ISO 13232-3:1996

IS0
INTERNATIONAL
STANDARD 13232-3
First edition
Motorcycles - Test and analysis
procedures for research evaluation of rider
crash protective devices fitted to
motorcycles -
Part 3:
Anthropometric impact dummy
Mo tocycles - Mkthodes d ’essai et d ’analyse de I’&aluation par la
recherche des dispositifs, months sur /es motocycles, visant 2 la protection
des motocyclistes contre /es collisions -
Partie 3: Mannequin anthropomktrique
Reference number
IS0 13232-3: 1996(E)
IS0 13232=3:1996(E)
Page
Contents
Scope
........................................................................................................................................................
Normative references .
.................... ...................................... 2
Definitions .
..................................... 2
Mechanical requirements for the motor cyclist anthropometric impact dummy
............................................................ ..................... .................................................
4.1 Basis dummy.
........................... ........... ................................................................
4.2 Motor cyclist dummy head skins
4.3 Motor cyclist dummy neck components .
............................................................................... 3
4.4 Motor cyclist dummy upper torso components
...............................................................................
4.5 Motor cyclist dummy lower torso components
................................................................................................................... 5
4.6 Modified elbow bushing
4.7 Motor cyclist dummy hands .
................................................................................... 6
4.8 Motor cyclist dummy upper leg components
.............................................................................. 6
4.9 Motor cyclist dummy frangible knee assembly.
4.10 Leg retaining cables . .
.................................................................................
4.11 Motor cyclist dummy lower leg components.
............................................................................................................
Sampling of frangible components
Initial conformity of production. 8
5.1 .
.............................................................................................. 8
5.2 Subsequent conformity of production
........................... ....................... .............. ...................................... 9
Test met hods .
6.1 Frangible bone static bending deflection test. .
................................................................................ 9
6.2 Frangible bone static torsional deflection test.
.................................................................................
6.3 Frangible bone dynamic bending fracture test
................................................................................ 10
6.4 Frangible bone dynamic torsional fracture test
........................................................................ 10
6.5 Frangible femur bone static axial load fracture test.
........................................................................... 10
6.6 Frangible knee static strength and deflection test
............... 10
6.7 Frangible abdomen test . .
6.8 Motor cyclist neck dynamic axial torsion test . .
........................................... ................. .................. 11
Marking and documentation of frangible components
................ ................................................................ 11
7.1 Marking .
........................... ..................... ................... ............................................. 11
7.2 Documentation .
Annexes
A Drawings for motor cyclist anthropometric impact dummy special components .
B Rationale for Part 3 of IS0 13232 . . . . . 43
0 IS0 1996
All rights reserved. Unless otherwise specified, no part of this publication may be
reproduced or utilized in any form or by any means, electronic or mechanical, including
photocopying and microfilm, without permission in writing from the publisher.
International Organization for Standardization
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Printed in Switzerland
II
IS0 13232=3:1996(E)
Foreword
IS0 (the International Organization for Standardization) is a worldwide federation of national standards bodies (IS0
member bodies). The work of preparing International Standards is normally carried out through IS0 technical
committees. Each member body interested in a subject for which a technical committee has been established has
the right to be represented on that committee. International organizations, governmental and non-governmental, in
liaison with ISO, also take part in the work. IS0 collaborates closely with the International Electrotechnical
Commission (IEC) on all matters of electrotechnical standardization.
Draft International Standards adopted by the technical committees are circulated to the member bodies for voting.
Publication as an International Standard requires approval by at least 75 % of the member bodies casting a vote.
This part of IS0 13232 was prepared by Technical Committee ISO/TC 22, Road vehicles, Subcommittee SC 22,
Motorcycles.
At the request of the United Nations Economic Commission for Europe, Group for Road Vehicle General Safety
(UN/ECE/TRANS/SCI/WP29/GRSG), this International Standard has been prepared by ISOnC 22/SC 22,
Motorcycles, as eight interrelated parts, on the basis of original working documents submitted by the International
Motorcycle Manufacturers Association (IMMA).
This is the first version of the standard.
IS0 13232 consists of the following parts, under the general title Motorcycles - Test and analysis procedures for
research evaluation of rider crash protective devices fitted to motorcycles:
Part 1: Definitions, symbols and general considerations
- Part 2: Definition of impact conditions in relation to accident data
Part 3: Anthropometric impact dummy
Part 4: Variables to be measured, instrumentation and measurement procedures
Part 5: Injury indices and risk/benefit analysis
- Part 6: Full-scale impact-test procedures
- Part 7: Standardized procedures for performing computer simulations of motorcycle impact tests
Part 8: Documentation and reports
Annex A forms an integral part of this part of IS0 13232. Annex B is for information only.

IS0 13232=3:1996(E)
Introduction
This International been prepared on the basis of exist ing technology.
Standard has Its purpose is to define common
research methods for making an overall evaluatio In of
and a means the effect that d evices whit h are fitted to motor
of riders,
cycles and intend ed for the crash protection have on injuries, when assessed over a range of impact,
conditions which are ba sed on accident data
It is intended that the methods and recommendations contained in this International Standard should be used in all
basic feasibility research. However, researchers should also consider variations in the specified conditions (for
example, rider size) when evaluating the overall feasibility of any protective device.
