INVESTIGATION OF FLUID FLOW IN AXIAL HYDROSTATIC BEARING

Similar documents
NUMERICAL ANALYSIS OF THE EFFECTS OF WIND ON BUILDING STRUCTURES

Journal bearings/sliding bearings

Battery Thermal Management System Design Modeling

A Comparison of Analytical and Finite Element Solutions for Laminar Flow Conditions Near Gaussian Constrictions

Exergy Analysis of a Water Heat Storage Tank

Flow in data racks. 1 Aim/Motivation. 3 Data rack modification. 2 Current state. EPJ Web of Conferences 67, (2014)

Differential Relations for Fluid Flow. Acceleration field of a fluid. The differential equation of mass conservation

Lecture 6 - Boundary Conditions. Applied Computational Fluid Dynamics

TWO-DIMENSIONAL FINITE ELEMENT ANALYSIS OF FORCED CONVECTION FLOW AND HEAT TRANSFER IN A LAMINAR CHANNEL FLOW

Natural Convection. Buoyancy force

THE CFD SIMULATION OF THE FLOW AROUND THE AIRCRAFT USING OPENFOAM AND ANSA

CFD SIMULATION OF SDHW STORAGE TANK WITH AND WITHOUT HEATER

Study on Pressure Distribution and Load Capacity of a Journal Bearing Using Finite Element Method and Analytical Method

Measurement and Prediction Technology of Cooling Capability for Hybrid Drivetrain Components. Tadashi Yamada TOYOTA MOTOR CORPORATION

Effect of design parameters on temperature rise of windings of dry type electrical transformer

Adaptation of General Purpose CFD Code for Fusion MHD Applications*

Numerical Analysis of Independent Wire Strand Core (IWSC) Wire Rope

Increase the efficiency of your rotating machines by optimizing your bearing lubrication

Steady Flow: Laminar and Turbulent in an S-Bend

Practice Problems on Boundary Layers. Answer(s): D = 107 N D = 152 N. C. Wassgren, Purdue University Page 1 of 17 Last Updated: 2010 Nov 22

Turbulence Modeling in CFD Simulation of Intake Manifold for a 4 Cylinder Engine

FRETTING FATIGUE OF STEELS WITH IFFERENT STRENGTH

Using CFD to improve the design of a circulating water channel

AIR STREAMS IN BUILDING FOR BROILERS

Comparison of Bearings --- For the Bearing Choosing of High-speed Spindle Design. Xiaofan Xie. Dept. of Mechanical Engineering, University of Utah

FEM analysis of the forming process of automotive suspension springs

A. Hyll and V. Horák * Department of Mechanical Engineering, Faculty of Military Technology, University of Defence, Brno, Czech Republic

O.F.Wind Wind Site Assessment Simulation in complex terrain based on OpenFOAM. Darmstadt,

Numerical Investigation of Heat Transfer Characteristics in A Square Duct with Internal RIBS

AN EFFECT OF GRID QUALITY ON THE RESULTS OF NUMERICAL SIMULATIONS OF THE FLUID FLOW FIELD IN AN AGITATED VESSEL

Introduction to COMSOL. The Navier-Stokes Equations

The simulation of machine tools can be divided into two stages. In the first stage the mechanical behavior of a machine tool is simulated with FEM

HEAT TRANSFER ANALYSIS IN A 3D SQUARE CHANNEL LAMINAR FLOW WITH USING BAFFLES 1 Vikram Bishnoi

Comparison of Heat Transfer between a Helical and Straight Tube Heat Exchanger

A LAMINAR FLOW ELEMENT WITH A LINEAR PRESSURE DROP VERSUS VOLUMETRIC FLOW ASME Fluids Engineering Division Summer Meeting

CENTRIFUGAL PUMP OVERVIEW Presented by Matt Prosoli Of Pumps Plus Inc.

EXPERIMENTAL RESEARCH ON FLOW IN A 5-STAGE HIGH PRESSURE ROTOR OF 1000 MW STEAM TURBINE

When the fluid velocity is zero, called the hydrostatic condition, the pressure variation is due only to the weight of the fluid.

