COMPARISON OF DIFFERENT CAR SEATS REGARDING

HEAD-NECK KINEMATICS OF VOLUNTEERS DURING REAR END

IMPACT

Eichberger A, Geigl BC, Moser A, Fachbach B, Steffan H Inst. for Mechanics, University of Technology Graz, Austria

Hell W, Langwieder K Verband der Schadenversicherer e. V. , Büro für KfZ-Technik, Munich,

Gerrnany

ABSTRACT

Various research studies performed at different institutes (Deutscher 1 994, Geigl et al 1 994) have shown that current car seats are by no means optimized regarding the protection of occupants during rear end impacts. Sied tests performed with volunteers and PMTO's (Geigl et al, 1 994) have shown some weak points of selected seats. In order to obtain more information on problems within the construction of current car seats, a comparison of standard seats seemed to be important.

In a collaboration between Graz University of Technology and the VdS (Verband der Schadenversicherer, Munich) approx. 7500 rear end impacts with personal injuries were investigated. The data was taken from the 'Vehicle Safety 90" (VdS, 1 994), a ·statistic which contains 1 5,000 actual car to car accidents with at least one occupant injured during 1 990 in Germany (old states only). From these investigations several factors which influence neck injuries in rear end collisions could be evaluated.

On the other hand sied tests with volunteers were performed for some selected car seats. The head-neck kinematics of the occupants was measured and visualized. ldentical test conditions as far as possible have been chosen in repeated tests to ensure a fair comparison of the different tests. Nine different types of car seats were used at sied impact velocities of 8 and 1 1 km/h. The mean sied decelerations were settled at a level of 2.5 g.

The comparison of the statistics with the measurements showed a fair correlation between both approaches. So a "ranking" of the different seats regarding their risk of a neck injury during rear end impacts could be defined and the biggest problems in seat construction could be summarized.

- 153 -

METHODOLOGY

REAL CRASH INVESTIGATIONS - The data of the "real crash study" were taken from 'Vehicle Safety 90" (VS 90) (VdS, 1 994). This material includes 1 5,000 accidents where at least one occupant was injured in Germany (old states only) in 1 990 and covers approximately 1 5% of the car collisions with personal injury claims.

The characteristics of these collisions were compiled in a data base. These characteristics are: car model, car mass, passengers, injuries, angle and offset of collision, etc. Approx. 50% of these collisions were rear end collisions. Due to an extended investigation 520 rear end collisions were taken from this data base and reconstructions of the accidents were performed.

lnfluences on neck injuries dealing with the car (mass, model, structure, head restraint adjustment), the occupant (age, sex, pretended injuries) and situation of the crash (ß V, angle and offset of collision, etc.) were evaluated.

SLED TESTS - To validate the statistic data and the influence of the car seat construction, 34 sied tests were performed with 9 d ifferent car seats. The sied and other hard- and software used are described in more detail by Geigl et al (1 994). Due to the fact that Hybrid-11 1-Dummies do not show realistic head­neck-kinematics in rear end collisions (Geigl et al 1 994, Scott et al 1 993), only sied tests with volunteers were performed. The impact speed of the sied was selected between 8 and 1 1 km/h and corresponded with the change of velocity (ß V) of the struck car in reality. All tested seats have been taken from used cars and were in good condition. Most of the selected seats (See table 1 ) were taken from frequent cars in 1 990. The Golf I I I seat was selected for comparison purposes.

Table 1 - List of tested car seats

Car Model year of production AUDI 80 1 988 BMW 5 . . 1 992 FORD Escort 1 985 MAZDA 323 1 989 MERCEDES W124 1 987 OPEL Corsa A 1 985 PORSCHE 91 1 1 988 VW Golf I I 1 989 VW Golf I I I 1 993

The deceleration behavior of the sied was defined as a nearly rectangular pulse at a level of approx. 2.5 g. Test conditions have been kept identical as far as possible to ensure a good reproducibility and comparabil ity of the different tests.

- 1 54 -

The following parameters were used for the sied tests:

• The inclination of the seat back was adjusted to 25° against the vertical for all tests.

• Sied impact velocity: 1 0.5 +1-0.2 km/h (Test no. 1 to 17) , 8.5 +1-0.2 km/h (Test no. 1 8 to 34).

• The deceleration level of the sied was kept as constant as possible (average deceleration approx. 2.5 g)

• Adjustment of the head restraint was as "good" as possible (average distance between the top of the head and the top of the head restraint approx. 60 mm).

• The volunteers were told to sit relaxed in the position they prefer in their own car.

