Search Results

Standard

Type “F” Clamps for Plumbing Applications

2022-02-02

CURRENT

J1670_202202

This SAE Standard covers complete dimensional and general specifications for worm drive hose clamps for general use in the plumbing industry.

Standard

Type "F" Clamps for Plumbing Applications

2008-12-02

HISTORICAL

J1670_200812

This SAE Standard covers complete dimensional and general specifications for worm drive hose clamps for general use in the plumbing industry.

Standard

Test Method for Evaluating the Electrochemical Resistance of Coolant System Hoses and Materials

2005-09-12

HISTORICAL

J1684_200509

This test method provides a standardized procedure for evaluating the electrochemical resistance of automotive coolant hose and materials. Electrochemical degradation has been determined to be a major cause of EPDM coolant system hose failures. The test method consists of a procedure which induces voltage to a test specimen while it is exposed to a water/coolant solution. Method #1, referred to as a “Brabolyzer” test, is a whole hose test. Method #2, referred to as a “U” tube test, uses cured plate samples or plates prepared from tube material removed from hose (Method No. 2 is intended as a screening test only). Any test parameters other than those specified in this SAE Recommended Practice, are to be agreed to by the tester and the requester.

Standard

Test Method for Evaluating the Electrochemical Resistance of Coolant System Hoses and Materials

2018-11-21

CURRENT

J1684_201811

This test method provides a standardized procedure for evaluating the electrochemical resistance of automotive coolant hose and materials. Electrochemical degradation has been determined to be a major cause of EPDM coolant system hose failures. The test method consists of a procedure which induces voltage to a test specimen while it is exposed to a water/coolant solution. Method #1, referred to as a “Brabolyzer” test, is a whole hose test. Method #2, referred to as a “U” tube test, uses cured plate samples or plates prepared from tube material removed from hose (Method No. 2 is intended as a screening test only). Any test parameters other than those specified in this SAE Recommended Practice, are to be agreed to by the tester and the requester.

Standard

Recommended Practices for Design and Evaluation of Passenger and Light Truck Coolant Hose Clamped Joints

2013-07-09

CURRENT

J1697_201307

This SAE Recommended Practice covers recommended practices for design and evaluation of hose clamped joints primarily in automotive applications. It is intended to: (a) evaluate current joint designs, (b) compare existing designs, (c) aid in the development of new designs, (d) give objective results once weights are set, (e) rate the overall design and individual sections of design, and (f) encourage future research by industry and the OEM's.

Standard

Test Method for Evaluating the Electrical Resistance of Coolant System Hose Covers

2021-08-12

CURRENT

J2790_202108

This test method provides a standardized procedure for evaluating the electrical resistance of automotive coolant hose covers. It is known that an electrical potential exists between the engine and the radiator. Coolant hose cover conductivity has been determined to be a factor to reduce hose clamp life when vehicle build variations allow possible contact of the hose or the clamp to metal components on the radiator and engine thus completing an electrical circuit. The ensuing electrical current can undercut the clamp protective coating, leaving it vulnerable to the corrosive effects of road salts, moisture, and other environmental contaminants. SAE Recommended Practice J1684 addresses the electrochemical resistance of the tube portion of the coolant hose.

Standard

Test Method for Evaluating the Electrical Resistance of Coolant System Hose Covers

2007-06-15

HISTORICAL

J2790_200706

This test method provides a standardized procedure for evaluating the electrical resistance of automotive coolant hose covers. It is known that an electrical potential exists between the engine and the radiator. Coolant hose cover conductivity has been determined to be a factor to reduce hose clamp life when vehicle build variations allow possible contact of the hose or the clamp to metal components on the radiator and engine thus completing an electrical circuit. The ensuing electrical current can undercut the clamp protective coating, leaving it vulnerable to the corrosive effects of road salts, moisture, and other environmental contaminants. SAE Recommended Practice J1684 addresses the electrochemical resistance of the tube portion of the coolant hose.

Standard

Compression Set of Hoses or Solid Discs

2004-11-30

HISTORICAL

J1638_200411

This SAE Recommended Practice is used for establishing the compression set that could be expected to occur with a thermoset elastomeric hose under securing clamps. It seeks to reproduce the type of indentation caused by the clamps in the wall of a hose. An excessive compression set measured by this method may indicate a hose that could eventually allow leakage of fluid or gas past the clamps in service.

Standard

Compression Set of Hoses or Solid Discs

2015-04-21

CURRENT

J1638_201504

This SAE Recommended Practice is used for establishing the compression set that could be expected to occur with a thermoset elastomeric hose under securing clamps. It seeks to reproduce the type of indentation caused by the clamps in the wall of a hose. An excessive compression set measured by this method may indicate a hose that could eventually allow leakage of fluid or gas past the clamps in service.

