle switch installed on top of the grip is used to operate the speed brakes. 1-144. A pushbutton switch for the microphone is also installed on the grip. 1-145. The wiring for the grip extends out the bottom, joins with other wiring from the quadrant and connects to a terminal strip at fuselage station 221. 1-146. POWER CONTROL LEVER. The power control lever is installed on the fuel control and rotates through an arc of 90 degrees. Power lever OFF position is set 22 degrees 30 minutes forward of vertical . 1-147. FUEL SYSTEM. 1-148. GENERAL. 1-149. The fuel system (see figure 1-14.) consists of a fuel-oil cooler, main fuel strainer, engine fuel pump, hydromechanical fuel control, fuel flow totalizing transmitter, fuel pressurizing and dump valve, and the fuel manifolds. 1-150. SYSTEM OPERATION. 1-151. Fuel from the aircrafts boost system is delivered to the fuel-oil cooler where it passes through cooling coils to reduce the temperature of the oil. From the fuel-oil cooler the fuel passes through a 60-mesh strainer and into the engine- driven fuel pump. The two-stage pump delivers fuel at predetermined pressures and quantities to the hydromechanical control. 1-152. Due to the characteristics of the engine it is necessary that fuel flow be maintained within certain limits which vary depending upon operating conditions. The variables sensed by the control are those of burner pressure, engine rpm, and compressor inlet pressure. Subject to these variables, the control is capable of accurately maintaining the desired engine rpm during steady state operation by a governor droop system. Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-33 Description \\,..ACCESSORY ... SEC TION (N1) Approved For Release 2001/98 : CIA-RDP75600300R000100050001-7 VOL II ? LOW PRESSURE COMPRESSOR HIGH PRESSURE COMPRESSOR FUEL NOZZLES ? T URBINE EMERGENCY ACCESSORY SECTION (N2) e# ireff Z., #17 Ael' RPM SENSE PT Pb FUEL CONTROL ENG DRIVEN THROTTLE FUEL PUMP FUEL FILTER FUEL PRESS. TRANSMITTER DRAIN INLET sFUEL 1-34 4111` ENGINE COMPARTMENT MINI,???? ] PRESSURIZING AND DUMP VALVE DRAIN FUEL FLOW TOTALIZING TRANSMIT TER AP. COCKPIT FUEL PRESSURE INDICATOR NORMAL H EMER EMERGENCY FUEL CONTROL SWITCH METERED FUEL PRESSURE MEIN SECONDARY FUEL FLOW PUMP DISCHARGE PRESSURE MA"' PRESSURE SENSE (UNMETE RED FUEL) CZ= FUEL CONTROL BODY PUMP INT ERSTAGE PRESSURE RE TURN PRESSURE UM= BYPASS BOOST PUMP PRESSURE ="""*...? FUEL DRAIN PRIMARY FUEL FLOW 0=3:730 DUMP SIGNAL 1:132 GAL FUEL REMAINING COUNTER Figure 1-14. Engine Fuel System Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 DRAIN Approved For Release 2001/08/28 :_glAtRDP751300300R000100050001-7 Description VOL II 1-153. During acceleration and starting, the control senses burner pressure, and engine rpm, and as a result, schedules fuel flow to permit the maximum rate of acceleration allowable within the engine temperature limits without compressor surge while discouraging "rich blow-out". 1-154. During deceleration the fuel control schedules fuel flow as a function of burner pressure to ensure the maintenance of sufficient fuel flow at the minimum flow level to support combustion, thus preventing the condition called "lean die-out". 1-155. Metered fuel from the control passes through a fuel flow totalizing trans- mitter, then into the fuel pressurizing and dump valve. The purpose of this valve is to provide the division of flow between the primary and secondary nozzle orifices to ensure proper fuel atomization. Also incorporated in the fuel pressurizing and dump valve body is a dump valve which drains the fuel manifold at shutdown. Fuel from the pressurizing and dump valve enters the engine fuel manifolds, which provide separate paths for primary and secondary fuel flow, and finally into the 48 duel-orifice nozzles where it is atomized for burning in the combustion chambers. 1-156. Fuel System components are listed in table 1-2. Table 1-2. Fuel System Components NAME PART NO. VENDOR Fuel-Oil Cooler 87880-3 Airesearch Main Fuel Strainers Strainer Assy (200 Mesh) 301385 or 748-1 Airline Welding Prod. Strainer Assy (60 Mesh) 300720 Airline Welding Prod. Engine Fuel Pump 023341-030-038P1 Pesco Fuel Control 597797 Hamilton Standard Fuel Flow Totalizing Transmitter H222 Contractor Fuel Pressurizing and Dump 476828 Pratt & Whitney Valve Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 1-35 Description Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 -2-4 VOL II 1-157. COMPONENTS DESCRIPTION. 