Echemics proposes to explore the feasibility of an innovative technology for the diamond machining of the materials that are not conventionally considered to be diamond machinable. Ultraprecision diamond machining such as diamond turning and milling has been widely used to produce optical-quality surfaces, ultra- precisely remove materials, and fabricate microstructures and microdevices with sub-nanometer level surface finishes and sub-micrometer form accuracies. It is an indispensable machining process for fabricating ultraprecision macro- and micro-optics and non-optical components for biomedical products used for biomedicine, biomedical analysis, diagnostics, and treatments. However, one significant drawback of diamond machining is that it can only machine very limited materials called diamond machinable materials. It cannot machine many important materials such as ferrous alloys, stainless steel, titanium and nickel due to catastrophic diamond tool wear. Current technical solutions for extending diamond tool life only achieve limited success; suffer from high cost and complicated setup; and need additional equipment. The chemical reactive wear of diamond tools resulting from the surface-catalyzed reaction between diamond carbon and workpiece (e.g., steel) is one significant tool wear route. However, the current technical solutions have not explored the possibility of manipulating this catalytic reaction. Therefore, this proposal tries to investigate a novel approach to stop or slow down this catalytic reaction so that the high reaction rate can be greatly reduced and tool life can be extended. In this Phase I project, Echemics aims to prove if the proposed technical approach can indeed extend diamond tool life compared with normal diamond machining. If Phase I is successful, Phase II of the project will improve the process and fabricate some prototype biomedical products. As there is an increasing demand for directly diamond machining non-diamond machinable materials for a wide variety of biomedical and other applications, this proposed technology provides a new solution for this call. If successful, Echemics aims to commercialize this novel technology for growing the company and also making the country's ultraprecision manufacturing sector more competitive. This SBIR Phase I project will explore the feasibility of an innovative technology for the ultraprecision diamond machining of the materials that are not conventionally considered to be diamond machinable. Diamond machining is an indispensable machining process for fabricating ultraprecision macro- and micro- optics and non-optical components for biomedical products, including such as diagnostic imaging devices, drug delivery components, implantable components, lab-on-a-chip devices, micro total analysis systems (?-TAS), and MEMS (MicroElectroMechanical Systems) for biomedicine, biomedical analysis, diagnostics, and treatments. The proposed technology aims to fabricate totally new devices, improve the quality of existing devices, lower manufacturing costs, and become a more universal rapid prototyping tool. ? ? ?

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Small Business Innovation Research Grants (SBIR) - Phase I (R43)
Project #
1R43EB007412-01
Application #
7265234
Study Section
Special Emphasis Panel (ZRG1-BST-G (11))
Program Officer
Lee, Albert
Project Start
2007-05-01
Project End
2007-10-31
Budget Start
2007-05-01
Budget End
2007-10-31
Support Year
1
Fiscal Year
2007
Total Cost
$97,099
Indirect Cost
Name
Echemics
Department
Type
DUNS #
170257500
City
Monterey Park
State
CA
Country
United States
Zip Code
91754