DOCSLIB.ORG

Shell Mysella® S3 Z

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Shell Mysella® S3 Z Product information: Gas-engine oils Shell Mysella® S3 Z n Reliable protection n Very low ash content for two- and four-stroke engines DESIGNED TO MEET CHALLENGES™ PERFORMANCE AT A GLANCE Every part of your machine or process has been meticulously engineered, so you want Protection Oil life System efficiency to use a lubricant that has been designed to ensure that your equipment is well protected Shell Mysella® S3 Z and works efficiently. n Reliable protection n Very low ash content ✓✓✓✓ ✓✓✓✓ ✓✓✓✓ ® The Shell Mysella range of gas-engine oils for two- and four-stroke has been developed to enable equipment engines operators to select the oil that will deliver Shell Mysella® S2 Z optimum value to their operations through n Reliable protection ✓✓✓✓ ✓✓✓ ✓✓✓ n wear protection n Ash-free content for two-stroke engines n long oil life n system efficiency. Performance level is a relative indication only. A VERY LOW ASH STATIONARY-GAS-ENGINE OIL Shell Mysella S3 Z, a very low ash gas-engine oil, is Shell’s primary recommendation for operations with mixed fleets of two- and four-stroke engines that are fuelled by natural gas or low-pressure natural gas. Shell Mysella S3 Z helps provide superior performance and is an excellent choice for all applications that recommend ashless and low- ash oils for the gas engines and compressors used in gas transmission, gathering, storage and power generation. Key data SAE: 30, 40; BN: 2.0; ash: 0.13% DESIGNED TO PROTECT The very low ash formulation of Shell Mysella S3 Z enables potentially longer spark plug life, which can extend the time between replacements. In addition, it has excellent anti-scuff and anti- wear characteristics that help to protect engines, including brake mean effective pressure (BMEP) engines, during the running-in (break-in) period. 1Performance reported by individual customer. Actual performance may vary, depending on the application, the current oil used, the maintenance EXCELLENT anti-scuff and anti-wear protection are demonstrated in this Cooper GWA-8 engine.1 procedures and the condition of the equipment. DESIGNED FOR LONG OIL LIFE Shell Mysella S3 Z is highly resistant to nitration and oxidation, which can lead to filter deposits, increased viscosity and acid build-up. DESIGNED FOR HIGH EFFICIENCY Shell Mysella S3 Z combines a low tendency to form carbon with a strong detergency system to avoid port plugging in two-stroke (two-cycle) engines, thereby helping to eliminate the need to clean cylinder ports between overhauls. In addition, Shell Mysella S3 Z has a very low ash formulation that enables spark plugs to remain almost as new; their lifetime is limited only by spark gap erosion. It also virtually eliminates detonation and pre- OUTSTANDING exhaust port cleanliness and liner ignition due to the absence of deposit hot spots. condition are demonstrated in this Cooper GMVA-10 engine after 18,900 operating hours.1 SPECIFICATIONS AND APPROVALS SHELL MYSELLA S3 Z HAS A Shell Mysella S3 Z meets the requirements of a wide range of equipment VERY LOW ASH FORMULATION. manufacturers. SAE viscosity grades available: 30, 40. THIS ENABLES POTENTIALLY LONGER SPARK PLUG LIFE, MEETS REQUIREMENTS WHICH CAN EXTEND THE TIME Ajax BETWEEN REPLACEMENTS. Allis-Chalmers Caterpillar (except 3400, 3500, 3600) Clark Climax Colt-Fairbanks Morse Cooper-Bessemer (two-cycle) REAL-WORLD VALUE DELIVERY Dresser-Rand (categories I, II and III) International-Harvester Shell Mysella S3 Z is a very low ash natural-gas- Minneapolis–Moline engine oil from Shell. It is suitable for a wide range of Waukesha two- and four-stroke engines. White Superior (naturally aspirated) Worthington FULL PRODUCT AND SERVICE PORTFOLIO Whatever your needs or application, we can provide APPLICATIONS a full range of oils and greases, including synthetic, Suitable for use in two- and four-stroke gas engines high-performance products and additional services. operating compressors on gas collection and gas transmission