Comparison of child and ATD belt fit and posture on belt-positioning boosters during self-selected, holding device, and nominal conditions

Gretchen H Baker; Katarina Bohman; Julie A Mansfield; Lotta Jakobsson; John H Bolte 4th

doi:10.1016/j.aap.2023.107280

Comparison of child and ATD belt fit and posture on belt-positioning boosters during self-selected, holding device, and nominal conditions

Accid Anal Prev. 2023 Nov:192:107280. doi: 10.1016/j.aap.2023.107280. Epub 2023 Sep 10.

Authors

Gretchen H Baker¹, Katarina Bohman², Julie A Mansfield³, Lotta Jakobsson², John H Bolte 4th³

Affiliations

¹ Injury Biomechanics Research Center, the Ohio State University. 2063 Graves Hall, 333 W 10(th) Ave, Columbus, OH 43210, USA. Electronic address: Gretchen.Baker@osumc.edu.
² Volvo Cars Safety Centre, 405 31 Göteborg, Sweden.
³ Injury Biomechanics Research Center, the Ohio State University. 2063 Graves Hall, 333 W 10(th) Ave, Columbus, OH 43210, USA.

PMID: 37699266
DOI: 10.1016/j.aap.2023.107280

Abstract

Objective: Pediatric anthropomorphic test devices (ATDs) are important tools for the assessment of child occupant protection and should represent realistic child belt fit and posture on belt-positioning boosters. Previous comparisons have been made to children in either self-selected or nominal postural conditions. This study compares belt fit and postural measurements between pediatric ATDs and a single cohort of children assuming different postures on boosters: self-selected, holding a portable electronic device, and nominal.

Methods: A cohort of children (n = 25) were evaluated in a stationary vehicle on five boosters and in three postural conditions: nominal, self-selected, and a representative holding electronic device position. The Hybrid III 6- and 10-year-old and Q-Series 6- and 10-year-old ATDs were evaluated in the same five boosters and in two postural conditions: nominal and a representative holding electronic device position. A 3D coordinate measurement device was used to quantify belt fit (shoulder belt score, lap belt score, maximum gap size, and gap length) and anatomic landmark positions (head, suprasternale, ASIS, and patella). Landmark positions and belt fit were compared between ATDs and children for each booster and postural condition, and Pearson correlations (r) were assessed across boosters.

Results: ATDs generally represented Nominal child postures across boosters. In the Device condition, ATDs were seldom able to be positioned to represent both the torso and head position of children, due to limited ATD spinal flexibility. When the torso position was matched, the ATD head was more rear by 63 mm. Correlations between Nominal child and ATD belt fit and belt gap metrics were generally weak and not significant, with the exception of lap belt score (all ATDs p < 0.07, r = 0.8549-0.9857).

Discussion: ATDs were generally able to represent realistic child postures and lap belt fit in Nominal and short duration Self-selected postures in a laboratory setting. However, these results display the potential difficulty of utilizing ATDs to represent more naturalistic child postures, especially the more forward head positions and flexed spinal posture associated with utilizing a portable electronic device.

Keywords: Belt-positioning Booster; Child Restraint System; Pediatric ATD; Posture; Seat Belt Fit.

MeSH terms

Accidents, Traffic*
Benchmarking*
Child
Humans
Posture
Seat Belts
Torso