In addition, researchers may
wish to vary or extend elements of the methodology in order to research issues which are of particular interest to
them. In all such cases which go beyond the basic research, if reference is to be made to this International
Standard, a clear explanation of how the procedures used differ from the basic methodology should be provided.
In order to this International Standard properly, it is strongly recommended that ail eight parts be used
apply
together, p larticul arly if the results are to be published.
To the extent, if any, that any products identified in this International Standard may be subject to patent rights, and
to the extent, if any, that licenses may be available relative to such patents, potential manufacturers of such
products are advised that individual patent inquiries should be made and alternative products considered. A record
of patent holders’ statements, if any, regarding their willingness to negotiate licenses under patent and like rights
with applicants throughout the world under reasonable terms and conditions, is on file with the IS0 Central
Secretariat.
IS0 13232-3:1996(E)
INTERNATIONAL STANDARD @ IS0
- Test and analysis procedures for research
Motorcycles
evaluation of rider crash protective devices fitted to
motorcycles -
Part 3:
Anthropometric impact dummy
1 Scope
This International Standard specifies minimum requirements for research into the feasibility of protective devices
fitted to motor cycles, which are intended to protect the rider in the event of a collision.
This International Standard is applicable to impact tests involving
- two wheeled motor cycles;
- the specified type of opposing vehicle;
- either a stationary and a moving vehicle or two moving vehicles;
- for any moving vehicle, a steady speed and straight line motion immediately prior to impact;
- one helmeted dummy in a normal seating position on an upright motor cycle;
- the measurement of the potential for specified types of injury, by body region;
- evaluation of the results of paired impact tests (i.e.,
comparisons between motor cycles fitted and not
fitted with the proposed devices).
This part of IS0 13232 specifies the minimum requirements for the
- biofidelity of the motor cyclist anthropometric impact dummy;
- compatibility of the dummy with motor cycles, helmets, multi-directional impacts, and the instrumentation;
- repeatability and reproducibility of the dummy properties and responses.
This International Standard does not apply to testing for regulatory or legislative purposes.
2 Normative references
The following standards contain provisions which, through reference in this text, constitute provisions of this
International Standard. At the time of publication, the editions indicated were valid. All standards are subject to
revision, and parties to agreements based on this part of IS0 13232 are encouraged to investigate the possibility of
applying the most recent editions of the standards indicated below. Members of IEC and IS0 maintain registers of
currently valid International Standards.

IS0 13232=3:1996(E)
IS0 13232-I: 1996, Motor cycles - Test and analysis procedures for research evaluation of rider crash protective
- Definitions, symbols and general considerations.
devices fitted to motor cycles - Part 1
and analysis procedures for
1996, Motor cyc les - Test research evalua tio n of rider crash protective
IS0 13232-4:
-Part4- Variables to be measured, in strumentation a nd measurement procedures.
devices fitted to motor cycles
- Test and analysis procedures for research evaluation of rider crash protective
IS0 13232-6: 1996, Motor cycles
Part 6 - Full-scale impact test procedures.
devices fitted to motor cycles -
- Test and analysis procedures for research evaluation of rider crash protective
IS0 13232-8: 1996, Motor cycles
Part 8 - Documentation and reports.
devices fitted to motor cycles -
IS0 6487: 1987, Road vehicles - Measurement techniques in impact-tests - Instrumentation.
49 CFR Part 572, subpart E: 1993, Anthropomorphic test dummies, United States of America Code of Federal
Regulations issued by the National Highway Traffic Safety Administration (NHTSA). Washington, D.C.
3 Definitions
For the purposes of this part of IS0 13232, the definitions given in IS0 13232-1 apply, of which the following are of
particular relevance to this part of IS0 13232.
- abdominal foam insert;
- alternative products;
- certification, compliance;
- knee compliance element;
- load cell simulator;
- lot;
- specimen.
4 Mechanical requirements for the motor cyclist anthropometric impact dummy
The manufacturers of dummies or dummy components which are intended to meet this International Standard, shall
provide with the supplied dummies or dummy components, certification that the dummies or dummy components
meet the requirements specified below.
4.1 Basis dummy
The basis dummy shall be the Hybrid Ill 50th percentile male dummy ”. The dummy shall be equipped with
- the sit/stand construction2 ’;
- the head/neck assembly which is compatible with the six axis upper neck load cell which is specified in
4.4.1.2 of IS0 1 3232-42 ’;
- standard, non-sliding knees2).
1) Basis dummy as specified in 49 CFR Part 572, subpart E, or equivalent.
2) A list describing one or more example products which meet these requirements is maintained by the IS0 Central
Secretariat and the Secretariat of ISO/TC 22/SC 22. The list is maintained for the convenience of users of this
International Standard and does not constitute an endorsement by IS0 of the products listed. Alternative
products may be used if they can be shown to lead to the same results.
@ IS0 IS0 13232=3:1996(E)
The basis dummy specified components shall be modified or replaced as described below.
