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User's Manual for the BIOSID Side Impact Test Dummy (Sept. 2007) SAE Product Code: EA-24 This 42 page user's manual covers the Biosid 50th Percentile Male side impact crash test dummy. It is intended for use by technicians who work with this device. It covers the construction, assembly and disassembly, available instrumentation, external dimensions and segment masses, as well as calibration test procedures.

Eyellipse and Head Contour Locator Line - Adjustable Seat SAE Product Code: EA-5 The EA-5 is a drafting tool that describes the position of the eyellipse and the occupant head contour for horizontally adjustable seats with back angles between 5 and 40 degrees. Note! This product will be discontinued when current stock is depleted.

SAE J1052 Mar87 Motor Vehicle Driver and Passenger Head Position SAE Product Code: EA-6 The templates are two-dimensional shapes that describe the seated vehicle occupant head positions in side and rear view. The driver head position contours with seat travel apply to drivers in horizontally adjustable seats. The head position contours without seat travel apply to both drivers and passengers in fixed seats. Note! This product will be discontinued when current stock is depleted. The templates are two-dimensional shapes that describe the seated vehicle occupant head positions in side and rear view. The driver head position contours with seat travel apply to drivers in horizontally adjustable seats. The head position contours without seat travel apply to both drivers and passengers in fixed seats.

Honda R&D Technical Review is a periodical containing research papers related to Honda R&D Center activities worldwide that cover automobile, motorcycle, power products, aircraft engine, and other fundamental technologies. Honda Motor offers a book for the April 2021 issue with 104 pages containing 12 papers focusing on the following latest topics: Technology for Prediction of Contactor Noise for Electric-powered Vehicle Batteries Reduction of Internal Resistance in High Capacity Lithium-ion Batteries with 3D Lattice-structured Electrode Predictive Technique for Seat Belt Submarining Injury by Triaxial Iliac Load Cell

User's Guide for the Six Month Old Infant Dummy (CRABI) (June 1995) SAE Product Code: EA-28 This 31 page user's manual covers the 6-month-old Child Restrain Air Bag Interaction (CRABI) infant dummy. It is intended for use by technicians who work with this device. It covers the construction and clothing, assembly and disassembly, available instrumentation, external dimensions and segment masses, as well as calibration test procedures. It includes instructions for joint adjustment and skin repair.

The 16 papers in this technical paper colection present advancement of auto safety-related technologies that deal with roof crush testing, pedestrian safety, front, side and rear impact, simulation of interior head impact, FE study of factors on risk of KTH injuries in frontal impact, CAE methods and testing, and field modeling and assessment techniques.

This technical paper collection contains 20 papers presenting new technologies and research in the area of vehicle rear-end collision, rollover collision and lateral impacts. Papers may be related to analysis of crash compatibility, statistical data analysis, design of vehicle systems, biomechanics and dummy development. To see a listing of papers included in this special publication, click on the papers link below.

The 24 vehicle aerodynamic papers in this technical paper collection cover topics such as cooling airflow, aerodynamic optimization and aero add-ons, transient flows and effects, and wind tunnel development and simulation tools.

This technical paper collection contains 11 papers that focus on occupant protection biomechanics.

"Spotlight on Design" features video interviews and case study segments, focusing on the latest technology breakthroughs. Viewers are virtually taken to labs and research centers to learn how design engineers are enhancing product performance/reliability, reducing costs, improving quality, safety or environmental impact, and achieving regulatory compliance. Sensors are essential to the safety, efficiency, and dependability of modern vehicles. Crash sensors can anticipate a collision faster than humans would, and tire pressure sensors can alert the driver or pilot in case action is needed. In the episode "Sensors: Advanced Safety" (20:36) Continental engineers look at the evolution of passive safety systems, discuss the changes in sensors over the last ten years and what is coming next. Engineers at Meggitt demonstrate how tire pressure monitoring system sensors for aerospace are built and tested.

"Spotlight on Design" features video interviews and case study segments, focusing on the latest technology breakthroughs. Viewers are virtually taken to labs and research centers to learn how design engineers are enhancing product performance/reliability, reducing cost, improving quality, safety or environmental impact, and achieving regulatory compliance. In the episode "Automated Vehicles: Sensors and Future Technologies" (24:31), highly automated driving is looked at in detail as the culmination of years of research in automotive technology, sensors, infrastructure, software, and systems integration. Real-life case studies show how organizations are actually developing solutions to the challenge of making cars safer with less driver intervention. IAV Automotive Engineering demonstrates how a highly automated vehicle capable of lane changing was created.

"Spotlight on Design: Insight" features an in-depth look at the latest technology breakthroughs impacting mobility. Viewers are virtually taken to labs and research centers to learn how design engineers are enhancing product performance/reliability, reducing cost, improving quality, safety or environmental impact, and achieving regulatory compliance. Automated driving is made possible through the data acquisition and processing of many different kinds of sensors working in unison. Sensors, cameras, radar, and lidar must work cohesively together to safely provide automated features. In the episode "Automated Vehicles: Converging Sensor Data" (8:01), engineers from IAV Automotive Engineering discuss the challenges associated with the sensor data fusion, and one of Continental North America’s technical teams demonstrate how sensors, radars, and safety systems converge to enable higher levels of automated driving.

The three major challenges in the power electronics in hybrid and electric vehicles are: System cost, power density and reliability. High temperature power device and packaging technologies increases the power density and reliability while reducing system cost. Advanced Silicon devices with synthesized high-temperature packaging technologies can achieve junction temperature as high as 200C (compared to the present limitation of 150C) eliminating the need for a low-temperature radiator and therefore these devices reduces the system cost. The silicon area needed for a power inverter with high junction temperature capability can be reduced by more than 50 - 75% thereby significantly reducing the packaging space and power device and package cost. Smaller packaging space is highly desired since multiple vehicle platforms can share the same design and therefore reducing the cost further due to economies of scale.

Ford's thermal management with batteries. Presenter Robert Taenaka, Ford Motor Co.

SAE 2011 High Efficiency IC Engines Symposium - Session 3 - Advanced Diesel Engine Technologies Presenter Andrew Brown, Delphi Corp.

Despite significant investment by both government and industry, the electric vehicle is not achieving the market share needed to make a significant impact on carbon emissions and energy independence. This presents some particular questions to policymakers and manufacturers; how to overcome the barriers to development and adoption in a tough economic climate? how can industry be encouraged to develop electric vehicle technology that meets consumers performance and pricing needs and how can consumers be encouraged to buy? The dramatic reductions in CO2 emissions required by international law present some formidable targets that need to be met over the coming two decades. How can we accelerate EV adoption to help achieve them?