1 Challenge the future The Lateral Motion of Wafer under the Influence of Thin-film Flow Leilei Hu Solid and Fluid Mechanics 30-09-2013.

Slides:



Advertisements
Similar presentations
Technická univerzita v Liberci Magnetic Field of Massive Conductor at Low Frequency Martin Truhlá ř Faculty of Mechatronics, Informatics and Interdisciplinary.
Advertisements

Chapter Four Fluid Dynamic
TRC Project: Predictions of Force Coefficients in Off-Centered Grooved Oil Seals A novel FE Bulk-Flow Model for Improved Predictions of Force Coefficients.
Aero-Hydrodynamic Characteristics
University of Western Ontario
SIEMENS, MUELHEIM 1 1 Fluid-Structure Interaction for Combustion Systems Artur Pozarlik Jim Kok FLUISTCOM SIEMENS, MUELHEIM, 14 JUNE 2006.
Kjell Simonsson 1 Vibrations in linear 1-degree of freedom systems; I. undamped systems (last updated )
Fluids Mechanics Carlos Silva December 2 nd 2009.
Computational Modeling of Flow over a Spillway In Vatnsfellsstífla Dam in Iceland Master’s Thesis Presentation Chalmers University of Technology 2007.
FLUID FLOW IDEAL FLUID BERNOULLI'S PRINCIPLE How can a plane fly? How does a perfume spray work? What is the venturi effect? Why does a cricket ball swing.
Flow over an Obstruction MECH 523 Applied Computational Fluid Dynamics Presented by Srinivasan C Rasipuram.
Nazgol Haghighat Supervisor: Prof. Dr. Ir. Daniel J. Rixen
1 Simple harmonic motion displacement velocity = dx/dt acceleration = dv/dt LECTURE 3 CP Ch 14 CP449.
Basic Governing Differential Equations
MECH 221 FLUID MECHANICS (Fall 06/07) Chapter 9: FLOWS IN PIPE
Chapter 9 Solids and Fluids
EFFECTS OF CHAMBER GEOMETRY AND GAS PROPERTIES ON HYDRODYNAMIC EVOLUTION OF IFE CHAMBERS Zoran Dragojlovic and Farrokh Najmabadi University of California.
HYDRODYNAMIC EVOLUTION OF IFE CHAMBERS WITH DIFFERENT PROTECTIVE GASES AND PRE-IGNITION CONDITIONS Zoran Dragojlovic and Farrokh Najmabadi University of.
Fluid Properties and Units CVEN 311 . Continuum ä All materials, solid or fluid, are composed of molecules discretely spread and in continuous motion.
The Physics of Balloons and Submarines…cont’d…. The Ideal Gas Law Equation We learned that Pressure of an Ideal Gas is proportional to Particle Density.
Unit 3 - FLUID MECHANICS.
In the analysis of a tilting pad thrust bearing, the following dimensions were measured: h1 = 10 mm, h2 = 5mm, L = 10 cm, B = 24 cm The shaft rotates.
Airball Demo Modeling —— Dimensional Analysis Method Based on Genetic Algorithm for Key Parameters Identification Name : Zhisheng Team Advisor : Zhang.
Motion of a mass at the end of a spring Differential equation for simple harmonic oscillation Amplitude, period, frequency and angular frequency Energetics.
Basic structural dynamics II
Introduction to COMSOL Travis Campbell Developed for CHE 331 – Fall 2012 Oregon State University School of Chemical, Biological and Environmental Engineering.
1 Challenge the future To do list. add extra slide about the coupling, at pressure level. Burn CD.
In Engineering --- Designing a Pneumatic Pump Introduction System characterization Model development –Models 1, 2, 3, 4, 5 & 6 Model analysis –Time domain.
PHAROS UNIVERSITY ME 259 FLUID MECHANICS FOR ELECTRICAL STUDENTS Basic Equations for a Control Volume.
Flow rate across a fluid element with top and bottom faces moving Fluid element h dx dy Consider the fluid element with dimensions dx, dy, and h (film.
Energy Equation. Chapter 2 Lecture 3 2 Mechanical Energy? Forms of energy that can be converted to MECHANICAL WORK completely and directly by mechanical.
Fluid Mechanics Chapter 11. Expectations After this chapter, students will:  know what a fluid is  understand and use the physical quantities mass density.
Proceedings of the 18 th International Conference on Nuclear Engineering ICONE18 May , 2010, Xi’an, China Hannam University Fluid-elastic Instability.
COMSOL Conference Prague 2006Page 1 Poisson equation based modeling of DC and AC electroosmosis Michal Přibyl & Dalimil Šnita Institute of Chemical Technology,
© 2011 Autodesk Freely licensed for use by educational institutions. Reuse and changes require a note indicating that content has been modified from the.
In-term project presentation by Kanish Jindal Modeling of chlorine contact chamber at West Lafayette treatment plant.