4.2 Motor cyclist dummy head skins
The head skin components shall include the two basis Hybrid Ill head skins, plus two extensions which provide
helmet compatibility. The geometries of the head skins and extensions are shown in figure A. 1, where 1 and 2 are
the basis Hybrid Ill head and rear skull cap skins and 3 and 4 are the jaw and nape extensions which provide helmet
compatibility. The masses of the jaw and nape skin extensions shall be 0,27 kg + 0,05 kg and 0,15 kg & 0,05 kg,
respectively ‘) . The head-neck s k’ ‘n modifications to the Hybrid Ill head shall be attached by means of any suitable
adhesive. Such an adhesive shall be shown to provide a bond between the mating parts in which the parent
material will fail under tensile loading before the bond itself. Cyanoacrylate is an example of a suitable adhesive.
4.3 Motor cyclist dummy neck components
4.3.1 Neck shroud
The neck shroud shall be as specified in figure A.2 ”.
4.3.2 Lower neck mount
The basis Hybrid Ill lower neck mount shall be modified as shown in figure A.3 to increase head position
adjustability. ‘)
4.3.3 Motor cyclist neck
The standard Hybr id Ill neck and its interface s with the head and torso a ssembly shall be modif ied as shown
UPPer
in figure A.4’ the neck torsion ele ment examp hich is ill in figure A.5.”
) and shall into rporate I an le of w ustra ted
rocedures described in 6.8, the
When dynamical tested ccording to the neck torque relative to the head angle of
IY P
corridors show In in figure 1.
rotation shall be W ithin th
4.3.4 Replacement nodding blocks
The standard Hybrid Ill nodding blocks shall be replaced with one of the three pairs of nodding blocks shown in
figure A.6 ’), using the procedure described in annex D of IS0 13232-6.
4.4 Motor cyclist dummy upper torso components
4.4.1 Replacement thoracic spine
Either a standard Hybrid Ill thoracic spine, or a replacement thoracic spine ‘) shall be used. If a replacement spine is
used, then the replacement thoracic spine shall be compatible with the internal data acquisition system described in
IS0 13232-4. When combined with the internal data acquisition system, the replacement thoracic spine shall
- mai ntain the same i nterface geomet and overall height as the stand ard Hybrid Ill spine box, including the
rY
sho ulder, rib, lower neck mount, an d I umb ar spine attac hment points
not interfere with the motion of the shoulders;
1) A list describing one or more example products which meet these requirements is maintained by the IS0 Central
Secretariat and the Secretariat of ISO/TC 22/SC 22. The list is maintained for the convenience of users of this
International Standard and does not constitute an endorsement by IS0 of the products listed. Alternative
products may be used if they can be shown to lead to the same results.

IS0 13232-3: 1996(E)
-5
E
rr”
20=
.
10 -
I
I
0 1
0 20 40 60 80 100 120
Head Matim(degrees)
Figure 1 - Motor cyclist neck torsional response corridor
A
provide at least 75 mm of sternum deflection in the sagittal plane, measured perpendicularly, relative to the
front surface of the spine box;
- not exceed 125 mm in lateral width;
- result in the same upper torso mass and centre of gravity as specified for a standard Hybrid III upper torso?
4.42 Modified chest skin
With the chest skin properly installed on the upper torso, the back of the chest skin shall be modified with four
holes which expose the two upper and two lower rib attachment screws in order to enable measurement of the
upper torso angle, using a torso inclinometer such as the example shown in IS0 13232-6, figure C. 1.
4.5 Motor cyclist dummy lower torso components
When fully assembled, the lower torso assembly shall result in the same lower torso mass and centre of gravity as
specified for the standard Hybrid Ill lower torso2 ’.
1) Refer to General Motors Hybrid Ill drawing numbers 78051-89 and 78051-338 in 49 CFR Part 572.
2) Refer to General Motors Hybrid Ill drawing numbers 78051-70 and 78051-338 in 49 CFR Part 572.
@ IS0
IS0 13232=3:1996(E)
4.5.1 Modified straight lumbar spine
For use with either the six-axis or three-axis lumbar load ceil, the straight lumbar spine and cable shall be FTSS part
numbers 1260004 and 1260005 ”. The lower lumbar spine transducer mount and ballast block shall be replaced
with the part shown in figure A.7 for a six-axis load cel12) and in figure A.8 for a three-axis load cel12! An abdomen
reaction plate, as shown in figure A.9 for the six-axis load2) cell or figure A.1 0 for the three-axis load cel12), shall be
mounted to the lower lumbar spine transducer mount and ballast block.
When using the dummy without either of the permissible lumbar load cells described in 4.4.1.4 of IS0 13232-4, the
load cell shall be replaced with a lumbar load ceil simulator2!
4.5.2 Motor cyclist dummy abdominal insert
The basis Hybrid Ill abdominal insert shall be replaced with a frangible solid abdominal insert, as shown in
figure A. 1 1. The replacement insert shall have a mass of 53 g + 3 g.
When tested according to the method described in 6.7, the specified values of force shall be as given in table 1 2).
Table 1 - Specified values for certification of replacement abdominal insert
.
