DOCSLIB.ORG

Ford Triton V10 Service

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Ford Triton V10 Service Ford Triton V10 Service It looks as though Ford is going to be bringing back the 6.8-liter Triton V10 for 2017. Much to people’s surprise, the V10 actually never stopped production. Many thought that the Triton was no longer available when Ford quit offering the engine as an option for the 2011 Superduty. However, the V10 has been offered as an option for the F450-F750 cab and chassis along with motorhome chassis since 2012. With the introduction of the 6.2-liter V8, the V10 was simply dropped from the Superduty line. The V10 has been an option for the Ford truck chassis since 1997. With the elimination of the 385 series 460-cubic-inch big block, Ford offered the V10 as a diesel alternative. The V10 is a part of Ford’s modular family, and is actually identical to the 5.4-liter SOHC with a 3.552˝ bore and 4.165˝ stroke with the addition of two cylinders. The two-valve version, which produced 310 horsepower and 425 ft.-lbs. of torque, was offered on 1997 through 2004 models. The three-valve version was offered on model year 2005 through present vehicles with 360 horsepower and 457 ft.-lbs. of torque. The crankshaft is unique with a split pin for 72° firing intervals (with a firing order of 1-6-5-10-2-7-3-8-4-9) and a balance shaft placed in the driver’s side cylinder head to help in dampening vibrations. With a life expectancy of 300,000-plus miles, the V10 has offered great service and reliability. These engines are reasonable to rebuild and have a variety of aftermarket parts available for them. One thing to keep in mind would be the initials “PI” cast into the cylinder heads. These initials stand for “Performance Improvement.” Early versions of this engine from 1997 until 1999 were considered “Non-PI.” The PI versions started in 2000 and incorporated changes to the cylinder head and intake manifold, which resulted in significant power gains for the engine. The intake manifold and cylinder heads of PI engines will not interchange with Non-PI engines due to differences in port design. ford-triton-balance-shaft The balance shaft in the Triton V10 is placed in the top of the driver’s side cylinder head above and is driven by the camshaft. Cylinder Heads The F7VE head, known as a Non-PI version, was produced from 1997 until 1999. These have rounded intake ports with an open-style combustion chamber with one intake valve and one exhaust valve. The YC2E head was produced from 2000 until 2001 and is known as a PI version. It has somewhat of a square-shaped intake port with more of a closed-style combustion chamber that offered a small compression ratio change. Also, it has one intake valve and one exhaust valve. The 1C2E was produced from 2002 until 2004 and known as a PI version. It has the same head as the YC2E with differences in the spark plug threads. The 1C2E cylinder head is often referred to as a LP, which stands for “long plug.” These heads had revisions to the spark plug threads because Ford had issues with the Modular engines (meaning the 4.6 liter and 5.4 liter) prior to this that would blow the spark plugs out. The problem was that there were not enough threads holding the spark plugs in the cylinder heads. Over a period of time, the spark plugs would work loose and then blow out, stripping the threads from the cylinder head. There is a service tool and procedure for the prior cylinder heads that will ream the stripped spark plug hole to allow for a new threaded insert for the spark plug. The 5C3E was produced from 2005 until 2007 and signaled the introduction of the three-valve version. This head had two intake valves and one exhaust valve. The spark plugs changed to a different design for the three-valve combustion chamber. The intake ports are an oval shape for the split port design of the two intake valves. The 9C3E is the latest head (produced from 2008 until present) and is very similar to the 5C3E except for a smaller combustion chamber that results in a small compression change. From 1997 until 2005, the two-valve cylinder heads used a spark plug with a 14 mm thread, an 18 mm reach and a 5/8˝ hex. The valve diameters were 44.5 mm for the intake valve and 36 mm for the exhaust valve. From 2005 until present, the three-valve cylinder heads used a spark plug with a 12 mm thread, 26.5 mm reach and a 9/16˝ hex. The valve diameters were 34 mm for the two intake valves and 37.5 mm for the one exhaust valve. Head bolts are torque-to-yield (TTY), meaning for one-time use. The two-valve and three-valve versions require different part numbers for replacement head bolts. Engine Blocks The blocks follow the same evolution as the heads. The biggest change was the 1C3E block that was in production from 2001 until 2003. It was produced for PI cylinder heads and had knock sensor bosses in the engine valley. Keep in mind that you may find that some blocks will have the knock sensor bosses machined and some will not be machined. The 3C3E block was in production from 2003 until 2005, it was produced for the PI cylinder heads and should have machined knock sensor bosses in the valley of the engine, as would all later models. The PI cylinder heads used a PI intake, which had a shallow plenum versus the Non-PI intakes. The Non-PI heads cannot be used with latest version block because the deep plenum of the intake will hit the knock sensor bosses in the valley of the engine. There are various types of intakes for these engines based on their applications. Some intakes are aluminum and some are plastic. There are differences in designs used between truck and van applications. The important thing to remember is there is not only a difference in port designs for Non-PI, PI and three-valve versions, but also for the depth of the plenum. Chains and Tensioners The timing chains and tensioners were the same for all years of production. Non–PI engines produced from 1997 until 1999 take a different camshaft from the PI versions produced from 2000 until 2005. The three-valve-per-cylinder versions produced from 2005 until present also required a different camshaft. Keep in mind which version you have when purchasing a new camshaft and remember that there are separate part numbers for the left-bank and right-bank camshafts. Oil Pump The same gerotor-style pump was used for all years of production. In June 1996, Ford manufactured the first Triton 6.8-liter V10 at the Windsor Engine Plant. The Triton V10 was added to the same production line as the 4.6- and 5.4-liter engine because they all could be built on the same line..
