Search Results

Standard

H-III50M Ankle Update to Eliminate Signal Noise

2015-03-03

CURRENT

J2949_201503

Standard

H-III5F Chest Jacket Harmonization

2023-03-08

CURRENT

J2921_202303

Standard

H-III5F Chest Jacket Harmonization

2013-01-22

HISTORICAL

J2921_201301

Standard

H-III5F Spine Box Update to Eliminate Noise

2022-05-09

CURRENT

J2915_202205

This SAE Information Report documents the problems with the 2002 regulated version of the spine box and defines a recommended solution to resolve the problem.

Standard

H-III5F Spine Box Update to Eliminate Noise

2011-08-05

HISTORICAL

J2915_201108

Standard

Hybrid III Family Chest Potentiometer Calibration Procedure

2000-06-30

HISTORICAL

J2517_200006

This procedure establishes a recommended practice for establishing the sensitivity of the chest displacement potentiometer assembly used in the Hybrid III family of Anthropomorphic Test Devices (ATDs, or crash dummies). This potentiometer assembly is used in the Hybrid III family to measure the linear displacement of the sternum relative to the spine (referred to as chest compression). An inherent non-linearity exists in this measurement because a rotary potentiometer is being used to measure a generally linear displacement. As the chest cavity is compressed the potentiometer rotates, however the relationship between the compression and the potentiometer rotation (and voltage output) is non-linear. Crash testing facilities have in the past used a variety of techniques to calibrate the chest potentiometer, that is to establish a sensitivity value (mm/(volt/volt) or mm/(mvolt/volt)).

Standard

Hybrid III Family Chest Potentiometer Calibration Procedure

2006-09-22

HISTORICAL

J2517_200609

This procedure establishes a recommended practice for establishing the sensitivity of the chest displacement potentiometer assembly used in the Hybrid III family of Anthropomorphic Test Devices (ATDs, or crash dummies). This potentiometer assembly is used in the Hybrid III family to measure the linear displacement of the sternum relative to the spine (referred to as chest compression). An inherent nonlinearity exists in this measurement because a rotary potentiometer is being used to measure a generally linear displacement. As the chest cavity is compressed the potentiometer rotates, however the relationship between the compression and the potentiometer rotation (and voltage output) is nonlinear. Crash testing facilities have in the past used a variety of techniques to calibrate the chest potentiometer, that is to establish a sensitivity value (mm/ (volt/volt) or mm/ (mvolt/volt)).

Standard

Hybrid III Family Chest Potentiometer Calibration Procedure

2010-09-28

HISTORICAL

J2517_201009

Standard

Hybrid III Family Chest Potentiometer Calibration Procedure

2016-08-03

HISTORICAL

J2517_201608

Standard

Hybrid III Family Chest Potentiometer Calibration Procedure

2022-10-07

CURRENT

J2517_202210

This procedure establishes a recommended practice for establishing the sensitivity of the chest displacement potentiometer assembly used in the Hybrid III family of Anthropomorphic Test Devices (ATDs, or crash dummies). This potentiometer assembly is used in the Hybrid III family to measure the linear displacement of the sternum relative to the spine (referred to as chest compression). An inherent nonlinearity exists in this measurement because a rotary potentiometer is being used to measure a generally linear displacement. As the chest cavity is compressed the potentiometer rotates, however the relationship between the compression and the potentiometer rotation (and voltage output) is nonlinear. Crash testing facilities have in the past used a variety of techniques to calibrate the chest potentiometer, that is to establish a sensitivity value (mm/(volt/volt) or mm/(mvolt/volt)).

Standard

Low Speed Knee Slider Test Procedure for the Hybrid III 50th Male Dummy

2009-03-05

HISTORICAL

J2876_200903

This procedure establishes a recommended practice for performing a Low Speed Knee Slider test to the Hybrid III 50th Male Anthropomorphic Test Device (ATD or crash dummy). This test was created to satisfy the demand from industry to have a certification test which produces similar results to an actual low energy automotive impact test. An inherent problem exists with the current certification procedure because the normal (2.75 m/s) knee slider test has test corridors that do not represent typical displacements seen in these low energy impact tests. The normal test corridors specify a force requirement at 10 mm and at 18 mm, while the low speed test needs to have a peak displacement around 10 mm.