1-158. FUEL-OIL COOLER. The fuel-oil cooler, by transferring heat from the engine oil, heats abnormally cool fuel, prevents ice formation in the fuel strainer and fuel control, and provides additional oil cooling at high altitude. For further details refer to the Lubrication, Scavenge, and Breather System. 1-159. MAIN FUEL STRAINERS. One fuel strainer (200-mesh) is located near the outlet of the left-hand sump tank half at approximately fuselage station 389; the other fuel strainer (60-mesh) is located on the right side of the fuselage structure slightly above the fuel-oil cooler. For further details refer to -2-5 Maintenance Manual. 1-160. ENGINE FUEL PUMP (See figure 1-15.) The function of the engine fuel pump is to supply fuel under pressure to the engine fuel system. 1-161. The fuel pump is a high-pressure engine-driven pump consisting of one gear-type pump element and one centrifugal -type booster element combined as a single unit. 1-162. The booster element is located opposite the drive end of the pump and is driven through a step-up gear train. A shear section is incorporated in the centrifugal element drive. 1-163. A No. 40-mesh removable filter is located in the pump body between the discharge side of the booster stage and the inlet side of the gear stage. The filter is designed to bypass fuel in the event of clogging. 1-164. A fuel pressure relief valve is contained in the pump body on the dis- charge side of the gear pump. The pressure relief is adjusted to limit the pres- sure rise of the pump to a maximum pressure of 835 to 845 psi. 1-165. Operation. Fuel enters the booster stage through the pump inlet on the end of the impeller casting where the fuel is boosted approximately 20 psi. The fuel passes through the filter to the inlet side of the main pump and is discharged through the outlet port to the fuel control. Excess fuel from the fuel control is returned to the main pump through the return port and is recirculated within the pump. 1-36 Approved For Release 2001/08/28 : CIA-RDP75B00300R000100050001-7 Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 -2-4 VOL II FUEL INLET FUEL FILTER Description FUEL PUMP DRIVE SHAFT ADAPTER FUEL PRESSURE TRANSMIT TER AND SNUBBER CONNECTION (REMOVE PLUG) FUEL PUMP BODY ? FUEL BYPASS (FROM FUEL CONTROL) ? Figure 1-15. Engine Fuel Pump 1-166. FUEL CONTROL. (JFC-25-15) PRESSURE RELIEF VALVE FUEL OUTLET (TO FUEL CONTROL) 1-167. The fuel control (see figure 1-16.) is a hydromechanical unit designed to meter fuel to the engine. Fuel is metered in the normal system according to a predetermined flow schedule, which varies as a function of the pilot's throttle lever position, burner pressure, and engine rpm. 1-168. The hydromechanical control is made up of hydraulic and mechanical components. The operating forces required within the control are delivered by servos which operate on approximately a 2:1 pressure ratio. 1-169. The fuel control also incorporates a standby emergency control system designed to provide emergency control operation with minimum performance. This system is manually selected by the pilot by means of a toggle switch. When the system is in operation an amber light on the center instrument panel comes on. 1-170. NORMAL SYSTEM OPERATION. (See figure 1-17.) The normal operating system of the fuel control consists of a metering system and a computing system. The metering system alters the fuel supplied to the fuel control by the engine-driven fuel pump to provide the engine thrust output required, but subject to engine oper- ating limitations which are sensed and scheduled by the control computing section. Approved For Release 2001/08/28 : CIA-RDP75B00300R000100050001-7 1-37 Des cription Approved For Release 2001/08/28 : CIA-RDP75600300R000100050001-7 VOL II Pet 0 0 c4 1=1 f=1 Z Z ? fx1 1-1 ?d 0 Z 0 E-1 H (121 0 r-11 qHuZ cf) rxi z 9 Z