Load more

Recommended publications
  • Mike Mavrigian Special Firing Order Camshafts Allow the Performance
    Performance Perspectives Special firing order camshafts allow the performance engine builder to create a smoother-running engine, with improved fuel distribution and enhanced crankshaft and main bearing durability. his article falls under the category for the same reasons...to smooth out the harmon- of “thinking outside the box.” It’s a ics in the pursuit of greater engine durability and trite phrase, I know, but the point to potentially generate more power. is that we don’t need to always Power gain potential aside, the primary reason think of an OE carmaker’s engine to address (and alter) cylinder firing order is to Mike firing order specification as gospel. achieve a smoother-running engine (a smoother, Mavrigian In certain racing applications, a special firing or- more lineal acceleration ramp), with less harmonic Tder (SFO) camshaft can be used as a tuning aid, effect (and crank deflection) on the crankshaft and [email protected] allowing the competition engine builder to fur- its main bearings. In theory, virtually all engines can ther address combustion heat and crankshaft dis- benefit from this. The engines that can most bene- turbance (harmonic) issues. fit include those that run at or near peak rpm levels In essence, the goal in changing the firing or- for long periods of time, such as oval track, road der is to create a smoother-running engine and race and marine engine applications, as well as en- more even fuel distribution, with enhanced gines that are called upon to produce maximum crankshaft and main bearing durability. In the power in a very short period of time (drag race).
    [Show full text]
  • MX-13 MX-13 Coach & Bus Engine Coach & Bus Engine
    MX-13 MX-13 Coach & Bus engine Coach & Bus engine DAF Components Hugo van der Goeslaan 1 P.O Box 90065 5600PT Eindhoven The Netherlands www.dafcomponents.com [email protected] Tel. +31 (0)40 21 43 293 ISO14001 ISO/TS16949 Environmental Quality Management System Management System No rights can be derived from this publication. DAF Trucks N.V. reserves the right to change product specifi - cations without prior notice. Products and services comply with the Global Directives effective at the time of sale but may vary depending on the country in which you are located. For the most recent information, contact DW143203/0919 DAF Components. A PACCAR COMPANY DRIVEN BY QUALITY DAF COMPONENTS MX-13 Coach & Bus engine The 12.9 Litre PACCAR MX-13 engine uses state of the A well-controlled and further optimized combustion MX-13 ENGINE art technologies, fi rst class materials, extensive function process using smart dosing controls and modulating fuel No. of cylinders and cylinder arrangement 6 in line, vertical integration and a heavy duty foamed wire loom to achieve line pressure assures highest effi ciency and lowest fuel Valves 4 highest reliability and durability. Excellent torque at low consumption ever. Repair & Maintenance costs have been Bore x Stroke [mm] 130 x 162 engine speeds and a high performance is available over a cut as well by extending intervals and increased uptime. Piston displacement [dm3] 12.9 wide rev. range. The best engine has become even better. Compression ratio 18,5 : 1 The engine is available in Euro 6, Euro 5 and Euro 3 Aspiration Turbocharged with charge cooling versions.