Standard

Low Speed Knee Slider Test Procedure for the Hybrid III 50th Male Dummy

2015-05-07

HISTORICAL

J2876_201505

This procedure establishes a recommended practice for performing a Low Speed Knee Slider test to the Hybrid III 50th Male Anthropomorphic Test Device (ATD or crash dummy). This test was created to satisfy the demand from industry to have a certification test which produces similar results to an actual low energy automotive impact test. An inherent problem exists with the current certification procedure because the normal (2.75 m/s) knee slider test has test corridors that do not represent typical displacements seen in these low energy impact tests. The normal test corridors specify a force requirement at 10 mm and at 18 mm, while the low speed test needs to have a peak displacement around 10 mm.

Standard

Low Speed Knee Slider Test Procedure for the Hybrid III 50th Male Dummy

2022-07-29

CURRENT

J2876_202207

This procedure establishes a recommended practice for performing a Low Speed Knee Slider test to the Hybrid III 50th Male Anthropomorphic Test Device (ATD or crash dummy). This test was created to satisfy the demand from industry to have a certification test which produces similar results to an actual low energy automotive impact test. An inherent problem exists with the current certification procedure because the normal (2.75 m/s) knee slider test has test corridors that do not represent typical displacements seen in these low energy impact tests. The normal test corridors specify a force requirement at 10 mm and at 18 mm, while the low speed test needs to have a peak displacement around 10 mm.

Standard

Low Speed Thorax Impact Test Procedure for the HIII 50th Male Dummy

2022-06-29

CURRENT

J2779_202206

Standard

Low Speed Thorax Impact Test Procedure for the HIII 50th Male Dummy

2015-07-22

HISTORICAL

J2779_201507

Standard

Low Speed Thorax Impact Test Procedure for the HIII 50th Male Dummy

2007-01-24

HISTORICAL

J2779_200701

This procedure establishes a recommended practice for performing a Low Speed Thorax Impact Test to the Hybrid III 50th Male Anthropomorphic Test Device (ATD or crash dummy). This test was created to satisfy the demand by the industry to have a calibration test which resulted in similar results to an actual low energy automotive impact test. An inherent problem exists with the current calibration procedure because the normal (6.7 m/s) thorax impact test has test corridors that are not representative to these low energy impact tests. The normal test corridors specify a displacement range of around 68 mm and the low speed displacement corridor needs to be around 25 mm. The intent of this recommended practice is to develop a low speed thorax calibration procedure for the H-III50M dummy in 25 to 30 mm deflection range.

Standard

Low Speed Thorax Impact Test Procedure for the HIII5F Dummy

2010-01-13

HISTORICAL

J2878_201001

Standard

Low Speed Thorax Impact Test Procedure for the HIII5F Dummy

2022-06-09

CURRENT

J2878_202206

This procedure establishes a recommended practice for performing a Low Speed Thorax Impact Test to the Hybrid III Small Female Anthropomorphic Test Device (ATD or crash dummy). This test was created to satisfy the demand by the industry to have a certification test which results in peak chest deflection similar to current full vehicle, frontal impact tests. An inherent problem exists with the current certification procedure because the normal (6.7 m/s) thorax impact test has test results for peak chest deflection that are greater than those currently seen in full vehicle, frontal tests. The intent of this document is to develop a low speed thorax certification procedure for the H-III5F dummy with a 3.0 m/s impact similar to the SAE J2779 procedure for the H-III50M dummy.

Standard

Low Speed Thorax Impact Test Procedure for the HIII5F Dummy

2016-06-28

HISTORICAL

J2878_201606

This procedure establishes a recommended practice for performing a Low Speed Thorax Impact Test to the Hybrid III Small Female Anthropomorphic Test Device (ATD or crash dummy). This test was created to satisfy the demand by the industry to have a certification test which results in peak chest deflection similar to current full vehicle, frontal impact tests. An inherent problem exists with the current certification procedure because the normal (6.7 m/s) thorax impact test has test results for peak chest deflection that are greater than those currently seen in full vehicle, frontal tests. The intent of this document is to develop a low speed thorax certification procedure for the H-III5F dummy with a 3.0 m/s impact similar to the SAE J2779 procedure for the H-III50M dummy.

Standard

Lumbar Flexion Test Procedure for the Hybrid III 50th Male Dummy

2023-03-20

CURRENT

J3074_202303

This procedure establishes a recommended practice for performing a lumbar flexion test to the Hybrid III 50th male anthropomorphic test device (ATD or crash dummy). This test was created to satisfy the demand from industry to have a certification test which characterizes the lumbar without interaction of other dummy components. In the past, there have not been any tests to evaluate the performance of Hybrid III 50th lumbar.