Standard

COMPRESSION SET OF HOSES OR SOLID DISCS

1993-05-01

HISTORICAL

J1638_199305

This SAE Recommended Practice is used for establishing the compression set that could be expected to occur with engine coolant hoses under securing clamps. It seeks to reproduce the type of indentation caused by the clamps in the wall of the hose. An excessive compression set measured by this method would indicate a hose that could eventually allow leakage of coolant past the clamps in service. This method has been found to give repeatable results in the range of 25% to 50% initial compression.

Standard

Test Method for Evaluating the Sealing Capability of Hose Connections with a PVT Test Facility

2012-10-24

CURRENT

J1610_201210

This test method provides a standardized procedure for evaluating the sealing capability of a hose connection or any of the individual components of the connection with a pressure, vibration, and temperature (PVT) test facility. This test method consists of a test procedure which includes vibration and coolant flow (#1 ) and a similar test procedure specified without vibration or coolant flow (#2). Any test parameters, other than those specified in this SAE Recommended Practice, are to be agreed to by the tester and the requestor.

Standard

Non-Contact Hose Measurement Study 1

2001-08-06

HISTORICAL

J2605_200108

The Hose Measurement Task Force conducted a round-robin study to determine the measuring capability of automotive suppliers and users to simultaneously measure the Inside Diameter (ID), Outside Diameter (OD), Wall Thickness (Wall), and Wall thickness Variation (WV) of hose using a laser-based, non-contact LOTIS QC-20 gauging device. Three (3) companies (all end users) participated in this testing with one of the three companies performing the GR&R calculations presented herein. Based upon the round-robin study this report will detail procedures, test measuring devices, results, and conclusions.

Standard

Non-Contact Hose Measurement Study 1

2006-01-04

HISTORICAL

J2605_200601

The Hose Measurement Task Force conducted a round-robin study to determine the measuring capability of automotive suppliers and users to simultaneously measure the Inside Diameter (ID), Outside Diameter (OD), Wall Thickness (Wall), and Wall thickness Variation (WV) of hose using a laser-based, non-contact LOTIS QC-20 gauging device. Three (3) companies (all end users) participated in this testing with one of the three companies performing the GR&R calculations presented herein. Based upon the round-robin study this report will detail procedures, test measuring devices, results, and conclusions.

Standard

Non-Contact Hose Measurement Study 1

2015-04-21

CURRENT

J2605_201504

The Hose Measurement Task Force conducted a round-robin study to determine the measuring capability of automotive suppliers and users to simultaneously measure the Inside Diameter (ID), Outside Diameter (OD), Wall Thickness (Wall), and Wall thickness Variation (WV) of hose using a laser-based, non-contact LOTIS QC-20 gauging device. Three (3) companies (all end users) participated in this testing with one of the three companies performing the GR&R calculations presented herein. Based upon the round-robin study this report will detail procedures, test measuring devices, results, and conclusions.

Standard

Dimensions and Tolerances for Coolant System Hoses

2021-03-08

CURRENT

J2387_202103

The purpose of this SAE Recommended Practice is to provide dimensions for both standard and thin-wall hoses and to provide commercial and precision tolerances for SAE 20R3 and SAE 20R4 coolant system hoses.

Standard

Dimensions and Tolerances for Coolant System Hoses

2003-01-24

HISTORICAL

J2387_200301

The purpose of this SAE Recommended Practice is to provide dimensions for both standard and thin-wall hoses and to provide commercial and precision tolerances for SAE 20R3 and SAE 20R4 coolant system hoses.

Standard

Dimensions and Tolerances for Coolant System Hoses

1997-10-01

HISTORICAL

J2387_199710

The purpose of this SAE Recommended Practice is to provide dimensions for both standard and thin-wall hoses and to provide commercial and precision tolerances for SAE 20R3 and SAE 20R4 coolant system hoses.

Standard

Geometric Dimensions and Tolerancing for Curved Hose

2021-03-08

CURRENT

J2370_202103

To provide the curved hose industry and their customers with a recommended practice for applying GD&T procedures to curved hoses and to provide generic curved hose drawings that represent the application of GD&T to typical curved hose parts. Dimensioning and Tolerancing will be in accordance with ASME Y14.5M.

Standard

Geometric Dimensions and Tolerancing for Curved Hose

2009-03-05

HISTORICAL

J2370_200903

To provide the curved hose industry and their customers with a recommended practice for applying GD&T procedures to curved hoses and to provide generic curved hose drawings that represent the application of GD&T to typical curved hose parts. Dimensioning and Tolerancing will be in accordance with ASME Y14.5M.

Standard

Geometric Dimensions and Tolerancing for Curved Hose

2003-12-19

HISTORICAL

J2370_200312

To provide the curved hose industry and their customers with a recommended practice for applying GD&T procedures to curved hoses and to provide generic curved hose drawings that represent the application of GD&T to typical curved hose parts. Dimensioning and Tolerancing will be in accordance with ASME Y14.5M.