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The Isodamp damping material (also known as Navy Damp) used in the ribs of current crash test dummies provides human-like damping to the thorax under impact. However, the range of temperature over which it can be used is very small. A new rib design using laminates of steel, fiberglass, and commercially available viscoelastic material has been constructed. Load-deflection response and hysteresis of the laminated ribs were compared with corresponding conventional ribs fabricated from steel and Isodamp. Impact tests were conducted on laminated and conventional ribs at 18.5° C, 22.2° C and 26.6° C. Results indicate that the response of the laminated ribs is essentially the same as that of the ribs with Isodamp at 22.2° C, which is the operating temperature of the conventional ribs. The variation in the impact response of the newly developed laminated ribs in the temperature range of 18.5° C to 26.6° C was less than 10%.

A new lower leg/ankle/foot system has been designed and fabricated to assess the potential for lower limb injuries to small females in the automotive crash environment. The new lower extremity can be retrofitted at present to the distal femur of the 5th percentile female Hybrid III dummy. Future plans are for integration of this design into the 5th percentile female THOR dummy now under development. The anthropometry of the lower leg and foot is based mainly on data developed by Robbins for the 5th percentile female, while the biomechanical response requirements are based upon scaling of 50th percentile male THOR-Lx responses. The design consists of the knee, tibia, ankle joints, foot, a representation of the Achilles tendon, and associated flesh/skins. The new lower extremity, known as THOR-FLx, is designed to be biofidelic under dynamic axial loading of the tibia, static and dynamic dorsiflexion, static plantarflexion and inversion/eversion.

A new pedestrian dummy, called ""POLAR'' has been recently developed. It can be used as a tool not only for the investigation of the mechanism of pedestrian accidents, but also for the assessment of vehicle aggressiveness to pedestrians. This dummy is modified from "'THOR,'' new- generation occupant dummy, in its body structure to reproduce human body kinematics in the event of collision with a vehicle more precisely. Its knee has a human-like structure, with condyles which shape is similar to that of human knee, meniscus, cruciate ligaments and collateral ligaments. Tibias of Polar are made of urethane which bending characteristic is that of human tibia. These features not only make the lateral bending and shearing responses of the leg and knee more human-like but also the whole body kinematics more human- like.

Early influences upon Thor ATD development are described, and the path of Thor development is traced up to the release of the current Thor ALPHA ATD design. Since the display of the first Thor ATD prototype at the 15th ESV Conference in Melbourne in 1996, Thor has undergone extensive test and evaluation on an international basis in cooperation with many partner institutions. This paper summarizes some of the lessons learned from this broad test experience, and documents actions which have been undertaken to upgrade the Thor product to ALPHA status in light of this experience.

Research into pedestrian protection has been carried out since the 1960s, in recent years there have been proposals in Europe to legislate requirements in this area and therefore the research is becoming more focused. In the draft regulation, impactor tests have been proposed as a method for evaluating the impact caused by vehicles'' body for pedestrians. This paper introduces impactor model and actual vehicle analysis as a means for simulating impactor testing. Three types of impactors for vehicle tests are presented. It is necessary that the models are first matched with the results of the calibration tests, then matched with the results of the tests on actual vehicles.

A new lower extremity has been developed to be used with Thor, the NHTSA Advanced Frontal Dummy. The new lower extremity, known as Thor-Lx, consists of the femur, tibia, ankle joints, foot, a representation of the Achilles' tendon and the associated flash/skins, it has been designed to improve biomechanical response under axial loading of the femur during knee impacts, axial loading of the tibia, static and dynamic dorsiflexion, static plantarflexion and inversion/aversion. Instrumentation includes a standard Hybrid ill femur load cell, accelerometers, load cells, and rotary potentiometers to capture relevant kinematic and dynamic information from the foot and tibia. The design also allows the Tnor-Lx to be attached to the Hybrid III, either at the hip, or at the knee.

New vehicle body structure was developed that reduce pedestrian head injury in traffic accidents. The structure was developed to be incorporated into mass production models. This report show the concrete examples and performance of the structure. At first this paper describe application area of vehicle and injury criteria. During development, it is nessesary to fine control of load characteristic especially at the place that cannot make long stroke. The difference of each structures arrived to some kinds of pattern of energy absorb structure. Next problem was to satisfy another basic performance of the body structure, for example panel stiffness, noise vibration. Generally, automotive engineers focus their efforts on increasing body strength in order to improve body performance. The new structures were developed to satisfy the target for energy absorption characteristics, and also provide a sufficient level of body strength.

Honda has been studying ways of improving vehicle design to reduce the severity of pedestrian injury. Full-scale test using a pedestrian dummy is an important way to assess the aggressiveness of a vehicle to pedestrians. However, from test results it is concluded that current pedestrian dummies have stiffer characteristics than Post Mortem Human Subjects (PMHS). Also, the dummy kinematics during a collision is different from that of a human body. Because of the limitations of current dummies, it was decided to develop a new pedestrian dummy. At the first stage of the project, a computer simulation model that represented the PMHS tests was developed. Joint characteristics obtained from the simulation model were used in building a new pedestrian dummy which has been named Polar I. The advanced frontal crash test dummy, known as Thor, was selected as the base dummy. Modifications were made for the thorax, spine, knee etc.

The motion of occupants seated in a typical side facing seat in a general transport aircraft was analyzed using the DYNAMAN simulation program. This paper presents the results of the first phase of the study, where simulations were performed to validate the computer model against a set of tests performed at CAMI using Hybrid II and Hybrid III dummies. There was usually good agreement between test and simulation of the pelvic and chest accelerations, and right side lap belt and shoulder belt loads. The head accelerations tended to be underestimated and the neck and pelvic loads and moments overestimated in the simulations. The only injury parameter which consistently exceeded the tolerance value was the lateral moment at the head-neck junction.