Drop test simulation and power spectrum analysis of a head actuator assembly in a hard disk drive

This work aims to develop a method for predicting the displacement and failure of the Head Actuator Assembly (HAA) during a drop test. When a Hard Disk Drive (HDD) is dropped from a certain height, it will accelerate due to gravity until it hits the ground with a certain speed, and the head suspensi...

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Veröffentlicht in:	International journal of impact engineering 2007, Vol.34 (1), p.120-133
Hauptverfasser:	Shi, Bao-Jun, Shu, Dong-Wei, Wang, Shao, Luo, Jun, Meng, Hui, Ng, Quock, Lau, Joseph H.T., Zambri, Razman
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Sprache:	eng
Schlagworte:	Drop test Exact sciences and technology Fracture mechanics (crack, fatigue, damage...) Fundamental areas of phenomenology (including applications) Hard disk drive Head actuator asssembly Physics Shock Simulation Solid mechanics Structural and continuum mechanics Vibration, mechanical wave, dynamic stability (aeroelasticity, vibration control...)
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container_title	International journal of impact engineering
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creator	Shi, Bao-Jun Shu, Dong-Wei Wang, Shao Luo, Jun Meng, Hui Ng, Quock Lau, Joseph H.T. Zambri, Razman
description	This work aims to develop a method for predicting the displacement and failure of the Head Actuator Assembly (HAA) during a drop test. When a Hard Disk Drive (HDD) is dropped from a certain height, it will accelerate due to gravity until it hits the ground with a certain speed, and the head suspension system may lift off the disk and land onto it in a very short time. The impact during the head slap often leads to failure of the HAA. The pivot-bearing stiffness is a very important factor for the dynamic behavior of the HAA during a drop test. A simplified beam model with a torsional spring and a translational spring located at the end of the arm has been developed to analyze the effects of the pivot-bearing stiffness on the dynamic response of the arm in the present paper. Moreover, to further investigate a pseudo-resonance phenomenon observed by the authors in a previous work, three types of acceleration shocks different in pulse shapes (half-sine, triangular, and dual-quadratic acceleration pulses) were selected as input loadings. Dynamic analyses of the actuator arm subjected to these loadings were carried out. Numerical results show that a pseudo-resonance phenomenon occurs for the maximum relative displacement, but at different pulse widths for these different acceleration shocks. Power spectrum analyses were implemented for these different acceleration shocks. An explanation is given in terms of the acceleration power at the resonant frequency of the arm. A corollary has been derived based on a theorem developed previously by the authors. A prediction is made by the corollary and confirmed by numerical results.
doi_str_mv	10.1016/j.ijimpeng.2006.06.008
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When a Hard Disk Drive (HDD) is dropped from a certain height, it will accelerate due to gravity until it hits the ground with a certain speed, and the head suspension system may lift off the disk and land onto it in a very short time. The impact during the head slap often leads to failure of the HAA. The pivot-bearing stiffness is a very important factor for the dynamic behavior of the HAA during a drop test. A simplified beam model with a torsional spring and a translational spring located at the end of the arm has been developed to analyze the effects of the pivot-bearing stiffness on the dynamic response of the arm in the present paper. Moreover, to further investigate a pseudo-resonance phenomenon observed by the authors in a previous work, three types of acceleration shocks different in pulse shapes (half-sine, triangular, and dual-quadratic acceleration pulses) were selected as input loadings. Dynamic analyses of the actuator arm subjected to these loadings were carried out. Numerical results show that a pseudo-resonance phenomenon occurs for the maximum relative displacement, but at different pulse widths for these different acceleration shocks. Power spectrum analyses were implemented for these different acceleration shocks. An explanation is given in terms of the acceleration power at the resonant frequency of the arm. A corollary has been derived based on a theorem developed previously by the authors. 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When a Hard Disk Drive (HDD) is dropped from a certain height, it will accelerate due to gravity until it hits the ground with a certain speed, and the head suspension system may lift off the disk and land onto it in a very short time. The impact during the head slap often leads to failure of the HAA. The pivot-bearing stiffness is a very important factor for the dynamic behavior of the HAA during a drop test. A simplified beam model with a torsional spring and a translational spring located at the end of the arm has been developed to analyze the effects of the pivot-bearing stiffness on the dynamic response of the arm in the present paper. Moreover, to further investigate a pseudo-resonance phenomenon observed by the authors in a previous work, three types of acceleration shocks different in pulse shapes (half-sine, triangular, and dual-quadratic acceleration pulses) were selected as input loadings. Dynamic analyses of the actuator arm subjected to these loadings were carried out. Numerical results show that a pseudo-resonance phenomenon occurs for the maximum relative displacement, but at different pulse widths for these different acceleration shocks. Power spectrum analyses were implemented for these different acceleration shocks. An explanation is given in terms of the acceleration power at the resonant frequency of the arm. A corollary has been derived based on a theorem developed previously by the authors. 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Numerical results show that a pseudo-resonance phenomenon occurs for the maximum relative displacement, but at different pulse widths for these different acceleration shocks. Power spectrum analyses were implemented for these different acceleration shocks. An explanation is given in terms of the acceleration power at the resonant frequency of the arm. A corollary has been derived based on a theorem developed previously by the authors. A prediction is made by the corollary and confirmed by numerical results.</abstract><cop>Oxford</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.ijimpeng.2006.06.008</doi><tpages>14</tpages></addata></record>
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subjects	Drop test Exact sciences and technology Fracture mechanics (crack, fatigue, damage...) Fundamental areas of phenomenology (including applications) Hard disk drive Head actuator asssembly Physics Shock Simulation Solid mechanics Structural and continuum mechanics Vibration, mechanical wave, dynamic stability (aeroelasticity, vibration control...)
title	Drop test simulation and power spectrum analysis of a head actuator assembly in a hard disk drive
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