Microdrop Generation

INTRODUCTION

WHAT CAN YOU DO WITH A MICRODROP?

Characteristics of Microdrops

Use of Microdrops in Pure Science

Use of Microdrops in Applied Science

Biotechnology Applications of Microdrops

Applications in Manufacturing and Engineering

METHODS OF EJECTING MICRODROPS

Acoustically Disrupted Continuous Fluid Jet

Thermal Inkjet

Piezoelectric Direct Pressure Pulse

Focused Acoustic Beam Ejection

Liquid Spark Inkjet

Electrohydrodynamic Inkjet

Flextensional Aperture Plate Inkjet

Electro-Rheological Fluid Inkjet

Liquid Ink Fault Tolerant Process Inkjet

TopSpotÒ Microdrop Ejector

Summary and Recommendations

PARTICLE KINETICS OF EJECTED MICRODROPS

Reynolds Number and Stokes Law

Terminal Velocity

Relaxation Time Constant

Streaming

Impact

Brownian Motion

Motion in Electric Fields

ELECTRIC CHARGING OF MICRODROPS

Rayleigh Limit to Charging Microdrops

Drop Charging Mechanisms

Practical Drop Charge Control Methods

Variations in the Induced Charge

ENGINEERING REQUIREMENTS FOR RELIABLE MICRODROP GENERATION

Conditions Needed for Monodisperse Drop-On-Demand Operation

Drive Pulse Amplitude

Drive pulse Shape

Internal Pressure Level

Drop Ejection Rate

Fluid Level

Fluid Temperature

TROUBLESHOOTING DROP EJECTORS

Clogged Nozzles

Damaged Nozzles

Internal Air Bubbles

Overly Wetted Meniscus

Misdirected Jets

Internal Pressure

Insufficient Drive Amplitude

Non-Optimal Pulse Waveform

Pulse Rate

Problematic Fluid

Mechanical Mount

Imaging System

Recommended Startup Procedure for a New System

IMAGING MICRODROPS

Direct viewing of illuminated microdrops

Bright Background Imaging of Microdrops

Bright Source Stroboscopically Illuminated Droplets

Light Emitting Diode Illumination Arrays

Imaging System Synchronization

Optics

Cameras

Stroboscopic Illumination Sources

Low Cost Microdrop Imaging Hardware

DROP EJECTOR DRIVE ELECTRONICS

Gated Voltage Sources

Linear Pulse Amplifiers

FABRICATION OF EJECTION APERTURE NOZZLES

Ejection Nozzle Requirements

Fabricating Acute Edge Conical Glass Nozzles

Fabricating Tapered Profile Glass Nozzles

Micromachined Ejection Apertures

Electroformed Ejection Apertures

Jewel Orifices

Metal Optical Pinhole Apertures

Overview of Hole Generating Techniques

Anti-Wetting Surface Coatings

DROP EJECTOR CONSTRUCTION

Tubular Reservoir Piezoelectric Drop Ejectors

Metal Body Drop Ejectors

Glass, Straight Tube, Welded Aperture Plate

Glass, Pipette, Welded Aperture

Glass, Miniature, Welded Aperture

Piezoelectric Element Configuration

Piezoelectric Disc Actuator

Rectangular Slab Drive Elements

Cylindrical Piezoelectric Drive Elements

Integral Heating Elements

PRESSURE CONTROL

Manometer Tube Pressure Control System

Variable Height Reservoir Pressure Control System

Automated Pressure Control

FLUID ENGINEERING FOR MICRODROP EJECTORS

Problematic Fluids

Non-Clogging

First Drop Reliability

Jetting Stability

Directional Stability

Freedom from Satellite Drops

Wide Jet Velocity Tolerance

Drive Waveform Tolerance

Repetition Rate

Environmental and Temporal Stability

Chemical Reactivity with Drop Generator

Toxicity

Cost

COMPONENTS OF DROP-ON-DEMAND EJECTOR FLUIDS

Payload

Solvents

Humectants

Dispersants

Surfactants

Viscosity Modifiers

Polymeric Fluid Elasticity Agents

Anti-fungal Agents (Biocides, Preservatives)

Chelating Agents

pH Controllers

Corrosion Inhibitors

Defoamers

Electrical Conductivity Salts

Additives Specific for Thermal Inkjet

Additives Specific for Inkjet Image Printing

MAKING JETTABLE SUSPENSIONS OF GROUND SOLIDS

Obtaining Small Diameter Particles

Wetting and Dispersing

Filtering and Settling

Essential References

Ejectability

Final Caution - Make Sure You Have a Real Suspension

APPENDIX I. SETTING UP A MICRODROP SYSTEM ASAP

APPENDIX II. EXAMPLE INKJET FLUID FORMULATIONS FROM PATENT LITERATURE

APPENDIX III. EJECTION TESTS OF BIOLOGICAL FLUIDS

Eric R. Lee

(2002) 241 pages

Contents