Physics 203 – College Physics I Department of Physics – The Citadel Physics 203 College Physics I Fall 2012 S. A. Yost Chapter 10 - Part 3 Chapter 11 –
Chapter 21: Molecules in motion Diffusion: the migration of matter down a concentration gradient. Thermal conduction: the migration of energy down a temperature.
SIMULATION OF GAS PIPELINES LEAKAGE USING CHARACTERISTICS METHOD Author: Ehsan Nourollahi Organization: NIGC (National Iranian Gas Company) Department.
April Second Order Systems m Spring force ky F(t) (proportional to velocity) (proportional to displacement)
30 th June 20111Enrico Da Riva, V. Rao Parametric study using Empirical Results June 30 th 2011 Bdg 298 Enrico Da Riva,Vinod Singh Rao CFD GTK.
Fluids. Introduction The 3 most common states of matter are: –Solid: fixed shape and size (fixed volume) –Liquid: takes the shape of the container and.
Physical Fluid Dynamics by D. J. Tritton What is Fluid Dynamics? Fluid dynamics is the study of the aforementioned phenomenon. The purpose.
HEAT TRANSFER FINITE ELEMENT FORMULATION
Chapter 21: Molecules in motion Diffusion: the migration of matter down a concentration gradient. Thermal conduction: the migration of energy down a temperature.
Numerical simulation of droplet motion and two-phase flow field in an oscillating container Tadashi Watanabe Center for Computational Science and e-Systems.
Numerical study of flow instability between two cylinders in 2D case V. V. Denisenko Institute for Aided Design RAS.
FLOW THROUGH GRANULAR BEDS AND PACKED COLUMN
Convection in Flat Plate Boundary Layers P M V Subbarao Associate Professor Mechanical Engineering Department IIT Delhi A Universal Similarity Law ……
1FCI. Prof. Nabila.M.Hassan Faculty of Computer and Information Basic Science department 2012/2013 2FCI.
A Numerical Solution to the Flow Near an Infinite Rotating Disk White, Section MAE 5130: Viscous Flows December 12, 2006 Adam Linsenbardt.
CFD Study of the Development of Vortices on a Ring Wing
A Biot model describing wave propagation in a porous solid saturated by a three-phase fluid Juan E. Santos 1,2 and Gabriela B. Savioli Instituto.
1 NUMERICAL AND EXPERIMENTAL STUDIES OF THIN-LIQUID-FILM WALL PROTECTION SCHEMES S.I. ABDEL-KHALIK AND M. YODA G. W. Woodruff School of Mechanical Engineering.
MOTION OF ERYTHROCYTES ALONG THE CAPILLARIES Alexander V. Kopyltsov.
Lecture Objectives: Define 1) Reynolds stresses and
Video 10-1 Kinetic Molecular Theory Properties of Gases Deviations from Ideal Gas Behavior.
Heat Transfer Su Yongkang School of Mechanical Engineering # 1 HEAT TRANSFER CHAPTER 6 Introduction to convection.
Indian Institute of Space Science and Technology STUDY OF EFFECT OF GAS INJECTION OVER A TORPEDO ON FLOW-FIELD USING CFD.
AP Physics Review Jeopardy.
Transient Analysis of Heat Transfer and Fluid Flow in a Polymer-based Micro Flat Heat Pipe with Hybrid Wicks Mehdi Famouria, Gerardo Carbajalb, Chen Lia.
Chapter 11 Fluids.
Internal Incompressible
Flow Through a Pipe Elbow (Comsol)
Multi-physics Simulation of a Wind Piezoelectric Energy Harvester Validated by Experimental Results Giuseppe Acciani, Filomena Di Modugno, Ernesto Mininno,
UNIT - 4 HEAT TRANSFER.
Oscillatory Motion.
Devil physics The baddest class on campus Ap Physics
FIDAP Numerical Modeling
FLUID MECHANICS REVIEW
Presentation transcript:

1 Challenge the future The Lateral Motion of Wafer under the Influence of Thin-film Flow Leilei Hu Solid and Fluid Mechanics

2 Challenge the future content of the presentation Introduction to the problem 1. mathematical model (dynamic equation) 2. numertical computation (close the equation) 3. parameter study 4. experimental verification

3 Challenge the future Introduction to the problem "Levitrack" is a solar-cell wafer processing device. The wafers are flying in the chamer in Levitrack where presursor gases are deposited onto the substrate of the wafers. Wafer transporting in process chamber

4 Challenge the future Wafer in the chamber & problem definition Wafer transporting in process chamber top view side view injecting direction

5 Challenge the future Targets Study and improve the dynamic behavior of the wafer in lateral directions. Modify the dimension of the chamber to reduce the possibility of the collision.