OpenFOAM Opensource and CFD

Development of High-Speed High-Precision Cooling Plate

Fluids and Solids: Fundamentals

Engineering Problem Solving as Model Building

INTRODUCTION TO FLUID MECHANICS

OpenFOAM simulations of the Turbulent Flow in a Rod Bundle with Mixing Vanes

Ravi Kumar Singh*, K. B. Sahu**, Thakur Debasis Mishra***

oil liquid water water liquid Answer, Key Homework 2 David McIntyre 1

FLUID MECHANICS IM0235 DIFFERENTIAL EQUATIONS - CB _1

Lecture 5 Hemodynamics. Description of fluid flow. The equation of continuity

Lap Fillet Weld Calculations and FEA Techniques

Understanding Plastics Engineering Calculations

SBi 2013:12. Use of perforated acoustic panels as supply air diffusers in diffuse ceiling ventilation systems

du u U 0 U dy y b 0 b

Optimum fin spacing for fan-cooled heat sinks

Radial-axial Radial mixing is based on the premise that the fluids to be mixed enter the mixer in the correct proportions simultaneously

Practice Problems on the Navier-Stokes Equations

5.2. Vaporizers - Types and Usage

SAFE A HEAD. Structural analysis and Finite Element simulation of an innovative ski helmet. Prof. Petrone Nicola Eng.

PUTTING THE SPIN IN CFD

Keywords: CFD, heat turbomachinery, Compound Lean Nozzle, Controlled Flow Nozzle, efficiency.

3. Prescribe boundary conditions at all boundary Zones:

Thermal Simulation of a Power Electronics Cold Plate with a Parametric Design Study

Heat Transfer Prof. Dr. Ale Kumar Ghosal Department of Chemical Engineering Indian Institute of Technology, Guwahati

Basics of vehicle aerodynamics

For Water to Move a driving force is needed

. Address the following issues in your solution:

Head Loss in Pipe Flow ME 123: Mechanical Engineering Laboratory II: Fluids

CFD software overview comparison, limitations and user interfaces

International Journal of Heat and Mass Transfer

SKF composite plain bearings. Compact and maintenance-free

I. INTRODUCTION II. INCREASING THE COOLING POWER OF PASSIVE CHILLED BEAM BY ADJUSTING ITS CONSTRUCTION

FLUID MECHANICS. TUTORIAL No.7 FLUID FORCES. When you have completed this tutorial you should be able to. Solve forces due to pressure difference.

Shell Morlina S4 B. Advanced Bearing & Circulating Oils. Interim Technical Data Sheet. Previous Name: Shell Omala RL

What is the most obvious difference between pipe flow and open channel flow????????????? (in terms of flow conditions and energy situation)

Department of Chemical Engineering, National Institute of Technology, Tiruchirappalli , Tamil Nadu, India

GEOMETRIC, THERMODYNAMIC AND CFD ANALYSES OF A REAL SCROLL EXPANDER FOR MICRO ORC APPLICATIONS

Technical Data. 7. Bearing Fits. 7.1 Interference. 7.2 Calculation of interference F B LLLLLLLLL( A-54

Geometry and dimensional tolerances of engine bearings

VISUAL PHYSICS School of Physics University of Sydney Australia. Why do cars need different oils in hot and cold countries?

A MTR FUEL ELEMENT FLOW DISTRIBUTION MEASUREMENT PRELIMINARY RESULTS

James M. Pleasants Company

CE 6303 MECHANICS OF FLUIDS L T P C QUESTION BANK PART - A

ZKL Bearings for Railway Rolling Stock

SUPER 600. Tracked Paver SUPER 600. Pave Widths 0.5m 2.7m. Maximum Laydown Rate 200 tonnes/h. Clearance Width 1.2m

Dr.A.K.Shaik Dawood. N.V.Kamalesh. Department of Mechanical Engineering, Associate Professor, Karpagam University, Coimbatore , India.

MASTER DEGREE PROJECT

Introduction of Duplex Pump HPD71+71 and Short-Stroke Pump HPV

Experiment # 3: Pipe Flow

Technology of EHIS (stamping) applied to the automotive parts production

CFD ANALYSES OF FLUID FLOW AND HEAT TRANSFER IN PATTERNED ROLL-BONDED ALUMINIUM PLATE RADIATORS

AgoraLink Agora for Life Science Technologies Linköpings Universitet Kurs i Fysiologisk mätteknik Biofluidflöden

PREDICTION OF MACHINE TOOL SPINDLE S DYNAMICS BASED ON A THERMO-MECHANICAL MODEL

Abaqus/CFD Sample Problems. Abaqus 6.10

Machine Design II Prof. K.Gopinath & Prof. M.M.Mayuram. Module 2 - GEARS. Lecture 17 DESIGN OF GEARBOX