• Since the sied was towed up to constant test speed against the line of sight, the volunteers were not able to predict the moment of the sied impact.

RESUL TS AND DISCUSSION

REAL CRASH INVESTIGATIONS - Within 93.5% of all rear end collisions with personal injuries, at least one of the passengers claimed a neck injury 0JS 90). Other injuries are comparatively rare (Münker et al, 1 994). The change of velocity (öv) of the struck car is offen at a low level (Fig. 1 ) .

Fig. 1 - Distribution of ö V of the struck car at rear end collisions

50 45 - 43.2% 40 : 35 30 27.2% -f- f--- - 23.6% � 25 20 ,_ r-- -1 5 >- f--- -10 ,_ - -

5% >- - - 1 1 1% 0% � 5 0

� � � � � "" "" "" "" "" � "' "' "' 0 "'1 "l "' ci .; .,.; .,.; /\

� N

Change of Velocity /lV [km/h] n=496

- 1 55 -

The change of velocity was determined by reconstruction of approx. 500 rear end collisions. This was realized by evaluating the EES* of the involved cars (using pictures of the crashed vehicles) and an assumption of the elasticity of the impact (Eichberger, 1 995). Fig. 1 shows that most rear end impacts with neck injury claims occurred at low velocity changes.

Further investigations on real crash material confirmed that the most important influences regarding neck injuries are: • car model (especially car mass, car structure and car seat) • change of velocity (�V) of the struck car.

To get the influence of the car model for the risk of neck injuries approx. 50 cars were statistically investigated. From this data the "Neck lnjury Factor" (NIF) for the considered cars was defined. The NIF describes the frequency of neck injuries claims for a car regarding the number of registrations of this car. lt was calculated by the following formula:

n : neck

"FS90 :

n m NIF = neck 0 Germany

n m FS90 car

number of neck injury claims of the considered car model (rear end impact) at Vehicle Safety 90 (VS 90) data base number of rear end impacts at the VS 90 data base (nFs90=7482).

m · number of registered cars in Germany 1 990 Germany '

m car

(mcar=30.684.8 1 1 ). number of the considered car in Germany 1 990

NIF=1 means that the frequency of neck injury claims of the considered car is equal the frequency of the car on the road. Therefore N IF =1 can be classified as average. Cars with NIF greater than 1 represent a higher risk, a NIF lower than 1 ind icates a safer car regarding neck injuries.

The NIF for frequent car models are shown in Fig. 2.

• Energy Equivalent Speed: Deformation energy expressed as velocity

- 156 -

Fig. 2 - Neck lnjury Factor of various car models

VOLVO, all models 1Ei1Diiiico�.30i0 ________ 1 ______________ 1 MB S·Klasse W126 (80-91)

PORSCHE, all models

OPEL Rekord E Car. (78-86)

MB 200·300 W123 T (78-84)

OPEL Rekord E (78-86)

OPEL Omega A Car. (86-93)

AUDI 100 (77-a2)

OPEL Omega A (86-93)

FORD Scorpio (85- )

MB 200-300 W123 (76-84)

FORD Sierra (82·92)

BMW3„ (75-81)

MB 2Q0.300 W124 T (86-91)

MB 200-300 W124 (85-91 )

BMW 5„ (88-95 )

OPEL Kadett D Car. (80-84)

MAZDA 626 (88-92)

TOYOTA Corolla (84-87)

OPEL Vec1ra (88- )

BMW 5„ (82-a7)

TOYOTA Corolla (88-92)

AUDI 100 (83-90)

MAZDA 323 (88-a9)

OPEL Ascona C (82-aB)

AUDI 80/90 (79-86)

MB 190 (83-93)

VW GoW II (84-91)

BMW 3„ (82·90)

OPEL Kadett E Car. (85-91)

FORD Escort (81·90)

VW Polo (75-81)

VWGoW 1 (74-a3)

OPEL Kadet1 E (85-91 )

AUDI 80190 (87 ·94)

FIAT Panda (8(). )

PEUGEOT 205 (83- )

OPEL Kadett D (80-84)

OPEL Corsa A (83-92)

VW Polo (82·94)