Deflection Force
mm N
20 1 040
40 1 875
60 2 810
,
4.5.3 Sit/stand pelvis
The internal data acquisition system may be contained within a sit/stand pelvis which has been suitably modified to
accommodate it2! Whether modified or not, the sit/stand pelvis shall
- maintain the same interface geometry and external dimensions as the standard Hybrid Ill sit/stand pelvis;
- not interfere with the motion of the legs.
4.6 Modified elbow bushing
The Delrin elbow bushing, Hybrid Ill part number 78051-l 9g3 ’, shall be modified with scribe marks, as shown in
figure A. 12.
1) Parts 1260004 and 1260005 are products supplied by First Technology Safety Systems, Plymouth, Michigan,
USA. This information is given for the convenience of users of this International Standard and does not
constitute an endorsement by IS0 of the product named. Alternative products may be used if they can be
shown to lead to the same results.
2) A list describing one or more example products which meet these requirements is maintained by the IS0 Central
Secretariat and the Secretariat of lSO/TC 22/SC 22. The list is maintained for the convenience of users of this
International Standard and does not constitute an endorsement by IS0 of the products listed. Alternative
products may be used if they can be shown to lead to the same results.
3) Refer to General Motors Hybrid Ill drawing number 78051-l 99 in 49 CFR Part 572.

IS0 13232=3:1996(E)
4.7 Motor cyclist dummy hands
The basis Hybrid Ill hands shall be replaced with the Itoh-Seiki Co. part number 065-322048 ’).
4.8 Motor cyclist dummy upper leg components
4.8.1 Frangible femur bone and mounting hardware
The frangible femur bone shall be mounted to the knee joint using the adaptor shown in figure A. 1 32 ’. The frangible
femur bone shall meet the interface and size requirements shown in figure A.1 4, and have a mass 85 g + 10 g.
The frangible bone materials and design shall remain constant in the axial direction along the minimum frangible
length, as shown in figure A.1 4.
When statically tested according to the methods described in 6.1, 6.2, and 6.5, the specified values of the static
When dynamically fractured according to the
deflection and strength of the bone shall be as given in table 2.
methods described in 6.3 and 6.4, the specified values of the peak strength of the bone shall be as given in
table 221.
Table 2 - Specified values for certification of frangible femur components
Dynamic peak strength
Static deflection Static strength
5,l mm 360 N l m
Bending
Torsion 5,8’ 205 N l m
34 680 N
Axial loading
4.8.2 Femur load cell simulator
When using the dummy without the permissible femur load cells described in 4.4.1.5 of IS0 13232-4, the load cell
shall be replaced with an upper femur load cell simulator, as shown in figure A. 1 52 ’.
4.9 Motor cyclist dummy frangible knee assembly
The frangible knee assembly and the interface with the knee clevis assembly shall be as shown in figure A.1 6. The
knee assembly shall have a mass of 1,OO kg t 0,05 kg.
When statically tested according to the methods described in 6.6, the specified values of the rotational angles for
the defined moments shall be as given in table 3. The specified values of the rotational angles and moments which
indicate peak strength at shear pin failure shall be as given in table 3.2’
4.10 Leg retaining cables
Each frangible leg bone shall be installed together with a leg retaining cable to prevent the loss of portions of the
1) Part number 065-322048 is a product supplied by Itoh-Seiki Co., Tokyo, Japan. This information is given for the
convenience of users of this International Standard and does not constitute an endorsement by IS0 of the
product named. Alternative products may be used if they can be shown to lead to the same results.
2) A list describing one or more example products which meet these requirements is maintained by the IS0 Central
Secretariat and the Secretariat of ISOK 22/SC 22. The list is maintained for the convenience of users of this
International Standard and does not constitute an endorsement by IS0 of the products listed. Alternative
products may be used if they can be shown to lead to the same results.
IS0 13232=3:1996(E)
Table 3 - Specified values for certification of frangible knee assembly components
Degree of Freedom Condition Specified value
Rotation at 89 N l m 20,0°
(pfe-failure)
Maximum torque 132Nmm
Valgus
Rotation at
25,0°
maximum torque
Rotation at 35 N l m 20,0°
(pfe-failure)
Torsion Maximum torque 87 N 9 m
Rotation at 40,0°
maximum torque
The cable mass shall not exceed 200 g for each frangible bone. The
dummy leg when the frangible bone fractures.
cable shall be installed with at least 5 mm of slack ’).
4.11 Motor cyclist dummy lower leg components
4.11 .l Frangible tibia bone and mounting hardware
The frangible tibia bone shall be mounted to the ankle joint using the adaptor shown in figure A. 17 ”. The bone shall
meet the interface and size requirements shown in figure A. 18 and have a mass of 120 g + 10 g. The frangible
bone materials and design shall remain constant in the axial direction along the minimum frangible length, as shown
in figure A.1 8.
When statically tested according to the methods described in 6.1 and 6.2, the specified values of the static
deflection of the bone shall be as given in table 4. When dynamically fractured according to the methods described
in 6.3 and 6.4, the specified values of the peak strength of the bone shall be as given in table 4 ”.