networks, and for power generation 1Performance reported by individual customer. Actual performance may applications vary, depending on the application, the current oil used, the maintenance procedures and the condition of the equipment. For more information, please contact shell.com/lubricants © SOPUS Products 2012. All rights reserved. CS7384-03 Product information: Gas-engine oils Shell Mysella® S3 N n Reliable protection n Low-ash content for four-stroke engines DESIGNED TO MEET CHALLENGES™ PERFORMANCE AT A GLANCE Every part of your machine or process has been meticulously engineered, so you want Protection Oil life System efficiency to use a lubricant that has been designed to ensure that your equipment is well protected ® Shell Mysella S5 N and works efficiently. n Extended oil life ✓✓✓✓ ✓✓✓✓ ✓✓✓✓ The Shell Mysella® range of gas-engine oils n Extra protection against deposits and corrosion has been developed to enable equipment operators to select the oil that will deliver Shell Mysella® S3 N optimum value to their operations through n Reliable protection ✓✓✓ ✓✓✓ ✓✓✓ n wear protection n Low-ash content for four-stroke engines n long oil life n system efficiency. Performance level is a relative indication only. AN ASH-FREE STATIONARY-GAS-ENGINE OIL Shell Mysella S3 N is a long-established and well-proven product. It is used extensively in all types of four-stroke engines burning natural and sour gas, in dual-fuel engines and in gas compressor sets. It carries a wide range of approvals from engine manufacturers, has good oil life and is trusted by customers all over the world. It helps to keep the engine clean and provides excellent cylinder head protection. Key data SAE: 30, 40; BN: 5.0; ash: 0.45% DESIGNED FOR LONG OIL LIFE The longer the oil life, the less fluid maintenance is required to help your equipment to operate for longer without interruption. Shell Mysella S3 N is designed to have good oil life characteristics in high-speed four-stroke engines. In medium-speed four-stroke engines, its oil-drain 1 interval can exceed 10,000 running hours. 1Performance reported by individual customer. Actual performance may vary, depending on the application, the current oil used, the maintenance procedures and the condition of the equipment. DESIGNED TO PROTECT Shell Mysella S3 N provides excellent valve seat protection and can thereby help to extend cylinder-head overhaul intervals. It also offers good combustion-chamber deposit control, as it produces low levels of ash of a favorable composition. It helps to keep ring grooves clean, which contributes to long ring and liner life, and can be used in installations equipped with an exhaust gas catalyst. DESIGNED FOR HIGH EFFICIENCY Shell Mysella S3 N is designed for excellent deposit control, which helps to prevent knocking and can unlock high levels of engine efficiency and availability. It is available in SAE30 grade for reduced friction and higher fuel efficiency. LONG RING AND LINER LIFE: Shell Mysella S3 N SPECIFICATIONS AND APPROVALS demonstrated excellent ring groove cleanliness (top) and left the cylinder liner in an excellent condition (bottom) in a Shell Mysella S3 N meets the requirements of a wide range of equipment Wärtsilä 20V34SG engine after 16,000 hours of operation 1 manufacturers. SAE viscosity grades available: 30, 40. without an oil change. CLAIMS AND APPROVALS MEETS REQUIREMENTS SHELL MYSELLA S3 N OFFERS GE-Jenbacher Caterpillar stationary gas engines MAK Waukesha GOOD COMBUSTION- MAN CHAMBER DEPOSIT MDE Dezentrale Energiesysteme CONTROL, AS IT PRODUCES MTU LOW LEVELS OF ASH. MWM-Deutz Nuovo Pignone Perkins Engines Rolls-Royce Wärtsilä REAL-WORLD VALUE DELIVERY Waukesha Shell Mysella S3 N is a well-established, low-ash gas- engine oil from Shell. It has a wide range of approvals from engine manufacturers and has been used APPLICATIONS successfully throughout the world. Ideal for use in four-stroke gas engines used for power generation and combined-heat-and-power systems FULL PRODUCT AND Suitable for use in four-stroke gas engines operating