1600 kg

1300 kg

1100 kg

1500 kg

1100 kg

1300 kg

1200 kg

1200 kg

1300 kg

1400 kg

1100 kg

1000 kg

1500 kg

1400 kg

1400 kg

900 kg

1 •

1050 kg

1200 kg

1000 kg

1300 kg

900 kg

1000 kg

0,54

0,55

0,58

59

59

0,61

0,65

0,65

0,67

0,68

0,70

0,70

0,71

0,72

0,74

0,77

0,80

0,83

0,84

0,85

0,85

0,87

0,89

0,8

1000 kg 0, 3

1200 kg

900 kg

1200 kg

900 kg

900 kg

700 kg

800 kg �

900 kg � 1100 kg

750 kg �

850 kg

800 kg

800 kg

750 kg

,96 0,97

1,04

1,04

FIAT Uno (83-93) " 1 •

RENAULT R5 (85-91)

NISSAN Micra (83-92)

FORD Fiesta (84-a8)

FORD Fiesta (76-a3)

FORD Fiesta ( 89- )

800 kg

700 kg

800 kg

700 kg

800 kg

0,0 1 ,0

1,12

1 ,14

,25

,25

1,29

31

1,34

1,37

1,37

1,38

1,44

,48

1,53

1,64

2,0

The NIF of the worst car is 5.5 times higher than the best in this study. This means that in the case of a rear end impact the risk of neck injuries is 5.5 times higher for the worst than for the best car.

- 157 -

Comparing the results to v Koch et al ( 1 995) a correlation coefficient between NIF and the "relative injury risk" r=0.77 can be observed (considering 21 car models which can be compared directly). The problem is that the factors are evaluated with d ifferent methods and do not belong to the same sample. Nevertheless both studies show similar tendencies and illustrate the fact that there is a clear influence of the car model on the risk of neck injury.

The NIF includes the influence of the car mass. The ratio of the masses of the two involved cars influences the change of velocity of the struck car. Fig. 3 shows the mass distribution of the struck and the striking car. 1 00% corresponds to all rear end collisions with neck injury claims in VS 90.

30

25 f 1 20

�15 1

10

5

0 "'

.X 8 .... 2 Q. "

Fig. 3 - Mass distribution of striking and struck car

"' .X "' .X "' .X "' .X "' .X � "' .X "' .X "'

.X "' .X "' .X "' .X

� � 8 .... CD

§ 8 8 � 8 § § 8 � § N ..,. .... � � § � 8 � � � � 8 � � ;! � � mass of cars

--+--striking car, n=5570 - • - struck car, n=6909

� § � §

§

' 1 i 1 i 1

N C>I � .X .& "'

Among cars of low mass (1 100 kg or less) more struck than striking cars can be observed. Among heavy cars (1 1 00 kg or more) the situation is turned upside down, consequently the risk of neck injury is higher when a heavy car strikes a car of low mass. The ratio of car masses is an important factor regarding the risk of neck injury but improvement can only be achieved by producing cars of equal mass which is an unrealistic scenario.

A lot of further influences like age and sex of the injured person, impact direction and offset of the collision, stiffness of car structure etc. were also investigated (Eichberger, 1 995), but it was not possible to isolate the influence of the car seat which was considered to be the most important factor. For this reason sied tests with volunteers where performed.

SLED TESTS - The aim was to get a ranking of the tested seats and to compare it to the Neck lnjury Factor (NIF) of the statistics. Sied deceleration was measured using a Kienzle UDS™, an accident data recorder mounted on the sied. The volunteers were equipped with two 3-axis accelerometers. The head accelerometer was mounted near the estimated center of gravity of the head. The torso accelerometer was mounted in front of the ehest, approx. the

- 158 -

same area as the torso accelerometer of the dummy (Geigl, 1994). At the same locations targets for the high speed video analysis were fixed.

Fig. 4 shows the acceleration behavior of sied, torso and head for one test. Head and torso accelerations are resultant of the triaxial accelerations. The corresponding relative angular displacement between head and torso is shown in Fig 5. The angular displacement was measured by analyzing the High Speed Video. The angle between head and torso at tO (first contact of sied and deformation element) was defined 0 and the relative angle between head and torso was calculated for the whole impact.

Fig 4 - Acceleration behavior of sied, torso and head

Head (Resultant) 8 Torso (Resultant)

:§i Sied (X-direction) g 6 1 � 4 +--.--+--+--+-�-l-�---+--,�f.J..d-.:��4-�-"--�--l-�"-1-�--l-�� Cl) ä) 8 2 +--l-�r/U-J��=----:;���....._,rl----,..4-�-l---4---!-�-!-�4-���--J <

�-l--'---l-....__-+-....__-+-....__-+-....__-+-�_.__._-l-_._-4-_._-1-_._-l-_._-l--"----1

0 1 5 � � 1 0 „ :g 5

:c - 0 c: Cl) E -5 Cl) (,) ra -10 c. .!!? -15 c ... .!! -20 =

g>-25 < -30

0 20 40 60 80 1 00 120 140 160 1 80 200 220 240 Time [ms]