    [Show full text]
  • Performance Camshafts
    PERFORMANCE CAMSHAFTS Street or strip, Engine Pro Performance Camshafts simply out perform the competition. Our manufacturing accuracy promotes improved valve train stability resulting in improved power gain. Our “controlled ramp” lobe profiles offer acceleration rates extending valve train life while delivering maximum horsepower. • Ground in the U.S.A. 100% American Made Castings and Billets • Manganese Phosphate Coated, Flame Hardened Castings or Induction Hardened Billets CAMSHAFT RANGE & SELECTION CHART • Computer Designed Lobe Profiles for Maximum Power • Profiles are Adcole Verified for the Ultimate in Accuracy SEE INDIVIDUAL LISTINGS FOR MORE INFORMATION • Journal Roundness Maintained to Within .0002” STAGE 1 CHARACTERISTICS RECOMMENDATIONS CAMSHAFT APPLICATION CHART IDLE QUALITY: SMOOTH STOCK TOWING: GOOD FOR PULLING HEAVY LOADS NOTES: TORQUE: IMPROVED LOW END, RACING: NOT RECOMMENDED COMMENTS 1600-2000 RPM COMPUTER MODIFICATIONS NOT NEEDED MECH/ DUR @ .050” ADV. DUR. VALVE LIFT LOBE SEP POWER LIFTER BELOW FUEL ECONOMY: YES CONTROLLED PART # HYD STAGE INT EXH INT EXH INT EXH INT EXH RANGE IDLE PART# PART # VEHICLES: AMERICAN MOTORS V8, 1966-92 TRANSMISSION: STOCK AUTOMATIC OR MANUAL 290, 304, 343, 360, 390, 401 C.I. DURATION @ .050’’: COMPRESSION MC1786 HYD 2 204 214 280 290 .448 .472 105 115 1500-4000 SMOOTH 2011 B, D UP TO 195 HYDRAULIC RATIO: 9.0:1 OR LESS COMMENT: GOOD AND LOW MID RANGE TORQUE AND PULLING POWER BUICK V6, 1978-88 STAGE 2 CHARACTERISTICS RECOMMENDATIONS 181, 196, 231, 252 C.I (EVEN FIRE W/INTEGRAL DIST. DRIVE GEAR) MC1731 HYD 1 194 204 270 280 .424 .448 109 119 1000-5000 SMOOTH 969 B IDLE QUALITY: SMOOTH TOWING: GOOD FOR LIGHT PULLING AND RV USE COMMENT: GOOD MILEAGE.
    [Show full text]
  • Modeling and Simulation of Airflow Dynamics in a Dynamic Skip Fire
    Downloaded from SAE International by Mark Wilcutts, Tuesday, February 02, 2016 Modeling and Simulation of Airfow Dynamics in 2015-01-1717 a Dynamic Skip Fire Engine Published 04/14/2015 Li-Chun Chien, Matthew Younkins, and Mark Wilcutts Tula Technology Inc. CITATION: Chien, L., Younkins, M., and Wilcutts, M., "Modeling and Simulation of Airfow Dynamics in a Dynamic Skip Fire Engine," SAE Technical Paper 2015-01-1717, 2015, doi:10.4271/2015-01-1717. Copyright © 2015 SAE International Abstract Over the years, a number of skip-fre engine control arrangements have been proposed which do not simply switch back and forth to Dynamic skip fre is a control method for internal combustion reduced cylinder sets. Förster et al [5] described use of a relatively engines in which engine cylinders are selectively fred or skipped to large number of fxed cylinder fre-skip patterns but did not describe meet driver torque demand. In this type of engine operation, fueling, how the fxed patterns could be switched in order to effectively and possibly intake and exhaust valves of each cylinder are actuated achieve smooth torque delivery in practice. on an individual fring opportunity basis. The ability to operate each cylinder at or near its best thermal effciency, and to achieve fexible In contrast to these strategies, Tula Technology's Dynamic Skip Fire control of acoustic and vibrational excitations has been described in (DSF) considers activation or deactivation of each cylinder event previous publications. independently, varying the density frings as driver demanded torque changes. Figure 1 shows the simple concept of using density of Due to intermittent induction and exhaust events, air induction and cylinder frings to produce a driver-demanded torque.