SERVICE PORTFOLIO compressors on gas collection and transmission Whatever your needs or application, we can provide networks a full range of oils and greases, including synthetic, high-performance products and additional services. For more information, please contact 1Performance reported by individual customer. Actual performance may vary, depending on the application, the current oil used, the maintenance procedures and the condition of the equipment. shell.com/lubricants © SOPUS Products 2012. All rights reserved. CS7384-04 Product information: Gas-engine oils Shell Mysella® S3 S n Extra protection n Medium-ash content for four-stroke engines DESIGNED TO MEET CHALLENGES™ PERFORMANCE AT A GLANCE Every part of your machine or process has been meticulously engineered, so you want Protection Oil life System efficiency to use a lubricant that has been designed to ensure that your equipment is well protected Shell Mysella® S5 S and works efficiently. n Extended oil life ✓✓✓✓ ✓✓✓✓ ✓✓✓✓ The Shell Mysella® range of gas-engine oils n Extra protection against sour gas has been developed to enable equipment operators to select the oil that will deliver Shell Mysella® S3 S optimum value to their operations through n Extra protection ✓✓✓ ✓✓✓ ✓✓✓ n wear protection n Medium-ash content for four-stroke engines n long oil life n system efficiency. Performance level is a relative indication only. A MEDIUM-ASH OIL FOR STATIONARY GAS ENGINES Shell Mysella S3 S is Shell’s well-established, medium-ash gas-engine oil. It has been designed especially for use in engines running on sour gas, such as biogas, sewage gas and landfill gas, where its acid neutralization ability provides good engine protection and long oil life. Shell Mysella S3 S is also suitable for engines that traditionally require a medium ash oil to protect the valve seating area of the cylinder head. Key data SAE: 40; BN: 8.5; ash: 0.9% SHELL MYSELLA S3 S IS DESIGNED TO HELP YOU OPERATE YOUR EQUIPMENT FOR LONGER WITHOUT INTERRUPTION IN BOTH NATURAL- AND SOUR-GAS APPLICATIONS.
Load more

Recommended publications
  • Refrigeration for Cryogenic Sensors and Electronic Systems
    A111D3 DTBETE NATL INST OF STANDARDS & TECH R.I.C. A11 103073272 /Refrigeration for cryogenic sensors and QC100 .U57 NO.607, 1981 C.I NBS-PUB-C 19 NBS SPECIAL PUBLICATION 607 U.S. DEPARTMENT OF COMMERCE / National Bureau of Standards Refrigeration for Cryogenic Sensors and Electronic Systems r Sponsored by International Institute of Refrigeration—Commission A 1 /2 rnj Office of Naval Research— Naval Research Laboratory DU/ Cryogenic Engineering Conference National Bureau of Standards NATIONAL BUREAU OF STANDARDS The National Bureau of Standards' was established by an act of Congress on March 3, 1901. The Bureau's overall goal is to strengthen and advance the Nation's science and technology and facilitate their effective application for public benefit. To this end, the Bureau conducts research and provides: (1) a basis for the Nation's physical measurement system, (2) scientific and technological services for industry and government, (3) a technical basis for equity in trade, and (4) technical services to promote public safety. The Bureau's technical work is per- formed by the National Measurement Laboratory, the National Engineering Laboratory, and the Institute for Computer Sciences and Technology. THE NATIONAL MEASUREMENT LABORATORY provides the nafional system of physical and chemical and materials measurement; coordinates the system with measurement systems of other nations and furnishes essenUal services leading to accurate and uniform physical and chemical measurement throughout the Nation's scientific community, industry, and commerce; conducts materials research leading to improved methods of measurement, standards, and data on the properfies of materials needed by industry, commerce, educational institutions, and Government; provides advisory and research services to other Government agencies; develops, produces, and distributes Standard Reference Materials; and provides calibration services.