Table 4 - Specified values for certification of frangible tibia components
Static Dynamic peak
deflection
strength
\ I
Bending 3,8 mm 280 N 1 m
7,0° 171 N. m
Torsion
1) A list describing one or more example products which meet these requirements is maintained by the IS0 Central
Secretariat and the Secretariat of lSO/TC 22/SC 22. The list is maintained for the convenience of users of this
International Standard and does not constitute an endorsement by IS0 of the products listed. Alternative
products may be used if they can be shown to lead to the same results.

IS0 13232=3:1996(E ’b
4.11.2 Modified lower leg skin
The basis Hybrid Ill lower leg skins shall be modified according to figure A. 19, to
- include a vertically aligned rear surface zipper to permit installation and removal of the skin from the leg;
- conform to the frangible knee structure.
The mass shall be 1,05 kg + 0,lO kg.
5 Sampling of frangible components
Fra ngible c ompo lnents shall be sampled to certify conformity of production. In all cases, such sampling shall be
components.
*formed using new, unused frangible
Per
5.1 Initial conformity of production
For certification of any new design, material specification, or manufacturing process of any frangible component and
for each of the test methods described in clause 6, ten unused components shall be tested to establish estimates of
the sample ’s mean and standard deviation. For example, certification of three different test methods would require
30 components to be tested. The sample mean value shall be within + 5% of the specified value for all strengths
The sample mean value shall be within + 20% of the specified value for all
and abdominal insert static forces.
static deflections. The sample standard deviation shall be less than 7% of the sample mean value for all strengths
and abdominal insert static forces. The sample standard deviation shall be less than 10% of the sample mean value
for all static deflections.
5.2 Subsequent conformity of production
Once a specific design, material specification, and manufacturing process have been certified, three components
from each lot which is identically manufactured shall be tested to verify the applicable characteristics specified in
table 5.
Table 5 - Frangible component subsequent conformity of production characteristics
Component Characteristic
Frangible abdominal insert Forces at 40 mm deflection
Frangible leg bone Dynamic bending strength
Knee shear pin Failure moments given in table 3
Knee compliance element Pre-failure rotations given in table 3
If none of the components deviates by more than two standard deviations, as defined in 5.1, from the established
mean value for the specified characteristic, the lot shall be considered acceptable for full-scale impact testing,
according to IS0 13232-6. If one or more of the tested components deviate by more than two standard deviations,
as defined in 5.1, from the established mean value for the specified characteristic, a different sample of three
components from the same lot shall be tested. If more than two of the total sample of six components deviate by
more than two standard deviations, as defined in 5.1, from the established mean values, the said lot shall not be
used for full-scale impact testing.

0 IS0
IS0 13232=3:1996(E)
6 Test methods
6.1 Frangible bone static bending deflection test
Using pins, attach rigid extensions of equal length, as shown in figure A.20, to each end of the frangible bone such
that the minimum combined length of the bone and extensions is as given in table 6. Support the specimen radially
at both ends, at the distances given in table 6. Place a 25 mm diameter solid rigid cylindrical bar at the mid-span
location, perpendicular to the specimen axial axis with the curved surfaces of the bone and bar in contact with each
other. Apply a radial load as given in table 6.
Table 6 - Frangible bone static bending deflection test specifications
Minimum Distance Applied
combined between radial
length supports load
mm mm N
Femur 355 341 1 350 z!z 25
Tibia 300 286 1 450 + 25
c
Measure the perpendicular linear deflection at the mid-span location of the specimen relative to the supported ends.
6.2 Frangible bone static torsional deflection test
Apply a torsional load of 69 N . m to the femur and 48 N . m to the tibia. Measure the torsional deflection of one
end of the bone relative to the other end.
6.3 Frangible bone dynamic bending fracture test
Using pins, attach rigid extensions and support the specimen as described in 6.1, using the bone extensions shown
in figure A.20 and the specimen supports shown in figure A.21. Align the specimen so that it is perpendicular to
both the cylindrical bar and the direction of motion of the impactor head, shown in figure A.22. Attach the
impactor head to the impactor device, which is shown in figures A.23 through A.26. Impact the specimen at
7,5 m/s t 0,2 m/s at mid-span, using the impacting mass shown in figure A.23.
Measure the impactor linear acceleration from just before bone contact until just after bone fracture, with an
Endevco accelerometer, model 2262A-1000 ”rigidly mounted to the impactor at the location shown in figure A.23.
Filter the data with an analog filter such that the data is attenuated by at least 40 dB at and above a frequency of
7 kHz. Sample the data at 10 kHz and filter the digital data such that the frequency response of the data output to
the unfiltered analog input is in accordance with IS0 6487, CFC 600. Determine the peak linear acceleration related
to the impact with the bone. Calculate the maximum bending moment as shown for this example:
M
= (0,251 (9,807) d, m a, max
x,max
I
M x max is the maximum bending moment, in Newton-metres;
,
d, is the distance between supports, in metres;
San Juan Capistrano, California, USA. This
1) Model 2262A-1000 is a product supplied by Endevco Corp.,
information is given for the convenience of users of this International Standard and does not constitute an
endorsement by IS0 of the product named. Alternative products may be used if they can be shown to lead to
the same results.