    [Show full text]
  • Firing Order Firing Order
    Firing order Firing order: The firing order is the sequence of power delivery of each cylinder in a multi-cylinder reciprocating engine. This is achieved by sparking of the spark plugs in a gasoline engine in the correct order. Or by the sequence of fuel injection in a diesel engine. When designing an engine, choosing an appropriate firing order is critical to minimizing vibration and achieving smooth running, for long engine fatigue life and user comfort, and heavily influences crankshaft design. ماحوظة: عند ترتيب اﻻسطوانات لﻻحتراق يجب عدم جعل ترتيب الحريق بالتتابع لترتيب اﻻسطوانات فى المحرك و ذلك: •ليتم توزع الحراره على اجزاء المحرك كلها وﻻ تذداد فى جزء عن اﻻخر. •ليتم توزيع الضغط فى المحرك على عمود المرفق فﻻ يؤدى الى احداث اهتزاز كبير فى المحرك. In case of 4 cylinder engine: the four crankpins are in one plane, 180o opposed. Since two pistons each are at the extreme position, the inline design permits following firing orders: 1-3-2-4 or 1-3-4-2 In case of 6 cylinder engine: the crankpins are in one plane, 120o apart. The inline design permits following firing orders: 1-5-3-6-2-4 or 1-4-2-6-3-5 Comparison of SI and CI Engines: NO Description SI Engine CI Engine 1 Basic cycle Operated on Otto cycle. Operated on Diesel cycle Gasoline fuel, highly volatile fuel and self Diesel, on- volatile, lower self ignition 2 Fuel Used ignition temperature temp. A gaseous mixture of fuel and air is introduced Fuel is injected inside the cylinder at high during suction stroke.
    [Show full text]
  • FIRING ORDER Ignition Firing Order Is
    FIRING ORDER !"#$%#&%'()*+*),-.(-%&- /0"12$(*#(%3)%&&,4%(5%*'("6(7'%*8%'(+",#-&(7%(%3+%',%#)%$9()0%)8(-0*-(-0%()"#$%#&%'()*+*),-.(,&(#"-(2"5%' Ignition firing-0*#(:;<:( orderȝ=(,;%;(%4%'(<:>(2%&&(-0*#(,-&('*-%$()*+*),-.(?:;<@( is: 1-3-4-2. Check it threeȝ=A(B*'8%$("#(-0%()"#$%#&%'(7"$.; times, then check it again. Rotate the engine to TDC on #1 power stroke (cam lobes point outwards and valves closed). The distributor rotor should point to #1 spark plug wire terminal on the distributor cap and the C7a CHECKING THE DISTRIBUTOR (Marelli S 103 B or S 103 BA) AND THE IGNITION TIM- rotorING should be pointed toward the front of the car. Then move clockwise around the distributor cap checking that the wires are in the same 1-3-4-2 order. Dwell meter should read between 57 and 63 degrees, with new points closed, corresponding to .017 to .019’ (.43 to .48 mm) gap. Smear the distributor cam with grease. Check the inside of distributor cap IGNITIONfor any sign TIMING of moisture, carbon deposits or cracks and the central power electrode for free movement in its seat and for effective spring action. The Finallyignition check timing cap should terminals be checkedfor good whenconditions. the engine is warmed up to operating temperature (coolant exceeding 158°F; 70°C) by using a timing light. IGNITION TIMING At idleThe speedignition the timing timing should should be bechecked 5 to 7 when degrees the engineATDC, is that warmed is the up markto oper- “F” on the pulleyating should temperature be in line (coolant with theexceeding pointer 158°F; or .04” 70°C) (1 mm) by using apart a eithertiming side.
    [Show full text]
  • Number of Cylinders
    tgn tions Name: Date: Instructor: Textbookpages 162*181 Objective: After studying this chapter, you will be able to describe and explain basic automotive engine designs and classifications. Cylinder Arrangement 1. Define cylinder arrangement. 2. Name the five basic cylinder arransements. 3. The cylindersof a(n) _ engineare lined up in a singlerow. --). 4. A(n) _ enginehas only one bank of cylinders. 4. 5. Cylinders of a(n) _ engine lie flat on either side of the crankshaft. 5. Number of Cylinders 6. Normally, car and truck engineshave either _ cylinders. 6. (A) 4, 5, or 6 (B) 2,4, or 6 (:C) 4,6, or 8 (D) 6, 10,or 12 7 . A greaternumber of cylinders generally (increases/decreases)engine 7. smoothnessand power. 8. A(n) _ cylinder engine produces twice as many power strokes per 8. crank revolution as a(n) _ cylinder engine. (A) 3, 8 (B) 8,4 (c) 6,r0 (D) None of the above. Copyright by Goodheart-WillcoxCo., Inc. 5t 52 Modem Automotive TechnologyWorkbook Cylinder Numberingand Firing Order 9. Why do engine manufacturersnumber each engine cylinder? 10. cylinder numbersare normally stamped on an engine's_ rodsor they 10. are sometimescast into the 1i. Definey'ring order. 12. When is it important to know an engine's firing order? CoolingSystem Tlpe 13. Explain how a liquid cooling systemoperates. 14. _cooled enginesare seldomused in passengercars. 14. 15. An air cooling systemcirculates air over _ on the cylinders to prevent 15; overheating. Fuel Dpe 16. An enginecan be classifiedby the type of_ it burns. 16. 17. Name at least three types of fuels used in automotive engines.