Fig. 5 - Relative rotation between head and torso

1 1 1

1 1 1 1 i l Flexion 1

/ "" 1 1 / i--..._ - 1 7! -

j � 1 1

i 1 i \ 1 ,17 : 1 \ 7 1 1 '

Extension \ i..- l J 1 \.../ "---u

' 0 20 40 60 80 1 00 120 140 160 180 200 220 240

Time [ms]

- 1 59 -

After full contact with the seat back (40 ms) the torso is accelerated while the head remains in its initial position. Significant head acceleration starts after 1 00 ms. This delay of head and torso acceleration results in a relative motion between head and torso (Fig. 4). From the high speed video analysis, it can be observed that head - head restraint contact occurs at approx. 1 30 ms. This means that the forces and moments causing the head acceleration (up to 4g before contact) and head rotation between 1 00 and 1 30 ms have to be exerted by the neck (Fig. 5). The maximum head acceleration is reached after head -head restraint contact. Elasticity of the seat leads to a rebound after approx. 200 ms.

A ranking of the tested seats was evaluated by a point system (Eichberger, 1 995). The following characteristics were taken into account by grading, using a scale from 0 to 50 (50 points = theoretical maximum): • the height of the head restraint (distance between top of the head and top of the head restraint of various volunteers): 0 to 1 5 points • the horizontal gap between head and head restraint (for a realistic seating position): 0 to 1 0 points • the shape of the head restraint (size, curvature): 0 to 5 points • padding of the head restraint (hard-soft): 0 to 5 points • kinematics of the volunteers (angular displacements, accelerations): 0 to 1 0 points • characteristics of the seat back (elasticity, stiffness): 0 to 5 points

Fig. 6 shows this ranking as percentage of the theoretical maximum:

(i) "C 0 ::!!; ... CU (.)

Fig. 6 - Seat ranking of the sied test experiments

Porsche 9 1 1 , '88 - 76 % 1

BMW 5 .. '92 64 %

MB W124, '87

Audi 80, '88

VW Golf I I I , '93

MAZDA 323 '89

Ford Escort '85

VW Golf I I , '89

64 %

percentage of theoretical maximum

1 1 l 1

No tested seat was considered to be optimal ( 1 00 %). Due to the comparatively high mounted integral head restraint, the low horizontal distance

- 160 -

and other construction details, the seat of Porsche 91 1 was the best of the tested seats. In several tests of lower ranked seats the volunteers suffered from smaller neck complaints the next day which lasted for approx. 24 hours. For one test the volunteer complained about symptoms of cervical distortion for about two weeks.

Due to their poor seat design four additional seats could not be tested since the neck injury risk for the volunteers was obviously too high.

Fig. 7 - Correlation between horizontal d istance and angular d isplacement

1 35 T • 1 c smaller 1 Q) Q)

complaints I � initial contact between ' Q) 30 • 1 ..c head and head restraint - ..... c t... Q) -E c Q) .2 • • c.> III ns c - Q) • c. _ .!!? >< symptoms of "C .!.. ... 0 • cervical � f ::::1 0 distortion cn _ • c "C ns c • g! ns

1 0 :o:; "C ns ns • • - Q) • e .c • ftj E ';( ns E 0

0 20 40 60 80 1 00 120 140

horizontal distance between head and headrest [mm]

The relationship between the horizontal distance and the peak value of the angular displacement between head and torso can be seen in Fig. 7. The risk of neck injury rises with horizontal distance since all complaints reported by volunteers occurred at high d istances. Therefore a low horizontal d istance between head and head restraint is very important for a good seat design. Even a head restraint placed high enough can only prevent neck injuries when the head is sustained as soon as possible by the head restraint during rear end collision.

COMPARISON OF STATISTICAL AND EXPERIMENTAL DATA - The relation between the Neck lnjury Factor (NIF) from real crash statistics and the seat ranking from the sied tests is shown in Fig. 8.

- 161 -

Fig. 8 - Comparison between Neck lnjury Factor (NIF) and seat ranking

... CU ()

BMW 5 .. „ '92

MAZDA 323, '89

Wo/ Golf II , '89

FORD Escort, '85

AUDI 80, '88

OPEL Corsa A, '85

1 . -•. „ _ " 1

1 J • Neck Factor [%] 1 1

1 1 1 1 1 a seat Ranking [%]

1 1

1

0 1 0 20 30 40 50 60 70 80 90 100

[%]

For the purpose of this comparison the best NIF (Volvo: 0.299) was defined to 1 00% and the worst (Ford Fiesta: 1 .635) to 0%. The correlation between the neck injury factor from real crashes and the seat ranking is good.