6 Challenge the future Part I Mathematical model (Dynamic equation)

7 Challenge the future Mathematical model(1) Only lateral motion is considered Length of wafer in y direction infinitely long problem simplification y x y-velocity

8 Challenge the future Mathematical background of the model(2) dynamic equation----a result of force equilibrium with

9 Challenge the future Mathematical background of the model(2) g gap above the wafer g gap below the wafer L w ---- length of the wafer in lateral direction L y ---- length of the wafer in transporting direction μ ---- viscosity coefficient m ---- mass of wafer D w ---- thickness of wafer b ---- slope of the curve"average pressure difference---- lateral displacement" (to be determined) dynamic equation x ΔP b o

10 Challenge the future Part II Numerical computation (determination of "b")

11 Challenge the future Determination of b compute pressure value for x=0, 0.1mm, 0.2mm, 0.3mm, 0.4mm, 0.48mm stationary model basic idea x(lateral direction) y P1P1 P2P2 x ΔP b o

12 Challenge the future Computation results lateral forces----lateral displacements

13 Challenge the future physics coupling Avoid computation of full NS equations by dividing the flow into laminar flow and thin-film flow. numerical implementation less grids and less DoFs

14 Challenge the future Inlet boundary condition numerical implementation

15 Challenge the future Inlet boundary condition numerical implementation Q ---- volume flow d ---- diameter of inlet holes η ---- dynamic viscosity of nitrogen P s ---- supplying pressure pf ---- pressure in the inter side of the inlet holes L ---- length of the inlet holes v ave ---- average velocity of flow

16 Challenge the future Other numerical issues and solutions Mesh configuration generated according to the physics of the flow Mesh study performed to determine the size of the mesh Getting it converged step by step starting from lower Renolds number material

17 Challenge the future Part III Parameter study (Modify the chamber based on the dynamic equation)

18 Challenge the future Parameter study (1) supply pressure Height of chamber Diameter of exhausted holes Width of chamber increase the potential energy of the system initial velocity constant

19 Challenge the future Parameter study -- supply pressure increase the potential energy of the system

20 Challenge the future supply pressure supplying pressure (pa) stiffness coefficient (N/m) Ratio of stiffness coefficients

21 Challenge the future Parameter study -- height of chamber increase the potential energy of the system

22 Challenge the future P arameter study -- diameter of exhaust holes increase the potential energy of the system

23 Challenge the future Parameter study -- width of chamber increase the potential energy of the system

24 Challenge the future Analytical explanation of the results qualitative explanation of the flow model

25 Challenge the future Analytical explanation of the results qualitative explanation of the flow model stiffness is proportional to supply pressure

26 Challenge the future supply pressure supplying pressure (pa) stiffness coefficient (N/m) Ratio of stiffness coefficients

27 Challenge the future Parameter study (2) configuration updated initial configurationsupdated configurations width of chamber (mm) diameter of exhaust holes (mm)

28 Challenge the future Parameter study (2) configuration updated

29 Challenge the future Part IV Experimental verification

30 Challenge the future Experimental verification (1) experimental frequency ≈ analytical frequency

31 Challenge the future Experimental verification (2) translational oscillation

32 Challenge the future Experimental verification (2) translational frequency supplying pressure (pa) analytical frequency (Hz) experimental frequency (Hz) ratio

33 Challenge the future Experimental verification (3) rotational oscillation

34 Challenge the future Experimental verification (3) rotational frequency supplying pressure (pa) analytical frequency (Hz) experimental frequency (Hz) ratio

35 Challenge the future Experimental verification (4) In real system not all the flow contributes to the lateral stiffness of the wafer. explanation of the difference

36 Challenge the future Conclusions The dynamic equation and numerical computation are sufficient to show the oscillation behavior of the wafer. In reality,the leaking of the chamber is the dominant factor for the collision between the wafers and the walls, which causes much larger oscillation amplitude.

37 Challenge the future Experimental verification (2) translational oscillation

38 Challenge the future

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com. Inc. All rights reserved.