Afton Chemical Corporation The Importance of Lubrication in Sheet Metal Selection for Automotive Body Construction The Drive to Lightweight Materials Introduction by Bill Harwood, Marketing Manager-Metalworking, Afton Chemical Corporation, www.aftonchemical.com Article by Daniel J. Schaeffler, Ph.D., President, Engineering Quality Solutions, Inc., www.EQSgroup.com
Introduction Automakers today are met with a unique manufacturing challenge: balancing efficiency with safety. While vehicle manufacturers have embraced lightweighting, or using lighter metals to help produce lighter vehicles that meet government efficiency standards, they most also work to use material that is robust enough to provide crash and safety regulations. In this article, Daniel J. Schaeffler, Ph.D., President, Engineering Quality Solutions, Inc., discusses how the right lubrication can help automakers achieve a smooth transition to lightweight materials without sacrificing safety and performance. For more information about how Afton additives can help achieve the ideal lubrication, contact your Afton representative at www.aftonchemical.com/contact.
Magnitude of the Challenge
Balancing Safety & Efficiency
Just under 18 million cars and light trucks were sold in the United States in 2016 – representing 20% of the global total. In each of these vehicles, there are about 250 stamped parts in the body-in-white (BIW). This doesn’t include the additional 350 stamped parts found in the powertrain, instrument panel, and interior components like seats. Sales of most vehicle models are between 100,000 and 750,000 units per year – meaning that hundreds of thousands of each of the 600 stampings must be produced over the course of a year, with each being dimensionally identical and split-free. This requires an optimal combination of sheet metal, part design, and stamping process design. Manufacturers target using as few parts as possible to create the vehicle. Any additional parts take more resources to design, fabricate, and join, and contribute to unnecessary additional weight. Consequently, this means having the goal of forming fewer shapes of greater complexity (larger, deeper parts) rather than more stampings of simpler shapes. The simpler the shape, the easier it is for a conventional sheet metal grade to successfully form that shape. Conversely, with complex shapes, there is an increased risk of cracking.
Every vehicle sold in the United States needs to meet numerous crash regulations—front end, rollover, and side impact, to name just a few. The easiest way to satisfy these requirements is to use thick and strong metal in the body construction. Unfortunately, thicker metals are the enemy of the lightweighting that is necessary to meet the fuel economy and emission targets mandated by the government. The challenge for automakers is to use the material that offers the best balance of weight, strength, rigidity, and cost for every part of the vehicle. Conflicting constraints from increasing vehicle safety requirements and fuel economy targets are leading to an increased use of advanced steel and aluminum alloys. A study released in 2014 (Reference 1) projects that by 2025, 40% of all body and closure panels will be made from advanced high strength sheet steel alloys (AHSS) and 16% will be made from sheet aluminum alloys. Based on 250 stamped parts in a BIW and a sales volume of 17.5 million light vehicles, by 2025 it is forecast that 1.75 billion stampings will be made from AHSS and another 700 million aluminum alloy stampings.
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T R I B O L O G Y & L U B R I C AT I O N T E C H N O L O G Y • C M F P l u s
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