    [Show full text]
  • Diesel & Gas Turbine Worldwide
    December 2014 www.dieselgasturbine.com Also In This Issue th Rolls-Royce Adds New Engine Platform 45ANNIVERSARY Engine Testing & Development 1969 – 2014 DIESEL & GAS TURBINE WORLDWIDE MAGAZINE China’s Gas Turbine Future WW_DecCover.indd 1 11/17/14 9:11 AM MTU_Dec14_WW.indd 1 11/10/14 1:21 PM Navigating complex marine or naval projects? // Experience is everything Engine Supervision Local Operation Instrumentation Marine Ballast & Monitoring & Engine Safety & Wiring Water Management Engineered to Uncompromising Standards. Yours www.cmr-group.com CMR_Dec14_WW.indd 1 11/7/14 10:11 AM HAIGHT NOTES A Member of the Diesel & Gas Turbine Publications Group Editor & Publisher ...........................Brent Haight Managing Editor .............................Mike Rhodes Executive Editor ...................................DJ Slater Deputy Editor ...................................Mark Thayer Regional Manager/Editor ...............Ian Cameron Regional Manager/Editor .......... Roberto Chellini Regional Manager/Editor ........... Roberta Prandi Field Editor/Business Manager .... Bo Svensson Hold The Applause Senior Editor ................................... Patrick Crow Associate Editor ................................Jack Burke Associate Editor .............................Chad Elmore Associate Editor ................................... Art Aiello Copy Editor ................................ Jerry Karpowicz Digital Content Manager .......... Catrina Boettner Advertising Manager ........................Sarah Yildiz Circulation Manager .....................
    [Show full text]
  • June 16, 2017 Director WVDEP
    June 16, 2017 Director WVDEP – Division of Air Quality 601 57th Street SE Charleston, WV 25304 Tracking No. 1Z 865 F5F 01 9336 9074 RE: DTE Appalachia Gathering, LLC Coopers Run Compressor Station (Facility ID No. 061-00205, Permit No. R13-3291) G35-D Construction Application To Whom It May Concern: On behalf of DTE Appalachia Gathering, LLC (DTE)1, we are submitting this G35-D Construction Application to convert the Coopers Run Compressor Station’s current R13 permit into a G35- D and install new sources at the facility. Enclosed are one (1) original hard copy and two (2) CDs with PDFs of the application, along with a check for the application fee in the amount of $1,500. The affidavit of publication for the Class I Legal Advertisement will be forwarded upon receipt. DTE appreciates your review of this submittal. If you have any questions or comments about the attached information, please contact me at (724) 935-2611 x104. Respectfully, Domenic Tedesco Senior Consultant Trinity Consultants Attachments 1 DTE Appalachia Holdings, LLC recently purchased 100% of M3 Appalachia Gathering, LLC (M3) and retained the company’s Federal Employer Identification Number (FEIN). Subsequently, M3’s name was changed to DTE Appalachia Gathering, LLC (DTE). DTE will be sending a concurrent notification to WVDEP regarding this change. PROJECT REPORT DTE Appalachia Gathering, LLC Coopers Run Compressor Station G35-D Permit Application TRINITY CONSULTANTS 4500 Brooktree Drive Suite 103 Wexford, PA 15090 (724) 935-2611 June 2017 Environmental solutions delivered uncommonly well TABLE OF CONTENTS 1. INTRODUCTION 4 1.1. Facility and Project Description 4 1.2.
    [Show full text]
  • Cimac Congress Shanghai 2013
    CIMAC Congress Shanghai 2013 Cimac2013_DRUCK.indd 1 18.04.2013 10:23:55 www.shipandoffshore.net www.schiffundhafen.de For professionals in shipbuilding, offshore and marine industry Seehafen Verlag 3810_anz_mtp_s+h_fachkompetenz_A4_engl.inddCimac2013_DRUCK.indd 2 1 17.09.201218.04.2013 10:41:5910:23:56 www.shipandoffshore.net www.schiffundhafen.de CIMAC CONGRESS | SHANGHAI 2013 For professionals in shipbuilding, offshore Welcome Message The Chinese Society for Internal Combustion Engines, as the National Member of CIMAC, has the pleasure of organising the 27th CIMAC World Congress on Combustion Engines, scheduled and marine industry for May 13th - 16th2013 in Shanghai, China. CIMAC is a vigorous and attractive organisation, which brings together manufacturers, users, suppliers, oil companies, classifi ca- tion societies and scientists in the fi eld of engines. With more than 60 years of diligent, effective and valuable work, CIMAC has be- come one of the major forums in which engine builders and users can consult with each other and share concerns and ideas. The Congress will be devoted to the presentation of papers in the fi elds of marine, power generation and locomotive engine research and development, covering state-of-the art technologies as well as the application of such engines. Moreover, the event will provide the unique opportunity to meet colleagues and customers from the industry around the world. Located in the Yangtze River Delta and situated by the East China Sea, Shanghai is the biggest industrial and commercial city in China and also a famous international metropolis. Shanghai showing its own unique makings, ancient and modern, Eastern and Western, and traditional and fashionable, attracts more than 8 million visi- tors from all around the world every year.