Vapor Chambers. Figure 1: Example of vapor chamber. Benefits of Using Vapor Chambers

DEVELOPMENT OF HIGH SPEED RESPONSE LAMINAR FLOW METER FOR AIR CONDITIONING

CENTRIFUGAL PUMP SELECTION, SIZING, AND INTERPRETATION OF PERFORMANCE CURVES

Transcription:

INVESTIGATION OF FLUID FLOW IN AXIAL HYDROSTATIC BEARING Michal KOZDERA VŠB Technical University of Ostrava, Faculty of Mechanical Engineering, Department of hydromechanics and hydraulic equipment, 17. listopadu 15/2172, 708 33, Ostrava, Czech Republic Phone: + (420) 602 150 578, Email: michalkozdera@seznam.cz This paper describes numerical modelling of the flow in narrow gaps of axial hydrostatic bearing. These bearing produce oil layer between two sliding surfaces, where the fluid friction arises. The thickness of the lubricating film ranges from 0.05 to 0.15 mm. CFD program Ansys Fluent has been applied for the investigation of the flow field and generated forces. Keywords: axial hydrostatic bearing 1 INTRODUCTION Axial hydrostatic bearing belongs to a group of journal bearings. Their advantage is high load capacity, they are suitable for all circumferential speeds. Speed change does not have significant influence on the load capacity of the bearing. In contrast with hydrodynamically lubricated bearings, they can be operated near zero value of speed while maintaining the same properties. Bearing operating temperature depends on the type of lubricant, and can extend up to 200 C. They have very little frictional resistance, because there is fluid friction between sliding surfaces. Axial hydrostatic bearing has infinite durability, which depends on reliability of the external pressure source. Their disadvantage is very little ability to absorb vibrations. Their production and operation is more demanding than that of hydrodynamic bearings. 2 AXIAL HYDROSTATIC BEARING Axial hydrostatic bearing consists of two sliding surfaces bearing runner and bearing pad (Figure 1). On the bearing pad are created bearing recess and discharge grooves. The discharge grooves separate bearing recesses so that they do not affect each other. Figure 1 - Diagram of axial hydrostatic bearing 1

The lubricated fluid is supplied with the assistance of hydraulic aggregate. Basic technical parameters have been selected for the experiment: - volume discharge Q V = 50 l.min -1, - operating pressure p = 4.5 MPa. Part of the hydraulic aggregate is heating and cooling equipment. During the start up of the axial hydrostatic bearing the heating equipment is used that heats the mineral oil to the operating temperature. When running the axial hydrostatic bearing cooling equipment is used that keeps the working fluid at a constant temperature of 24 C to 28 C. Mineral oil is used for heavy-duty hydrostatic mechanisms. It contains additives against oxidation, wear, foaming and additives for viscous index increase. Classification according to ISO 6743 is HV 46 with following properties: - density ρ = 874 kg.m -3, - viscous index 170, - flash point 220 C, - congeal point -36 C. The oil is led through the distribution block from hydraulic aggregate. The fluid is divided and led to each bearing recess in the axial hydrostatic bearing. The fluid is evenly distributed with assistance butterfly throttles with stabilization of the pressure gradient to each bearing recess. Pressure fluid is fed into the lubrication grooves, which are in the fixed part of the bearing. Here, mineral oil spills evenly and starts causing hydrostatic pressure on the upper movable plate. Axial hydrostatic bearing can begin to rotate when it is lifted to the prescribed height. The fluid friction is created between two sliding surfaces. The thickness of the lubricant film ranges from 0.05 mm to 0.15 mm. The basic condition of the functionality of the axial hydrostatic bearing is to create a lubricating film, which covers all micro-roughness and macro-roughness. These deflections of the shape occur during the production process. Figure 2 : Detail of the bearing recess The fixed part of the bearing has an inner diameter of 1100 mm and outer diameter of 1450 mm. Axial hydrostatic bearing has 6 bearing recesses (Figure 2), which are separated by discharge grooves (Figure 3). Figure 3: Detail of the discharge groove 2

