论文信息 - Numerical Simulation of Head-Disk Impacts During Dynamic Loading Processes

Numerical Simulation of Head-Disk Impacts During Dynamic Loading Processes

In order to estimate the contact stress and deformation at the instant of head-disk impact during dynamic loading, Hertz's impact theory is implemented in a dynamic loading numerical simulator. By using a finite difference model for the air bearing, a finite element model for the slider-flexure-suspension system, and Hertz's contact model of head-disk impact, we obtain estimates of contact stress, area and time through simulation of the dynamic loading process. With our choice of the material properties and geometric configurations, the duration of sliding contact is about 7 μs, the maximum width of contact is about 10 μm, and the maximum contact stress is about 620 MPa. This is below the yield stresses of the chosen media.

David B. Bogy | Tae Gun Jeong

[1] J. Greenwood,et al. Contact of nominally flat surfaces , 1966, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[2] J. N. Fawcett,et al. The Role of Elastic Tangential Compliance in Oblique Impact , 1981 .

[3] J. N. Fawcett,et al. The oblique impact of elastic spheres , 1976 .

[4] David B. Bogy,et al. An Experimental Study of the Parameters That Determine Slider-Disk Contacts During Dynamic Load-Unload , 1992 .

[5] So how hard does a head hit a disk , 1991 .

[6] Masaaki Matsumoto,et al. Measurement of Slider/Disk Collision Forces Using Acoustic Emission Source Wave Analysis , 1993 .

[7] C. Ettles. Possible Flash Temperatures in Slider and Recording Disk Transient Contact , 1986 .

[8] David B. Bogy,et al. Numerical Simulation of Dynamic Loading in Hard Disk Drives , 1993 .

[9] Bharat Bhushan. Magnetic Head-Media Interface Temperatures—Part 3: Application to Rigid Disks , 1992 .

[10] Bharat Bhushan,et al. Tribology and Mechanics of Magnetic Storage Devices , 1990 .