IS0 13232=3:1996(E)
m is the mass of the impactor, in kilograms;
a m rnax is the maximum linear acceleration of the impactor mass, in g units;
I
9,807 is a conversion factor from g units to newtons.
6.4 Frangible bone dynamic torsional fracture test
Attach a rigid extension to each end of the frangible bone and restrain one end of the resulting specimen with a
Denton load cell, model B-21 93 ”. Attach a rig id moment arm to one of the rigid extensions, such that it extends
Impact the moment arm at 7,5 m/s f: 0,2 m/s at a distance
perpendicularly from the axial axis of the specimen.
Impact with a solid rigid cylindrical bar with a diameter of
0,150 m k 0,005 m from the axial axis of the specimen.
0,025 m +, 0,003 m and a total impacting mass greater than 50 kg. Orient the cylindrical bar to be perpendicular
to the direction of travel and to the moment arm.
Measure the bone torque using the load cell and filtering and sampling according to the method described in 6.3.
Determine the maximum torsional moment.
6.5 Frangible femur bone static axial load fracture test
Attach a rigid fixture to each end of the frangible bone such that any compressive load is transferred to the bone
through the bone mounting bolt. Place the specimen in a hydraulic press, as shown in figure A.27, such that the
centre line is aligned with the centre line of the hydraulic plunger and the lower end fixture is centred on a Denton
load cell, model B-21 93 ’). Apply a c ontinually increasing load at a rate of 6 500 N/s + 2 000 N/s until failure
occurs. Electronically record the applied load until the time of failure.
6.6 Frangible knee static strength and deflection test
6.6.1 Apparatus
Use either the apparatus shown in figure A.28, or the equivalent, including a
- lever arm with minimum length of 0,5 m;
- load cell located at the load application point;
- rotational potentiometer.
6.6.2 Procedure
increasing moment to the frangible knee valg us or torsional axis, at a rate of
Apply a continually
m/s. Record the rotational angle a nd applied pin failure occurs.
30 N l m/s + 5 N l mom ent until shear
6.7 Frangible abdomen test
Apply a continually increasing load to the center of an
Use the apparatus shown in figure A.29, or the equivalent.
unused frangible abdominal insert at a rate of 450 N/s + 150 N/s. Record the crush deflection and appiied load up
to a load greater than 3 300 N.
6.8 Motor cyclist neck dynamic axial torsion test
1) Load cell model B-21 93 is a product supplied by Robert A. Denton, Inc., Rochester Hills, Michigan, USA. This
information is given for the convenience of users of this International Standard and does not constitute an
endorsement by IS0 of the product named. Alternative products may be used if they can be shown to lead to
the same results.
IS0 13232=3:1996(E)
@ IS0
Release the pendulum so that its velocity
Use either the pendulum fixture shown in figure A.30, or the equivalent.
Measure the pendulum velocity in the last 1 O” before the vertical
at the bottom of the swing is 4,2 m/s + 0,2 m/s.
position. Measure the torque at the top of the neck, using a Denton load cell, model 17 16 ’). Measure the rotation
Plot the neck torque vs. the rotation angle of the lower neck
of the lower neck mount using a potentiometer.
mount.
7 Marking and documentation of frangible components
7.1 Marking
All frangi ble corn ponents shall be ma rked by their manufacturer with some designation of their lot number, in an
area not likely to be dam aged during testing.
7.2 Documentation
The manufacturer of each frangible part shall supply, with the frangible part, test data showing initial and
subsequent conformity of production according to clauses 4, 5, and 6. The test data shall be included in the full-
scale impact test documentation (see IS0 13232-8). The test data shall show the manufacturer and lot number
designation of the part.
1) Load cell model 17 16 is a product supplied by Robert A. Denton, Inc., Rochester Hills, Michigan, USA. This
information is given for the convenience of users of this International Standard and does not constitute an
Alternative products may be used if they can be shown to lead to
endorsement by IS0 of the product named.
the same results.
IS0 13232=3:1996(E)
Annex A
(normative)
Drawings for motor cyclist anthropometric impact dummy
special components
Drawings and specifications of special components for replacement of or modification to basis Hybrid Ill
components.
NO. REVISION DATE CHK ’C
A First release 1 O/29/92 N.S
B Conversion to IS0 standard 3/29/93
E.F
Further IS0 compliance
C _ g/02/93 P.E.P.
Side View
NOT SHOWN TO SCALE
.
.
--
4 1 Skin wn - Nppp [)29 2 Q5R
3 1 Skin Extension - Jaw
029-2-057
2 1 Skin - Rear Skull Cop
78051-229
Top View
1 1 Skin - Head 78051-228
ITEM QlY DESCRIPTION
SPECIFICATION
DIMENSIONS: MM DRAWN:
SCALE: 1:2
N- shew=henko . B I 0 K I N ET I C S
TOLERANCES CHECKED:
AND ASSOCIATES LTD
FRACTIONS f
DEC. .xf
Note: DATE:
TITLE:
1. Material specification; Solid Urethane, 30-40 Durometer (Shore A)
DEC. .Xti 3/29/93 Head Skin Extensions
2. Bond skin extensions to headform.
DEC. *xxx&
QUANTITY: 1
3. Skin extension masses; jow = 0,27 kg, nape = 0,15 kg
MATERIAL: FINISH:
ANGLES ‘f SHEET 1 OF 1
4. Components 1 ond 2 are standard Hybrid Ill heod skins.
na
DRAWING NO.