    [Show full text]
  • CE-2017-211 Firing Order Selection for a V20 Commercial Diesel Engine
    Article citation info: BUCZEK, K., LAUER, S. Firing order selection for a V20 commercial diesel engine with FEV Virtual Engine. Combustion Engines . 2017, 169 (2), 64-70. DOI: 10.19206/CE-2017-211 Konrad BUCZEK CE-2017-211 Sven LAUER Firing order selection for a V20 commercial diesel engine with FEV Virtual Engine The continuously increasing mechanical and thermal loads of modern engines require optimization of the designs with incorporation of a wide range of different aspects. Application of advanced computer simulations in the development process for most engine components is well established, leading to the creation of well optimized products. However, the optimization of such design variables like the firing order, which influences engine operation in several disciplines, is still challenging. Considering the ever increasing peak firing pressure requirements, the layout of the firing order in multi-cylinder commercial engines is an efficient way to reduce crank train / overall engine vibration and main bearing loads, whilst controlling engine balancing and preserving adequate gas exchange dynamics. The proposed general firing order selection process for four-stroke engines and, in particular, its first part being the optimization of the firing order based on crank train torsional vibration, is the main topic of this paper. The exemplary study for a V20 high speed commercial Diesel engine regarding the influence of the firing sequence on crank train torsional vibration has been conducted with the multibody dynamics simulation software “FEV Virtual Engine”. It addresses various engine crankshaft layouts and engine applications. Key words: firing order, torsional vibration, commercial engine powertrain 1. Introduction Subsequently, all alternative firing orders are to be gen- Selection of the firing order for typical automotive en- erated.
    [Show full text]
  • Engine Crankshaft Torsional Vibration Analysis for Anomalies Detection
    Cesare Palestini Engine crankshaft torsional vibration analysis for anomalies detection Thesis submitted for examination for the degree of Master of Science in Technology. Espoo 31.5.2018 Supervisor: Professor Petri Kuosmanen Advisors: Dr Irene Gallici and Dr Juho Könnö Copyright ⃝c 2018 Cesare Palestini Aalto University, P.O. BOX 11000, 00076 AALTO www.aalto.fi Abstract of the master’s thesis Author Cesare Palestini Title Engine crankshaft torsional vibration analysis for anomalies detection Degree programme Mechanical Engineering Major Master’s Programme in Mechanical Engineering Code of major ENG25 Supervisor Professor Petri Kuosmanen Advisors Dr Irene Gallici, Dr Juho Könnö Date 31.5.2018 Number of pages 61+4 Language English Abstract Reliability is a key factor in medium speed engines. Since they are employed in power plants and vessels, there is the constant need to increase the accuracy of their anomaly detection loops. Here I investigated a novel idea aimed at decreasing the number of sensors deployed. The goal was to understand whether using only one speed sensor, located at the flywheel, is enough to detect and possibly classify different abnormal operating conditions. A torsional vibration model of a V20 spark-ignited gas engine was developed and validated with field data. The model was then used to simulate normal, heavy knock, misfire and overpressure conditions. Subsequently, the speed signals ofthe crankshaft, measured at the flywheel, were analysed in the time- and frequency- domains, in order to identify possible patterns that could be linked to the four scenarios. The spectra of the signals were then processed with two machine-learning approaches: pattern recognition and a neural network.
