Factory directly provided AISI 1053 Carbon Steel (UNS G10530) Supply to Melbourne
Chemical Composition The chemical composition of AISI 1053 carbon steel is outlined in the following table. Element Content (%) Iron, Fe 98.36-98.82 Manganese, Mn 0.7-1.0 Carbon, C 0.48-0.55 Sulfur, S 0.05 Phosphorous, P 0.04 Physical Properties The physical properties of AISI 1053 carbon steel are tabulated below. Properties Metric Imperial Density 7.7-8.03 g/cm3 0.278-0.290 l...
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The chemical composition of AISI 1053 carbon steel is outlined in the following table.
The physical properties of AISI 1053 carbon steel are tabulated below.
|Density||7.7-8.03 g/cm3||0.278-0.290 lb/in3|
The following table shows mechanical properties of AISI 1053 carbon steel.
|Elastic modulus||190-210 GPa||29700-30458 ksi|
Researchers at NC State have developed a new method to control the interfacial energy of a liquid metal via electrochemical deposition (or removal) of an oxide layer on its surface using ~1 volt.
Liquid metals have very large surface tension and therefore typically adopt a spherical shape. Surfactants, like soap, can lower the interfacial tension between two dissimilar liquids (for example, water and oil), but have negligible impact on the large interfacial tensions of liquid metal. Unlike conventional surfactants, the approach here can tune the interfacial tension of a metal significantly (from ~7x that of water to near zero), rapidly, and reversibly using only modest voltages. These properties can be harnessed to induce new electrohydrodynamic phenomena for manipulating liquid metal alloys based on gallium, which may enable shape-reconfigurable metallic components in electronic, electromagnetic, and microfluidic devices without the use of toxic mercury. The results also suggest that oxides—which are ubiquitous on most metals and semiconductors—may be harnessed to lower interfacial energy between dissimilar materials.
The paper, “Giant and Switchable Surface Activity of Liquid Metal via Surface Oxidation,” is published online in Proceedings of the National Academy. For more information, visit the website of PNAS.
The work was supported by the National Science Foundation.
Dickey Research Group: http://www.che.ncsu.edu/dickeygroup/
Rotational molding of large plastic products is an ASH specialty.
ROTO-XL™ represents ASH’s unique roto-molding division focusing on tooling & hollow thermoplastic components up to 18’ long and 52” in diameter. ROTO-XL™ molded components may be “stand-alone” or integrated with any number of other components from ASH Divisions including, CNC swiss lathe in both metal & plastic, Metal Injection Molding, and thermoplastic & silicone injection molding.
ROTO-XL™ molded components may also be foam filled, assembled, decorated, and held for drop shipping. Additional services include custom gages for quality, fixturing, foam filling (for additional rigidity & compression strength up to 1400psi), and custom thermoplastic colors. ASH ROTO-XL™ tooling may be cast in aluminum or fabricated steel.
ROTO-XL™ molding is a cost effective alternative to injection molding for large plastic parts, components which must be hollow (such as berms, barrels, canoes, kayaks, slides), and those which may be made from commodity thermoplastics (polyethylene or polypropylene).
The molds are less expensive than injection molding tooling as they do not have to be large, bulky, and built to withstand the tremendous pressures of injection molding. During ROTO-XL™, the powdered thermoplastic is placed in the mold; the mold is closed, and it is spun in three axes while being heated. After the thermoplastic has been heated and spread evenly on the inner walls of the mold, the mold is then cooled, opened, and the part removed. While it takes longer to make a ROTO-XL part than a SuperMold™ component, ROTO-XL™ may be the single unique way to address your manufacturing needs. Let our engineering staff walk you through the best choice for your project.