Development of a New Ecological Lubrication System for Sheet Metal Forming Based on CO2 in Liquid

Markus Singer; Mathias Liewald; Anne Feuer

doi:10.4028/www.scientific.net/KEM.651-653.480

Paper Titles

A Parametric Study on Compression Molding of Reference Parts with Integrated Features Using Carbon Composite Production Waste
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Nano-Structured Tungsten Carbide Coating Reduces Wear of Tooling for Extrusion and Abrasive Materials Forming
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Investigation of the Suitability of Surface Treatments for Dry Cold Extrusion by Process-Oriented Tribological Testing
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Development of a New Ecological Lubrication System for Sheet Metal Forming Based on CO₂ in Liquid
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Towards a Fracture Energy Based Approach for Wear Prediction of WC-Co Tools in Industrial Cold Heading Process
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Complementary Approaches for the Numerical Simulation of the Micro-Plasto-Hydrodynamic Lubrication Regime
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Evaluation of Tooth Surface Micro-Finishing on Gear Noise
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Fretting Fatigue on Thin Sheets
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 651-653Development of a New Ecological Lubrication System...

Development of a New Ecological Lubrication System for Sheet Metal Forming Based on CO₂ in Liquid

Abstract:

Ecological aims and political requirements today are increasing demands on lubricants in sheet metal forming and their impact on environment. For that reason, metal forming industry wants to reduce the amount of lubricants containing polluting additives with a long-term goal of avoiding lubrication entirely. Additionally, dry metal forming will reduce the cleaning steps after the forming operation. This paper shows a new tribological system in which lubrication is replaced by CO₂ in a liquid state. Here, CO₂ is expanding directly into contact area between workpiece and tool surface and changes its state from gas to solid. The combination of this particular dry ice as well as the pressure of approximately 57 atm affects resulting friction coefficient significantly. After forming operation, CO₂ medium vaporizes and a dry component can be used immediately for the next process steps. In this case, the lubricant is applied directly into the contact area. Therefore, laser drilled micro holes are located in the contact area of the tool. Very first gained experimental results disclose such feasibility, the effects and the potential of this new lubrication system at that moment is based on strip draw tests. Different numbers of micro holes are examined to support blank holder pressure ranging between 5 MPa and 6 MPa. In this investigation a mild strength steel DC04 is used as sheet material. This knowledge is aimed to be used for further investigation and later transfer into real deep and stretch forming processes.

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Periodical:

Key Engineering Materials (Volumes 651-653)

Pages:

480-485

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.651-653.480

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Online since:

July 2015

Authors:

Markus Singer*, Mathias Liewald, Anne Feuer

Keywords:

Dry Forming, Friction, Lubrication System

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