Search Results

Standard

Power Cylinder Oil Consumption: Transport Mechanisms

2007-02-07

HISTORICAL

J2794_200702

This document covers oil transport mechanisms from the power cylinder which might affect oil consumption. It will not discuss in detail the oil consumption mechanisms from other components.

Standard

Power Cylinder Oil Consumption: Transport Mechanisms

2018-07-27

CURRENT

J2794_201807

This document covers oil transport mechanisms from the power cylinder system which might affect oil consumption. It will not discuss in detail the oil consumption mechanisms from other systems or engine components.

Standard

Power Cylinder Oil Consumption: Problem Solving

2007-04-17

HISTORICAL

J2795_200704

This document describes methodologies to determine the causes of high oil consumption caused by primarily the power cylinder system. .

Standard

Power Cylinder Oil Consumption: Problem Solving

2014-08-05

HISTORICAL

J2795_201408

This document describes methodologies to determine the causes of high oil consumption caused by primarily the power cylinder system.

Standard

Power Cylinder Friction: Mechanisms

2010-01-14

HISTORICAL

J2904_201001

This document covers the mechanisms from the power cylinder which contribute to the mechanical friction of an internal combustion engine. It will not discuss in detail the influence of other engine components or engine driven accessories on friction.

Standard

Power Cylinder Friction: Mechanisms

2018-05-16

HISTORICAL

J2904_201805

This document covers the mechanisms from the power cylinder which contribute to the mechanical friction of an internal combustion engine. It will not discuss in detail the influence of other engine components or engine driven accessories on friction.

Standard

Power Cylinder Effects on Friction and Fuel Economy

2024-01-22

CURRENT

J2904_202401

This document covers the mechanisms from the power cylinder, which contribute to the mechanical friction of an internal combustion engine. It will not discuss in detail the influence of other engine components or engine driven accessories on friction.

Standard

Power Cylinder Blow-by: Problem Solving

2014-08-05

HISTORICAL

J2798_201408

This document describes methodologies to determine the causes blow-by oil consumption caused by the power cylinder.

Standard

Power Cylinder Blow-by: Blow-by Mechanisms

2022-02-15

CURRENT

J2797_202202

This document covers the mechanisms associated with the power cylinder system which might affect blow-by. It will not discuss in detail the blow-by mechanisms from other systems or engine subsystems.

Standard

Power Cylinder Blow-By: Blow-By Mechanisms

2014-08-28

HISTORICAL

J2797_201408

This document covers the mechanisms associated with the power cylinder system which might affect blow-by. It will not discuss in detail the blow-by mechanisms from other systems or engine subsystems.

Standard

Power Cylinder Blow-By: Blow-By Mechanisms

2007-02-07

HISTORICAL

J2797_200702

This document covers the mechanisms associated with the power cylinder which might affect blow-by. It will not discuss in detail the blow-by mechanisms from other engine subsystems.

Standard

Internal Combustion Engines—Piston Vocabulary

2002-01-23

HISTORICAL

J2612_200201

This SAE Standard defines the most commonly used terms for pistons. These terms designate either types of pistons or certain characteristics and phenomena of pistons. The terms and definitions apply to pistons for reciprocating internal combustion engines and compressors working under analogous conditions.

Standard

Internal Combustion Engines—Piston Vocabulary

2010-05-20

HISTORICAL

J2612_201005

Standard

Internal Combustion Engines—Piston Rings—Vocabulary

1998-04-17

HISTORICAL

J1588_199804

Differences, where they exist, are shown in Appendix A with associated rationale. This SAE Standard defines the most commonly used terms for piston rings. These terms designate either types of piston rings or certain characteristics and phenomena of piston rings. The terms and definitions apply to piston rings for reciprocating internal combustion engines and compressors working under analogous conditions. Appendix B is included which lists equivalent terms in English, French, Russian, German, Spanish, Portuguese, Italian, and Japanese.

Standard

Internal Combustion Engines—Piston Rings—Scraper Rings

1998-04-17

HISTORICAL

J1999_199804

Differences, where they exist, are shown in Appendix A. This SAE Standard specifies the essential dimensional features of N, NM, E, and EM scraper piston ring types. Dimensional Tables 7 and 8 offer the choice of two radial wall thicknesses: a Radial wall thickness "regular" (Table 7) b Radial wall thickness "D/22" (Table 8) The requirements of this document apply to scraper rings for reciprocating internal combustion piston engines up to and including 200 mm diameter. They may also be used for piston rings of compressors working under similar conditions.

Standard

Internal Combustion Engines—Piston Rings—Rectangular Rings

1998-04-01

HISTORICAL

J1997_199804

Differences, where they exist, are shown in Appendix A. This SAE Standard specifies the essential dimensional features of R, B, and M rectangular piston ring types. Dimensional Tables 8 and 9 offer the choice of two radial wall thicknesses: a Radial wall thickness "regular" (Table 8) b Radial wall thickness "D/22" (Table 9) The requirements of this document apply to rectangular rings for reciprocating internal combustion piston engines up to and including 200 mm diameter. They may also be used for piston rings of compressors working under similar conditions.

Standard

Internal Combustion Engines—Piston Rings—Quality Requirements

1998-04-17

HISTORICAL

J1996_199804

Differences, where they exist, are shown in Appendix A. This SAE Standard specifies the quality aspects that are capable of definition but not normally found on a drawing specification. The difficulty of trying to define in absolute terms the quality attainable in normal commercial manufacture of piston rings is well known. In this document the commonly encountered aspects of quality in terms of casting defects and other departures from ideal are quantified. Many minor defects are clearly quite acceptable; other defects because of size or numbers are inadmissible.

Standard

Internal Combustion Engines—Piston Rings—Oil Control Rings

1998-04-01

HISTORICAL

J2002_199804

Differences, where they exist, are shown in Appendix A. This SAE Standard specifies the dimensional features of S, G, D, and DV oil control piston ring types. The normal range for the axial width of oil control rings (2.5 to 8 mm inclusive) is divided into 0.5 or 1.0 increments. In Table 7, dimensions in inch units are given for oil control rings with axial width 4.75 mm (equal to 3/16 in) for existing applications. The requirements of this document apply to oil control rings for reciprocating internal combustion piston engines up to and including 200 mm in diameter. They may also be used for piston rings of compressors working under similar conditions.

Standard

Internal Combustion Engines—Piston Rings—Material Specifications

1998-04-17

HISTORICAL

J1590_199804

Differences, where they exist, are shown in Appendix A. This SAE Standard establishes a classification of materials intended for the manufacture of piston rings based on mechanical properties and the stresses that these materials are capable of withstanding. This document applies to the manufacture of piston rings up to and including 200 mm diameter for reciprocating internal combustion engines. It also applies to piston rings for compressors working under similar conditions.

Standard

Internal Combustion Engines—Piston Rings—Keystone Rings

1998-04-01

HISTORICAL

J2000_199804

Differences, where they exist, are shown in Appendix A. This SAE Standard specifies the essential dimensional features of T, TB, TM, K, KB, and KM keystone piston ring types. The requirements of this document apply to compression rings for reciprocating internal combustion engines up to and including 200 mm diameter.