For one car model (AUDI 80) a considerable difference could be observed. The seat of the AUDI 80 was the only one in the test series with a frame design of the head restraint. This was not considered in the point system of the seat ranking and may increase the risk of neck injury. For the OPEL Corsa A the seat ranking is d istinctly better than the NIF which may reflect the influence of the car mass.

SUMMARY AND CONCLUSIONS

lt was shown that the relationship between the frequency of neck injuries at rear end impacts in actual crashes and the car seat "ranking" from experimental tests with volunteers was close. Compared to other influences (car mass, physiognomy of the passenger, angle of collision, „ .) the seat and its head restraint is the most important fact. Therefore it is possible to decrease the risk of neck injury by optimizing the car seat design (Muser et al, 1 994). The most important design parameters are a low horizontal d istance between head and head restraint as well as the head restraint height. In Fig. 9 the recommendation of the VdS (VdS, 1 994) about correct adjustment of the head restraint is shown.

- 162 -

Fig. 9 - Recommendation of the VdS on correct head restraint adjustment

Low horizontal distance

Topofhead = Top ofhead restraint

Unfortunately only a few cars are equipped with seats that allow correct adjustment.

Furthermore stiffness and elasticity of the seat frame, padding of the seat (higher damping rate) and ergonomics are to be optimized. Also the possibility of misadjustment should be reduced, e.g. by integrated head restraints. The fact that the average change of velocity of the struck car is comparatively low (approx. 1 O to 1 5 km/h) makes clear that improvements are possible.

About 20% of the neck injury claims occurred at an �V lower than 8 km/h and without thorough medical check-up. In the author's opinion, these cases can be considered as the lower limit of pretended injuries. Therefore a tot of neck injuries can be considered as "extra money" for the crash victim. lt is the task of the insurance companies (crash reconstruction, objective medical certificates) to deal with this aspect.

The results of this study suggest that many neck injuries caused by rear end collisions can be avoided simply by optimizing the seat design. Minimum requirements should be specified by regulations for seat and head restraint design. A detailed medical examination and a crash reconstruction for each case will decrease the number of pretended injuries.

REFERENCES

Deutscher C. : Bewegungsablauf von Fahrzeuginsassen beim Heckaufprall Eurotax (International) AG, 1994, ISBN 3-9520040-9-X

Eichberger A. : Beschleunigungsverletzungen der Halswirbelsäule bei PKW/PKW­Heckkollisionen im realen Unfallgeschehen. Diploma thesis, University of Technology Graz, Austria 1 995

- 1 63 -

Geigl B. C. , Steffan H. , Leinzinger P. , Roll, Mühlbauer M . , Bauer G. : The Movement of Head and Cervical Spine during Rear End Impact. Proceedings of the 1 994 International IRCOBI Conference on the Biomechanics of Impacts, pp 127 - 1 37, Lyon, France 1 994

Geigl B. C. , Steffan H. , Dippel C. , Muser M. H. , Walz F. , Svensson M. Y: Comparison of Head-Neck Kinematics during Rear End Impact between Standard Hybrid I I I , RIO Neck, Volunteers and PMTO's Proceedings of the 1 995 International IRCOBI Conference on the Biomechanics of Impacts, pp 261 - 270, Brunnen, Switzerland 1 995

Vehicle Safety 90: Analysis of Car Accidents. Foundations for Future Research Werk Publ.: VdS, Verband der Schadenversicherer e. V., Munich 1 994

Muenker , Langwieder K., Chen, Hell W. : HWS Beschleunigungsverletzungen. Verband der Schadenversicherer, Büro f. Kfz-Technik, Munich, 1 994

Muser M. H„ Dippel Ch., Walz F. : Neck lnjury Prevention by Automatically Positioned Head Restraint Proc. 1994 AAAM/ IRCOBI Conf. Joint Session, Lyon, France.

Scott M. W. , McConnell W. E. et al: Comparison of Human and ATD Head Kinematics During Low-Speed Rearend Impacts. SAE SP 945, SAE 930094, 1 993

v. Koch M. , Kullgren A., Lie A., Nygren A., Tingvall C . : Soft Tissue lnjury of the Cervical Spine in Rear-End and Frontal Car Collisions. Proceedings of the 1 995 International IRCOBI Conference on the Biomechanics of Impacts, pp 273 - 282, Brunnen, Switzerland 1 995

- 164 .