3 MATHEMATICAL MODEL OF THE AXIAL HYDROSTATIC BEARING Journal of applied science in the thermodynamics and fluid mechanics Solution of the flow in the narrow gap of the axial hydrostatic bearing comes out from the assumption of continuous, isotropic environment. Fluid flow is associated with the modelling of the problem, which is defined as: - three-dimensional flow, - laminar flow (fluid moves in very thin layers), - incompressible flow (ρ = constant), - isothermal flow (T = constant), t - stationary flow ( = 0 ), - flow without considering transmission of additions. Figure 4: Boundary conditions of the model For the numerical simulation CFD program Ansys Fluent was applied, which uses finite volume method. Since the periodic conditions can be used, definition of geometry was simplified to the 1/6 of the bearing geometry. Boundary conditions were chosen as shown in Figure 4 and 5. On inlet of the bearing, the velocity condition (flow condition) was defined and on the outlet zero gradients was assumed. For repetitive rotational geometry periodic boundary condition was used. The lower wall was set as a fixed and upper wall as rotating, where rotational speed was defined. Figure 5: Definition of the type of bearing walls 4 APPLICATION OF A MATHEMATICAL MODEL ON THE AXIAL HYDROSTATIC BEARING Evaluation was performed for the fluid layer thickness of 0.13 mm. Load capacity of the bearing and size of the static pressure were determined: - load capacity of the axial hydrostatic bearing 219 230 N, - average static pressure 4.47 MPa, - maximum static pressure 5.41 MPa. With decreasing thickness of fluid layer the load capacity and static pressure of the axial hydrostatic bearing significantly increases. Conversely, the load capacity is decreasing with the increase of the oil thickness. 3

Figure 6: Velocity vectors in the axial hydrostatic bearing To evaluate the results, the graphic output was created on the evaluation plain, which is located in the middle of the gap thickness. Figure 6 and 7 show the size of the velocity vectors of the axial hydrostatic bearing. The maximum of the velocity magnitude is 4.16 m.s -1. Mineral oil is fed into the bearing recesses and is flowing between the sliding surfaces around the bearing. The fluid can flow in all directions and chooses the path of lowest resistance. Figure 7: Detailed view of the size of the velocity vectors Velocity field on the evaluation plain at the outlet of the axial hydrostatic bearing is shown in Figure 8. The maximum magnitude of the velocity is located in the bearing recesses on the outlet from the bearing (shown in red) and decreases evenly towards the bearing discharge grooves. The magnitude of the velocity approaches zero in the field of the discharge grooves (shown in blue). 4

Figure 8: Velocity field on the outlet of the axial hydrostatic bearing Figure 9 shows the pressure field in the gap thickness of 0.13 mm in the evaluation plain of the hydrostatic axial bearing. The maximum magnitude of the static pressure is located in the bearing recesses (shown in red). Static pressure drops gradually to discharge grooves and reaches the value close to zero (shown in blue). Figure 9: Pressure field in the evaluation plain of the axial hydrostatic bearing 5

All bearing recesses exhibit the same distribution of pressure and velocity, as they are separated by bearing discharge grooves. In this design variant of axial hydrostatic bearing constant rotational speed of 40 min -1 was defined on the bearing runner. Speed, however, can be arbitrarily changed. Reduction of the speed to 20 min -1 did not change the load capacity or pressure conditions. It can be concluded that the speed change does not have significant influence on the axial bearing function. Further simulations could be carried out for design modifications of axial hydrostatic bearing, focused on different number of the bearing recesses and their shapes or changing the cross-sectional area of the discharge grooves. REFERENCES [1] BEČKA, J.: Tribologie. Praha: Vydavatelství ČVUT, 2007. [2] BLÁHA, J. - BRADA, K.: Hydraulické stroje. Praha: Státní nakladatelství technické literatury, 1992. [3] BLAŠKOVIC, P. - BALLA, J. - DZIMKO, M.: Tribológia. Bratislava: Alfa nakladatelství, 1990. [4] BOJKO, M.: BOJKO M.: Návody do cvičení "Modelování Proudění" - FLUENT. Ostrava: Vysoká škola báňská Technická univerzita Ostrava, 2008. [5] DRÁBKOVÁ, S.: Mechanika tekutin. Ostrava: Vysoká škola báňská Technická univerzita Ostrava, 2008. [6] KOZDERA, M.: Projekční návrhy axiálních hydrostatických ložisek. Ostrava: Vysoká škola báňská Technická univerzita Ostrava, 2008. [7] KOZUBKOVÁ, M.: Modelování proudění Fluent.. Ostrava: Vysoká škola báňská Technická univerzita Ostrava, 2008. [8] VINŠ, J.: Kluzná ložiska. Praha: Státní nakladatelství technické literatury, 1971. 6

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information