Components 3 and 4 are skin extensions to provide helmet compatability.
@+s- ITo
029-Z-056
Figure A.1 - Motor cyclist head skins and extensions

DATE CHK ’C
CHKNO. ’Cj REVISION
NO. REVMON DATE
29/l O/92 N.S.
R.T. A First release
E Dimension ond material spat changed 4/06/93
E.F.
4/25/94 P.E.P. 8 Material spec changed
F Further IS0 compliance
Shape of part & dim. changed z/03/93 R.T.
, c
I
1 3/29/93 1 E.F
1 D 1 Conversion to IS0 standard
104.2
CI
l
124.4
J ,3
-
m
=f=
I
I
95.7
j
I
ITEM1 Q-TY 1 DESCRIPTION SPECIFICATION
DIMENSIONS: MM DRAWN:
SCALE: 1: 1 N. Shewchenko
.BIOKINETICS
TOLERANCES CHECKED:
AND ASSOCIATES LTD
FRACTIONS f
DEC. .xf 1.5
DATE:
TITLE:
Note:
DEC. .Xxf 3/29/93 Neck Shroud - MATD
Bond with rubber cement or equivalent.
1.
DEC. .XXxf QUANTllY: 1
2. Polyester foam [ 1 7,6kg/m3] laminated with beige Arpege 70, both sides.
MATERIAL: FINISH:
ANGLES ‘f 1 SHEET 1 OF 1
.
(100% nylon, 70 denier, 70 g/m2, 1,5 mm thick)
1 e a lsee note 2 1 no
DRAWING NO.
3. NOT SHOWN TO SCALE
029-Z-060
Figure A.2 - Neck shroud modification specifications

DATE CHK ’C
NO. REVISION
C.W.
First Release 2/l 8/92
,A
C.W.
12/7/92
B Conversion to S.I. units
3/26/92 E.F.
C Conversion to IS0 standard
P.E.P
Further IS0 compliance 5/l 6/94
Nominal radii
/-
Only partial rear slot
view IS shown
- Slot extension
Not shown to scale
ITEM Q-IY DESCRIPTION SPECIFICATION
BIOKINETICS
AND ASSOCIATES LTD
TlTLE:
MATD2 modifications
to 78051-303
I~TERIAL: FINISH: ISHED i 0F i
ANGLES ‘f 0.5
na DRAWING NO.
029-Z-055
I
Figure A.3 - Hybrid III modified lower neck mount

CHK ’D
DATE
NO. REVISION
93/l 2/l S N.S.
First release
A
PEP
94/05/l 6
Conversion to IS0 standard
c 2.
Existing threads
Neck front
/
I.
Neck bottom
..-.
Existing Keensarts
FTSS Part no. 78051-336
2 1 Neck assembly
1 4 Threaded insert Tridair Keensert KN420
SPECIFICATION
ITEM QlY DESCRIPTION
Notes:
DRAWN:
1. install Keens&s according to following instructions;
N. Shewchenko
BIOKINETICS
Tap drill 8,43, 9,7 deep
CHECKED:
CSK to 9 10,03-9,78, AND ASSOCIATES LTD
FRACTIONS f
thread 3/8-16 UNC, 9,7 deep
install insert with Tridair tool TD 420 L. DEC. .xf 0.3 DATE: TITLE:
Hylll Neck Mod ’s
DEC. .xX& 0.2
93/12/15
-.
2. Neck structure made of aluminum 60610T6, .
Torsion Element
DEC. .XxX& QUANTlTY: 1
Butyl rubber SAE JZOO/ASTM 02000
FINISH: SHEET 1 OF 1
MATERIAL:
ANGLES ‘f 0.5
3. Not shown to scale
DRAWING NO.
n/a
029-2-100
-
cfl
Figure A.4 - Motor cyclist neck and interface requirements

CHK ’C
DATE
NO. REVISION
PEP JD
Change 1 st release note 1 93/12/17 95/l l/27
T-h 10 3 1
94/05/l 6 PEP
2 Conversion to IS0 standard
Exploded view
Assembly
(_
No. Description Specification
I
029-Z-081
i- Neck cable friction washer
029-Z-076
2 2 Rotation stop - neck
Notes:
029-2-071
3 1 Rotation stop
4 1 Collar 029-2-068
1 Mass 5 0.8 kg
t;f kg
S 2 Bearing - thrust 029-Z-069
2 Not shown to scali
6 1 Bearing - radial 029-2-070
7 1 Flange 029-Z-067
ITEM QlY DESCRIPTION SPECIFICATION
8 4 l/4-20 UNC, 9,5 long FHCS Unbrako
029-l-066 DIMENSIONS: mm DRAWN:
9 1 Torsion spring - ass ’y
10 2 6-32 UNC, 6,4 long SHCS Unbrako
SCALE: 1: 1 N. Shewchenko
~BIOKINETICS
11 4 6-32 UNC, 9,5 long SHCS Unbrako
TOLERANCES CHECKED:
12 4 1,59 Dia dowel pin, 3 long Unbrako
AND ASSOCIATES LTD
FRACTIONS f
13 2 3,2 Dia dowel pm, 6,4 long Unbrako
DEC. .X.& na
1029-Z-098 IDATE:
14 1 Front nodding block
I ITITLE: - . -. .
