Load Capacity and Durability of H-DLC Coated Hydrodynamic Thrust Bearings

Hydrogenated diamondlike carbon (H-DLC) coatings provide excellent wear resistance and low friction for bearing applications. However, the use of such coatings with aqueous lubricants could pose some difficulties due to the hydrophobic nature of the surface. A thrust bearing tribometer was used to compare performance of hydrophilic and hydrophobic surfaces in hydrodynamic lubrication with a mixture of water and glycerol as the lubricant. Hydrophobic surfaces on both runner and bearing were achieved with the deposition of H-DLC films on titanium alloy surfaces. Hydrophilic surfaces were created through modification of H-DLC surface with covalently bonded heparin. Several possible combinations of hydrophobic and hydrophilic surface conditions were used on the bearing and runner surfaces to provide full-wetting, partial-wetting, and half-wetting conditions. The experimental results confirmed that load support is still possible, when the bearing is half-wetted or partially wetted. However, the full-wetted bearing combination (i.e., Reynolds no-slip boundary condition) provided the highest load support. Introduction of slip at the surface resulted in a lower measured torque. Heparin treatment resulted in a lower than expected static friction and friction in full lubrication regime. The durability of coated surfaces was evaluated in a series of start–stop tests and in impact tests. The results confirmed that the coatings are stable and survive the test regiment that exceeded 50 test cycles; whereas the uncoated titanium alloy bearing surfaces were damaged after ten test cycles.

[1]  Hugh Spikes,et al.  A Low Friction Bearing Based on Liquid Slip at the Wall , 2006 .

[2]  Hiroshi Udagawa,et al.  Drag reduction of Newtonian fluid in a circular pipe with a highly water-repellent wall , 1999, Journal of Fluid Mechanics.

[3]  A. Lehninger Principles of Biochemistry , 1984 .

[4]  D. Williams,et al.  Shear-dependent boundary slip in an aqueous Newtonian liquid. , 2001, Physical review letters.

[5]  Prof. Dr. med. Gustav Steinhoff,et al.  Minimizing Cardiopulmonary Bypass Attenuates Myocardial Damage After Cardiac Surgery , 2007, ASAIO journal (1992).

[6]  Richard F. Salant,et al.  Numerical Analysis of a Journal Bearing With a Heterogeneous Slip/No-Slip Surface , 2005 .

[7]  A. Gonzalez-Elipe,et al.  Biocompatible surfaces by immobilization of heparin on diamond‐like carbon films deposited on various substrates , 2000 .

[8]  S. Troian,et al.  A general boundary condition for liquid flow at solid surfaces , 1997, Nature.

[9]  Maurizio Fermeglia,et al.  Virtual rheological experiments on linear alkane chains confined between titanium walls , 2001 .

[10]  Derek Thompson,et al.  Ceramics: Tough cookery , 1997, Nature.

[11]  S. Granick,et al.  Rate-dependent slip of Newtonian liquid at smooth surfaces. , 2001, Physical review letters.

[12]  C. Zapanta,et al.  Performance characterization of a rotary centrifugal left ventricular assist device with magnetic suspension. , 2008, Artificial organs.

[13]  S. Jahanmir,et al.  Design Analysis and Performance Assessment of Hybrid Magnetic Bearings for a Rotary Centrifugal Blood Pump , 2009, ASAIO journal.

[14]  Hooshang Heshmat,et al.  On a common tribological mechanism between interacting surfaces , 1989 .

[15]  Richard F. Salant,et al.  Numerical Analysis of a Slider Bearing with a Heterogeneous Slip/No-Slip Surface , 2004 .

[16]  I. L. Singer,et al.  Superlow friction behavior of diamond-like carbon coatings: Time and speed effects , 2001 .

[17]  B. Ratner Blood compatibility — a perspective , 2000, Journal of biomaterials science. Polymer edition.

[18]  Jože Vižintin,et al.  The Stribeck curve and lubrication design for non-fully wetted surfaces , 2009 .

[19]  Liliane Léger,et al.  Friction and slip of a simple liquid at a solid surface , 1999 .

[20]  Hooshang Heshmat Tribology of Interface Layers , 2010 .

[21]  Klaus Affeld,et al.  The effect of surface roughness on activation of the coagulation system and platelet adhesion in rotary blood pumps. , 2007, Artificial organs.

[22]  C. Beythien,et al.  In vitro analyses of diamond-like carbon coated stents. Reduction of metal ion release, platelet activation, and thrombogenicity. , 2000, Thrombosis research.

[23]  Hooshang Heshmat,et al.  Design of a small centrifugal blood pump with magnetic bearings. , 2009, Artificial organs.

[24]  W. A. Gross,et al.  Fluid film lubrication , 1980 .

[25]  H. Heshmat,et al.  The quasi-hydrodynamic mechanism of powder lubrication. I: Lubricant flow visualization , 1992 .

[26]  Robert A. Peura,et al.  Cardiac Assist Devices , 1986, IEEE Engineering in Medicine and Biology Magazine.

[27]  H. Reul,et al.  Investigation of materials for blood-immersed bearings in a microaxial blood pump. , 2003, Artificial organs.

[28]  S. Granick,et al.  Limits of the hydrodynamic no-slip boundary condition. , 2002, Physical review letters.

[29]  H. Heshmat,et al.  The quasi-hydrodynamic mechanism of powder lubrication. Part II: Lubricant film pressure profile , 1992 .

[30]  H. Spikes The half-wetted bearing. Part 1: Extended Reynolds equation , 2003 .