    [Show full text]
  • IO-720 Operator's Manual
    Operator’s Manual Lycoming IO-720 Series Approved by FAA 4th Edition Part No. 60297-19 October 2006 652 Oliver Street Williamsport, PA. 17701 U.S.A. 570/323-6181 IO-720 Series Operator’s Manual Lycoming Part Number: 60297-19 ©2006 by Lycoming. All rights reserved. Lycoming and “Powered by Lycoming” are trademarks or registered trademarks of Lycoming. All brand and product names referenced in this publication are trademarks or registered trademarks of their respective companies. For additional information: Mailing address: Lycoming Engines 652 Oliver Street Williamsport, PA 17701 U.S.A. Phone: Factory: 570-323-6181 Sales Department: 570-327-7268 Fax: 570-327-7101 Lycoming’s regular business hours are Monday through Friday from 8:00 AM through 5:00 PM Eastern Time (-5 GMT) Visit us on the World Wide Web at: http://www.lycoming.com LYCOMING OPERATOR’S MANUAL ATTENTION OWNERS, OPERATORS, AND MAINTENANCE PERSONNEL This operator’s manual contains a description of the engine, its specifications, and detailed information on how to operate and maintain it. Such maintenance procedures that may be required in conjunction with periodic inspections are also included. This manual is intended for use by owners, pilots and maintenance personnel responsible for care of Lycoming powered aircraft. Modifications and repair procedures are contained in Lycoming overhaul manuals; maintenance personnel should refer to these for such procedures. SAFETY WARNING Neglecting to follow the operating instructions and to carry out periodic maintenance procedures can result in poor engine performance and power loss. Also, if power and speed limitations specified in this manual are exceeded, for any reason; damage to the engine and personal injury can happen.
    [Show full text]
  • Guidelines to Engine Dynamics and Vibration
    The Ship Power Supplier Guidelines to engine dynamics and vibration by Hannu Tienhaara Technology Wärtsilä Corporation In recent years shipyards and shipowners have increasingly Vibration response tuned in to the negative consequences of engine vibrations. As this article will make clear, there are three important factors contributing The pressure on engine manufacturers to improve vibration to the vibration levels and behaviour of an engine and its components. behaviour has increased, which has also driven the development and use of advanced vibration analysis and 1. A rigid body motion of the engine on its flexible mounting simulation methods. The challenge is to keep vibrations on an The engine is moving as a solid part, sometimes causing problems with acceptable level while output power increases and structures connections. become lighter. A piston engine is, by its nature, a vibrating 2. Deformation of the engine block (global vibrations) machine. To keep vibrations under control it is essential to When in resonance, this causes high stresses that might lead to failures. understand the basics and the main sources of engine 3. Local vibrations of a component vibrations. Vibrations of a component with respect to its mounting. Structural vibration is generally a result of the exciting force and dynamic It is not always easy to distinguish the global and local vibrations based on properties of the structure (Figure 1). The same analogy can be used for any simple overall measurements. The contribution of the flexible mounting is vibrating system. easy to detect, but rigid body modes are of minor importance for most In modern engine development work all these different components - constructions because they cause only small deformations and stresses.
