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Standard

Standard Specification for Allowable Defects in Rolled Goods for Interior Trim

2022-01-28
CURRENT
J3064_202201
This specification is written for rolled goods used for trim sets for automotive seats. Face materials are fabric-woven or knitted textiles, and plastic goods like polyvinyl chloride (PVC), thermoplastic polyolefin (TPO), or thermoplastic polyurethane (TPU). This specification covers material rolled goods with and without foam or backing adhered to the face material.
Standard

Urethane for Automotive Seating

1998-07-01
CURRENT
J954_199806
This SAE Recommended Practice is intended to provide uniform tolerances for dimensions of urethane materials used for motor vehicle seating. Table 1 describes these tolerances as related to slab and molded applications.
Standard

Design Guidelines for Fiberboard Materials

2010-06-21
HISTORICAL
J1774_201006
This document provides information on the various fiberboard products, which are available for automotive application. It is intended to give engineers and designers a better understanding of product usage, characteristics, properties and industry terminology. The following sections cover these topics: 2 General Product Information 3 Design Characteristics 4 Physical/Mechanical Properties 5 Fiberboard Definitions In sections 2, 3 and 4 the fiberboard products are categorized. These sections give an overview of product types, with general information about characteristics and properties. In cases where product categories encompass more than one material or material grade, ranges were established to cover all of the products in that category. The individual companies that supply fiberboard products should be consulted for specific information about a particular product or application.
Standard

Design Guidelines for Fiberboard Materials

2019-09-25
CURRENT
J1774_201909
This document provides information on the various fiberboard products, which are available for automotive application. It is intended to give engineers and designers a better understanding of product usage, characteristics, properties and industry terminology. The following sections cover these topics: 2 General Product Information 3 Design Characteristics 4 Physical/Mechanical Properties 5 Fiberboard Definitions In sections 2, 3 and 4 the fiberboard products are categorized. These sections give an overview of product types, with general information about characteristics and properties. In cases where product categories encompass more than one material or material grade, ranges were established to cover all of the products in that category. The individual companies that supply fiberboard products should be consulted for specific information about a particular product or application.
Standard

Accelerated Exposure of Automotive Interior Trim Materials Using an Outdoor Under Glass Variable Angle Controlled Temperature Apparatus

2008-07-28
CURRENT
J2229_200807
This SAE Standard specifies the operating procedures for the exposure of automotive interior trim materials in an outdoor behind glass apparatus in which the temperature is controlled for part of the day. Specimen preparation, test durations, and performance evaluation procedures are covered in material specifications of the different automotive manufacturers.
Standard

LOAD DEFLECTION TESTING OF URETHANE FOAMS FOR AUTOMOTIVE SEATING

1994-01-01
HISTORICAL
J815_199401
Cellular foam products have been traditionally checked for load deflection by determining the load required to effect a 25% deflection. In seating, on the other hand, the interest is in determining how thick the padding is under the average passenger load (a measurement of padding left for "ride" and seated height), a second measurement to give an indication of initial softness, and a final figure to indicate resiliency. To most easily fulfill these requirements, load deflection on flexible urethane foams for automotive seating is determined here by measuring the thickness of the pad under fixed loads of 1 lb, 25 lb, and 50 lb on a 50 in2 circular indentor foot.
Standard

Load Deflection Testing of Urethane Foams for Automotive Seating

2007-08-13
HISTORICAL
J815_200708
Traditionally, cellular foam products have been checked for load deflection by determining the load required to cause a 25% deflection. In automotive seating, on the other hand, the load deflection is checked by determining the thickness under constant force conditions to (a) indicate the initial softness of the seat cushion, (b) measure how thick the seat cushion is under the average passenger load (a measurement of padding left for “ride” and seated height), and (c) determine a value to indicate resiliency. In this method these measurements are made by determining the thickness of the seat cushion under fixed loads of 4.5 N, 110 N, and 220 N with a 323 cm2 circular indentor foot.
Standard

Load Deflection Testing of Urethane Foams for Automotive Seating

2002-10-30
HISTORICAL
J815_200210
Traditionally, cellular foam products have been checked for load deflection by determining the load required to cause a 25% deflection. In automotive seating, on the other hand, the load deflection is checked by determining the thickness under constant force conditions to (a) indicate the initial softness of the seat cushion, (b) measure how thick the seat cushion is under the average passenger load (a measurement of padding left for “ride” and seated height), and (c) determine a value to indicate resiliency. In this method these measurements are made by determining the thickness of the seat cushion under fixed loads of 4.5 N, 110 N, and 220 N with a 323 cm 2 circular indentor foot.
Standard

Load Deflection Testing of Urethane Foams for Automotive Seating

1998-06-01
HISTORICAL
J815_199806
Cellular foam products have been traditionally checked for load deflection by determining the load required to effect a 25% deflection. In seating, on the other hand, the interest is in determining how thick the padding is under the average passenger load (a measurement of padding left for "ride" and seated height), a second measurement to give an indication of initial softness, and a final figure to indicate resiliency. To most easily fulfill these requirements, load deflection on flexible urethane foams for automotive seating is determined here by measuring the thickness of the pad under fixed loads of 1 lb, 25 lb, and 50 lb on a 50 in2 circular indentor foot.
Standard

Load Deflection Testing of Urethane Foams for Automotive Seating

2001-12-10
HISTORICAL
J815_200112
Traditionally, cellular foam products have been checked for load deflection by determining the load required to cause a 25% deflection. In automotive seating, on the other hand, the load deflection is checked by determining the thickness under constant force conditions to (a) indicate the initial softness of the seat cushion, (b) measure how thick the seat cushion is under the average passenger load (a measurement of padding left for “ride” and seated height), and (c) determine a value to indicate resiliency. In this method these measurements are made by determining the thickness of the seat cushion under fixed loads of 4.5 N, 110 N, and 220 N with a 323 cm 2 circular indentor foot.
Standard

Accelerated Exposure of Automotive Interior Trim Components Using a Controlled Irradiance Air-Cooled Xenon-Arc Apparatus

2012-11-19
CURRENT
J2212_201211
This SAE Recommended Practice specifies the operating procedures for a controlled irradiance, air-cooled xenon-arc apparatus used for the accelerated exposure of various automotive interior trim components. Test durations, as well as any exceptions to the sample preparation and performance evaluation procedures contained in this document, are covered in material specifications of the different automotive manufacturers.
Standard

Method of Testing Resistance to Crocking of Organic Trim Materials

2012-08-24
HISTORICAL
J861_201208
This test can be used to determine the resistance to crocking (color rub-off) of organic trim materials such as fabrics, vinyl coated fabrics, leather, coated fiberboard and carpet. This method is similar to AATCC Method 8 –Colorfastness to Crocking.
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