Load and stiffness of a planar ferrofluid pocket bearing

Lampaert, S.G.E.; Spronck, Jo W.; Ostayen, Ron A.J. van

doi:10.1177/1350650117739200

Cited by 27 publications

(14 citation statements)

References 24 publications

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“…With  of P(C, , D) varying from 0 to 2, B doesn't change in magnitude. At the point P(C, 0, D), the magnitude of the displacement vector R o can be given as (14) According to Biot-Savart Law, B o at the point P(C, 0, D) can be given as (15) where B ox , B oy , and B oz are the components of the mag-…”

Section: Calculation Of the Magnetic Field Strength In Magnetic Fluidmentioning

confidence: 99%

“…Later in the book titled "ferrohydrodynamic", Rosensweig gave a detailed description on the particular magnetic levitation force (selfsuspension buoyancy) by means of magnetic fluid stress tensor [3]. Up to now, this property of magnetic fluid has been exploited in many innovative devices, such as dampers [4][5][6], sensors [7][8][9][10][11], actuators [12][13][14], bearings [15,16], micromechanical system [17][18][19] and so on.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Research on the Axial Magnetic Levitation Force Acting on the Ring Magnet Suspended in Magnetic Fluid : Considering a Radial Eccentricity

Yu¹,

Li²,

Di³

et al. 2019

JMAG

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The self-suspension of magnet in magnetic fluid has been widely used in micromechanical systems, sensors, and dampers. The magnetic field associated with the ring magnet is obtained by numerical calculation and simulation through which the axial magnetic levitation force is calculated, and the numerical calculation, simulation, and experimental results agree with each other. The influence of the radial eccentricity of the ring magnet on the axial magnetic levitation force is studied, the ring magnet will experience a maximum axial magnetic levitation force without radial eccentricity. With the increase of radial eccentricity and the decrease of the distance between the bottom of the ring magnet and container, the axial magnetic levitation force will continue to decrease. But it is worth noting that the magnitude of the change caused by radial eccentricity is negligible compared to that of the axial magnetic levitation force.

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Section: Calculation Of the Magnetic Field Strength In Magnetic Fluidmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Research on the Axial Magnetic Levitation Force Acting on the Ring Magnet Suspended in Magnetic Fluid : Considering a Radial Eccentricity

Yu¹,

Li²,

Di³

et al. 2019

JMAG

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“…Investigation of hydrodynamic lubrication with ferrofluids of finite journal bearings using the Jenkins model has been done by Laghrabli et al 25 They analyzed static characteristics of finite journal bearings using two control parameters: magnetic force coefficient and Jenkins viscosity. Lampaert et al 26 studied the load capacity and the stiffness of a ferrofluid pocket bearing. They showed that the load and stiffness of this bearing are in general mainly determined by the sealing capacity of the seal and the pressure of the ferrofluid itself.…”

Section: Introductionmentioning

confidence: 99%

Investigating the steady state characteristics of noncircular journal bearings lubricated with ferrofluid under concentric finite wire magnetic field

Rahmatabadi

Meybodi

Mehrjardi³

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part J:

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The aim of the present work is to investigate the steady state performance of noncircular hydrodynamic two, three and four lobe journal bearings, lubricated with ferrofluid under concentric finite wire magnetic field. Applying momentum and continuity equation, for ferrofluid under the applied magnetic field, modified Reynolds equation is obtained. Assuming linear behaviour for the magnetic material of the ferrofluid, the Reynolds equation is solved, using finite element technique to obtain pressure distribution then applied to study the effect of magnetic lubricant on various bearing performance characteristics such as load capacity, attitude angle, friction coefficient, friction force and side leakage flow. The results indicate with increasing magnetic force coefficient, side leakage in noncircular bearings and friction coefficient is significantly reduced and improvement in load bearing capacity can be seen at the most values of eccentricity ratio, especially in two lobe noncircular bearing. The results also show that the eccentricity ratio has an effective influence on bearing performance characteristics, if the magnetic field and geometric configuration are selected properly.

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“…Integration of tribo-mechatronics and control has divided the active hydrostatic bearings into three classes. In class one, researchers have tried to use the external magnetic field for controlling viscosity of the magnetic fluid, so that the shaft vibrations could be controlled [20][21][22][23][24]. In the second class, authors tried to control recess pressure, and efforts were made to control the recess pressure through a piezoelectrically activated jet [25,26].…”

Section: Introductionmentioning

confidence: 99%

Model-Based Design Approach to Improve Performance Characteristics of Hydrostatic Bearing Using Multivariable Optimization

et al. 2021

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Research in the field of tribo-mechatronics has been gaining popularity in recent decades. The objective of the current research is to improve static/dynamics characteristics of hydrostatic bearings. Hydrostatic bearings always work in harsh environmental conditions that effect their performance, and which may even result in their failure. The current research proposes a mathematical model-based system for hydrostatic bearings that helps to improve its static/dynamic characteristics under varying conditions of performance-influencing variables such as temperature, spindle speed, external load, and clearance gap. To achieve these objectives, the capillary restrictors are replaced with servo valves, and a mathematical model is developed along with robust control design systems. The control system consists of feedforward and feedback control techniques that have not been applied before for hydrostatic bearings in the published literature. The feedforward control tries to remove a disturbance before it enters the system while feedback control achieves the objective of disturbance rejection and improves steady-state characteristics. The feedforward control is a trajectory-based controller and the feedback controller is a sliding mode controller with a PID sliding surface. The particle swarm optimization algorithm is used to tune the 6-dimensional vector of the tuning parameters with multi-objective performance criteria. Numerical investigations have been carried out to check the performance of the proposed system under varying conditions of viscosity, clearance gap, external load and the spindle speed. The comparison of our results with the published literature shows the effectiveness of the proposed system.

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Load and stiffness of a planar ferrofluid pocket bearing

Cited by 27 publications

References 24 publications

Research on the Axial Magnetic Levitation Force Acting on the Ring Magnet Suspended in Magnetic Fluid : Considering a Radial Eccentricity

Research on the Axial Magnetic Levitation Force Acting on the Ring Magnet Suspended in Magnetic Fluid : Considering a Radial Eccentricity

Investigating the steady state characteristics of noncircular journal bearings lubricated with ferrofluid under concentric finite wire magnetic field

Model-Based Design Approach to Improve Performance Characteristics of Hydrostatic Bearing Using Multivariable Optimization

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