    [Show full text]
  • Edelbrock 5021 Intake Manifold Installation Instructions
    TORKER II INTAKE MANIFOLD For Ford 289-302 C.I.D. V8 Engines Catalog #5021 INSTALLATION INSTRUCTIONS PLEASE study these instructions carefully before beginning this installation. Most installations can be accomplished with common tools and procedures. However, you should be familiar with and comfortable working on your vehicle. If you do not feel comfortable performing this installation, it is recommended to have the installation completed by a mechanic. If you have any questions, please call our Technical Hotline at: 1-800-416-8628, 7:00 am - 5:00 pm, Pacific Standard Time, Monday through Friday or e-mail us at [email protected]. • MANIFOLD: The Torker II manifold is designed for 289/302 c.i.d. small-block Ford V8 engines, and is recommended for street high performance and race vehicles only. The Torker II manifold is of single-plane design utilizing modern air flow technology. It provides good low rpm response plus increasing performance above the 5000 rpm range. It also provides horsepower and torque increases within the listed rpm range when used with any mix of aftermarket equipment available for vehicles operating within that range. Will not fit 255 c.i.d. Ford V8. Manifold height: same as OEM. • EGR SYSTEM: This manifold will not accept stock EGR (exhaust gas recirculation equipment). EGR systems are used on most 1972 and later model vehicles. Check local laws for requirements. • ACCESSORIES & INSTALLATION ITEMS: Major recommendations are listed below. See our catalog for details. To order a catalog, call (800) FUN-TEAM,
    [Show full text]
  • Ford V8 Engines
    Chapter Eight Ford V8 Engines The 302 cid and 351 W cid Ford engines are The oil pump is located on the bottom front of lightweight, small block V8 designs. Both use a 4 the block and is driven by the distributor through in. bore; the 302 cid has a shorter stroke than the an intermediate shaft. 35 1 W. The 2 engines are closely related in design, Figure 1 shows the internal components typical but the 351 W has a taller block with longer of the 302 and 351W engine. pushrods and connecting rods. Specifications (Table 1) and tightening torques The cylinders are numbered from front to rear: (Table 2) are at the end of the chapter. l-2-3-4 on the starboard bank and 5-6-7-8 on the port bank. Valve arrangement from front to rear is ENGINE SERIAL NUMBER I-E-I-E-I-E-I-E on the starboard bank and E-I-E-I-E-I-E-I on the port bank. The cylinder The engine serial number is stamped on a plate firing order is l-3-7-2-6-5-4-8. mounted either on the rear top of the cylinder The 302 cid engine is used with Models 888, 2 15, block between the intake manifold and flywheel 225-S, 225-TR and 22511-TR. The 351 cid engine housing (Figure 2) or on the end of the cylinder is used with Models 233, 255-TR, 25511-TR and head at the rear of the engine (Figure 3). 255-TRS (serial No.
    [Show full text]
  • Quantification of Diesel Engine Vibration Using Cylinder Deactivation for Exhaust Temperature Management and Recipe for Implementation in Commercial Vehicles
    Downloaded from SAE International by Audra Ziegefuss, Tuesday, May 21, 2019 2018-01-1284 Published 03 Apr 2018 Quantification of Diesel Engine Vibration Using Cylinder Deactivation for Exhaust Temperature Management and Recipe for Implementation in Commercial Vehicles Akibi Archer and James McCarthy Jr Eaton Corporation Citation: Archer, A. and McCarthy Jr, J., “Quantification of Diesel Engine Vibration Using Cylinder Deactivation for Exhaust Temperature Management and Recipe for Implementation in Commercial Vehicles,” SAE Technical Paper 2018-01-1284, 2018, doi:10.4271/2018-01-1284. Abstract vibration data in a dynamometer test cell. Three degrees of ommercial vehicles require continual improvements linear vibration and one degree of rotational vibration were in order to meet fuel emission standards, improve measured using accelerometers and rotational speed sensors. Cdiesel aftertreatment system performance and Historical data analysis showed that the remaining two rota- optimize vehicle fuel economy. Aftertreatment systems, used tional degrees of freedom were insignificant when considering to remove engine NOx, are temperature dependent. Variable driveline vibration. The engine was tested using a combination valve actuation in the form of cylinder deactivation (CDA) of deactivating two, three and four cylinders (of the six) up to has been shown to manage exhaust temperatures to the after- engine loads of approximately 4 bar BMEP in order to quantify treatment system during low load operation (i.e., under system vibration and resonance frequencies. These results 3-4 bar BMEP). During cylinder deactivation mode, a diesel were compared to driveline NVH standards to determine the engine can have higher vibration levels when compared to modes of operation that were acceptable over the engine speed normal six cylinder operation.
    [Show full text]