    [Show full text]
  • TVS 2017 Program
    PROGRAM SALZ BURG 2 0 17 Content Preface 3 Advisory Board 4 Organization 4 Program 5 Keynote speaker 10 Abstracts 11 Map – City of Salzburg 39 Symposium Location 40 Salzburg Congress Floor Plan 41 Exhibitors 42 Welcome Reception 43 Gala Dinner + Bus 44 Social + Partner Program 45 General Information 48 Contact 49 2 Dear Colleagues, Time flies: It is already three years since the first Torsional Vibration Symposium was held here in Salzburg. Now we are very pleased to welcome you to the second Torsional Vibra- tion Symposium from May 17th to 19th, 2017. We are again looking forward to welcoming torsional vibration experts from all around the globe, and to hearing lectures on a wide array of topics. In 2014 this specific meeting for torsional vibration experts attracted 186 participants from more than 20 countries. At that time 36 papers were presented and we are glad that during this second Torsional Vibration Symposium even more participants will be able to listen to an extended number of the latest technologies and technical trends. Being responsible for the conference, we would like to thank all the authors for their contri- butions to the event and for their efforts to make the program so complete. The exchange of knowledge and information between torsional vibration experts from universities, research institutes, consulting companies, software- and measurement companies and from the industry are of major significance to all of us. However, the conference does not only aim at contributing to the technical and scientific progress in the field of torsional vibrations, but it also aims at improving the cooperation between people with the same interests.
    [Show full text]
  • ME 604: Introduction to IC Engine and Gas Turbine
    Prepared by: Dr. Dulari Hansdah Assistant Professor Department of Mechanical Engineering NIT Jamshedpur Heat Engine A heat engine is a device which transforms the chemical energy of a fuel into thermal energy and uses this energy to produce mechanical work. useful devices since the 17th century, classic example of a heat engine is steam engine Classified into two types: External combustion engine and Internal Combustion engine External Combustion Engine Products of combustion of air and fuel transfer heat to a second fluid which is the working fluid of the cycle. Engine type Reciprocating or Maximum size in Principal Use rotary type kW Steam Engine Reciprocating 4000 Locomotives, ships Steam Turbine Rotary 5,00,000 Electric power, large marine Stirling or hot air engine Reciprocating 800 Experimental, power in space, vehicles Closed cycle gas turbine Rotary 80,000 Electric power, marine Source: M.L. Mathur and R.P. Sharma, “Internal Combustion Engine”, Text book In 1690 the first steam piston engine was developed by French physicist Denis Papin for pumping water. Steam engines are classified into single acting and double acting steam engine, simple and compound steam engine, low speed and high speed steam engine Fig: Steam engine details It is steam driven rotary engine. Oldest prime mover technology in which potential energy is converted into kinetic energy and then to mechanical energy Wide application in CHP (combined heat and power) plant Thermodynamic cycle is “Rankine cycle” Capacities varies from 50 kWs to hundreds of MWs Fig: Steam Turbine in steam power plant Working of turbine wholly depends upon the dynamic action of the steam Mechanical work is obtain through expansion Turbine.
    [Show full text]
  • A Study on the Effects of Sequential Turbocharged Diesel Engines
    ; A Study ON THE Effects OF Sequential TURBOCHARGED Diesel Engines Michael AleXANDER LOONSTIJN A Study on the Effects of Sequential Turbocharged Diesel Engines by Michael Alexander Loonstijn to obtain the degree of Master of Science - Mechanical Engineering at the Delft University of Technology, to be defended publicly on Tuesday July 12, 2016 at 14:00. Student number: 1334298 Project duration: December 1, 2015 – July 12, 2016 Thesis committee: Prof. Ir. J.J. Hopman, TU Delft, committee chair Rear-Admiral(ME)ret. Ir. K. Visser, TU Delft, supervisor Ir. M. de Boer, DSNS, supervisor Prof. Dr. Ir. S. Klein, TU Delft This thesis is confidential and cannot be made public until 12-July-2021. An electronic version of this thesis is available at http://repository.tudelft.nl/. Abstract Sequential turbocharging is a technique where multiple turbochargers are connected to an engine. These turbochargers are switched in sequentially. The manufacturers of engines with this system claim that the part-load and transient performance is better in comparison to engines with a single turbocharger. These claims and other effects in these engines are not well documented in scientific literature. The motivation for this research assignment is the application of the Pielstick PA6B V20 STC on board of the Indonesian navy SIGMA corvettes. The sequentially turbocharged engines have been selected for this design, based on the operating envelope of the engine. At low speed, the sequentially turbocharged engines are able to deliver more torque than a normal turbocharged Diesel engine. Based on the operating envelope, the sequentially turbocharged Diesel engine is able to deliver similar benefits that are normally present in gas turbine and electric motor propulsion systems; high torque at low speed.
    [Show full text]