15 Condyle pin 029-Z-075
~ 1 DEC. .XW Torsion Element
93/12/17
16 ~ 1 Rear nodding block 029-z-097
DEC. .XXXzt Sub-assembly
QUANTITY: 1
6-32 UNC, 12,7 long SHCS Unbrako
17 8
FINISH:
ANGLES ‘=t MATERIAL: ISHEET i OF i
18 1 Upper neck cap 029-2-072
Figure A.5 - Example motor cyclist neck torsion element

DATE CHK ’C
NO. REVISION
94/05/l 6 PEP
1. Conversion to IS0 standard
Nodding block locations added 94/05/l 8 PEP
2.
95/03/06 PEP
3. Notes added
Nodding blocks
Nodding blocka Nodding blocks
Front 029-Z-095 Front 029-p-nQfi
Front 029-Z-101
Rear 029-Z-096
Rear 029-Z- 102 Rear 02: -
Nodding block sat 1 Nodding block set 2 Noddhg block sot 3
- i Noddina block
2 - Neck torsional assembly 029-l -083
1 - Hybrid Ill neck with mods 029-2-100
ITEM QW DESCRIPTION SPECIFICATION
Noddhg block matAuk psr General Motors DIMENSIONS: mm DRAWN:
SCALE: NTS
Ed Fournier
Hybrid III druwing number 78015-351 BIOKINETICS
TOLERANCES CHECKED:
AND ASSOCIATES LTD
FRACTIONS f
DEC. .xf
DATE:
TITLE:
I
Head Positioning Using
Noted
I B-1
Figure A.6 - Range of head adjustments provided by three pairs of nodding blocks

CH# ‘[:
NO. REVISION DATE
A CAD reproduction of hand drawinq 1 O/22/92 C.W
1 Z/07/92 C.W.
B Conversion to S.I. units
C Material CRS to mild steel 1 Z/22/92 C.W .
3/26/93 E.F
D Conversion to IS0 standard
Further IS0 compliance 5/l 6/94 P.E.P
, E
RTl 7
I I 1
\ \/
L ’-
---
\ --w
i
es=-
cc- =i
, ‘+ I IF
‘L7
+&A -
1 b-,,yQ - 4z = = -
-/
\
I ’
’ /I \
3/8- 16 Tap
’ / \
19,l Deep
11,9
1 / \
2 Places
7 I I
I >\ \ a
136.3
I
I
I
I
I
I
I
I
I
I
I
I
57,2
t
lo,32 Drill A
19,l Chore
I I .I I
.a - -
I I
41,J Deep
60.3
TTEMIQTY 1 DESCRlPTlON SPEClflCATlON
I-
2 Places
DIMENSIONS: MM DRAWN:
120,7 SCALE: I:1
Chris W ithnall ,
BIOKINETICS
TOLERANCES CHECKED:
AND ASSOCIATES LTD
FRACTIONS =t
.
0.25 ’
NOTES: DEC. .xf: DATE:
TITLE: Lower Lumbar Spine
1. This part is welded with 029-2-0478 for a combined mass of
DEC. .Xti 3/26/93 Transducer Mount and
33,3 kg (including fastening hardware).
Ballast Block
DEC. .XxX+ QUANTlTY: 1
FINISH:
MATERIAL: SHEET 1 OF 1
2. All dimensions in millimetres except tap specifications. ANGLES ‘f 0.25
6 i/i iMild Steel , Machined Finish DRAWING NO.
3. Not shown to scale
I O29-2-047A
Figure A.7 - Lower lumbar spine transducer mount and ballast block for the s ix-axis load cell

IS0 13232=3:1996(E)
-
a
-
si
I
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in
-
ii!
:
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c
+
k
4- n
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E
c
c
ti
-
-
-
SI ’GZ - -
I 1 1 I
r-
O ”bOL
Is
Q ’PZ I
1 CHK ’D
1 DATE
1 NO. 1 REVISION I
\
10/22/92 C.W.
A CAD reproduction of hand drawing
B Conversion to S.I. units 12/07/92 c-w.
Material CRS to mild ateel 12/22/92 C.W.
C
R19,l Grind
L dR12.7 Grind fi4
3/29/93 E.F.
D Conversion to IS0 standard
Further IS0 compliance 05/l 6/94 P.E.P
E
6.41
100,l
R38.1 k
--a --
---
--T---
T--
l
I
I
I
I
I
I
I
r
I
I
58,7
. I
I
I I
I
I
I
I
I
I NOTES:
I
I 1. This port welded with 029-2-047A for a
I
1 I
combined mass of 3.33 kg (including
I
I
fastening hardware).
I
I
2. Not shown to scale
I I
...