Forestry Pesticide Aerial Spraying Environmental Science and Technology Library VOLUME 12 The titles published in this series are listed at the end of this volume. Forestry Pesticide Aerial Spraying Spray Droplet Generation, Dispersion, and Deposition by J.J.C. Picat Department of Chemic al Engineering, University of New Brunswick, Fredericton, NB, Canada and 0.0. Kristmansan formerlyof Department of Chemical Engineering, University of New Brunswick, Fredericro~NB,Canada SPRINGER-SCIENCE+BUSINESS MEDIA, B.V. Library of Congress Cataloging-in-Publication Data Picat, J. J. C. Farestry pesticide aerial spray ing : spray draplet generatian, dispersian, and depasitian I by J.J.C. Picat and 0.0. Kristmansan. p. cm. -- (Enviranmental science and technalagy library ; v. 12) Inc 1u des index. ISBN 978-94-010-6375-3 ISBN 978-94-011-5634-9 (eBook) DOI 10.1007/978-94-011-5634-9 1. Aerial spray ing and dusting in farestry--New Brunswick. 2. Farest insects--Cantral--New Brunswick. 3. Aerlal spray ing and dusting In farestry. 4. Farest insects--Cantral. I. Kristmansan, D. D. II. Title. III. Series. SB764.C36P53 1997 634.9·694--dc21 96-37439 ISBN 978-94-010-6375-3 Printed on acid-free paper AII Rights Reserved © 1997 Springer Science+Business Media Dordrecht OriginallY published by Kluwer Academic Publishers in 1997 Softcover reprint of the hardcover 1s t edition 1997 No part of the material protected by this copyright notice may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying, recording or by any information storage and retrieval system, without written permission from the copyright owner. T ABLE OF CONTENTS CHAPTER 1 INTRODUCTION 1.1 Historical Perspective ................................... 1 1.2 Scope and Orientation of Text ............................. 3 CHAPTER 2 CHARACTERIZING FOREST STANDS 2.1 Foliage Density and Vertical Distribution .................... 5 2.2 Forest Micrometeorology ............................... 10 2.3 Foliage as Filter for Atmospheric Particulates ............... 15 2.4 Foliage Simulators ..................................... 19 2.5 Importance of Properly Defining the Biological Interface ...... 23 CHAPTER 3 PROPERTIES OF SPRAY FORMULATIONS 3.1 Biological Toxic Requirement and Droplet Size ............. 26 3.2 Effects of Viscosity, Surface Tension, and Volatility .......... 29 3.3 Summary ............................................ 39 CHAPTER 4 SPRA Y AIRCRAFT AND ATOMIZERS 4.1 Aircraft in Use ........................................ 41 4.2 Aircraft Wake Behaviour ............................... 44 4.3 Droplet Generation and Atomizer Types ................... 50 4.4 Atomizer Characterization Methods ....................... 54 4.4.1 The PMS Spectrometer .......................... 55 4.4.2 The Malvern Spectrometer ........................ 64 4.4.3 Other Spectrometer Devices ....................... 67 4.5 Atomizer Droplet Spectrum Data ......................... 67 4.6 Correlations for Atomizer Emission Characteristics ........... 73 4.7 Dry Material Dispensing Devices ......................... 73 CHAPTER 5 RESEARCH FIELD TRIALS 5.1 Introduction .......................................... 78 5.2 Measurements and Analytical Methods .................... 79 vi TABLE OF CONTENTS 5.3 The Mass Balance Test as a Measure of Accuracy In Field Trials 90 5.4 Experimental Design, Management, and Costs ............... 91 CHAPTER 6 MODELING SPRAY APPLICATION, DISPERSION, AND DEPOSITION 6.1 Introduction .......................................... 97 6.2 Details of the PKBW model ............................. 99 6.1.1. Wake Velocity Distributions ...................... 99 6.1.2. Trajectory Calculations .......................... 99 6.1.3 Velocity and TurLulence in the Atmospheric Boundary Layer ........................................ 102 6.1.4 Calculating Deposition on Canopy and Ground ...... 104 6.1.5 Input Data for a Typical Run ..................... 105 6.1.6 Output for the Example ......................... 105 6.3 Model Validations and Comparisons: PKBW Model ........ 1.11 6.4 Off-target Drift and Buffer Zone Estimation. . . . . . . . . . . . . . . . 114 6.4.1 Some Field Data ............................... 114 6.4.2 Use ofPKBW for Drift Analysis ................. 124 6.5 Simulation of Block Spraying, PKBW Model .............. 126 CHAPTER 7 SPRAYING IN COMPLEX TERRAIN 7.1 Introduction .................................... 130 7.2 Air flows in Well-defined Mountain Valleys ............... 130 7.3 Implications with Respect to Pesticide Spraying ............ 130 7.4 Predicting Pesticide Dispersion and Deposition in Valleys .... 134 7.5 Comment ........................................... 137 CHAPTER 8 SPRAYING INNOVATIONS 8.1 Introduction ......................................... 139 8.2 Drop Size Optimization ................................ 139 8.2.1 The Concept .................................. 139 8.2.2 Field Confirmation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141 8.3 Field Trials for Dose Efficacy Measurements ............... 142 8.4 Aircraft Navigation and Data Logging ................... ~ 145 8.5 Investigating Possible Improvements in Application Methods with PKBW ......................................... 148 8.5.1 Utilization and Drift ofa Phytotoxic Herbicide ....... 148 8.5.2 "Smart" Formulations .......................... 153 TABLE OF CONTENTS vii CHAPTER 9 PESTICIDES AND GOVERNMENT REGULATIONS 9.1 Introduction ......................................... 156 9.2 Federal and Provincial Regulations in Canada .............. 157 9.3 Specific Excerpts from FIFRA .......................... 170 9.4 The Training of Pesticide Applicators and the Inspection of Application Equipment ...... . . . . . . . . . . . . . . . . . . . . . . . . . . 172 Appendix I SPRAY EFFICACY RESEARCH GROUP (SERG) 176 Appendix II ATOMIZER CHARAC1ERIZATION DATA .... 178 Appendix III DETAILS OF AGDISP, FSCBG, AND PKBW MODELS .................................... 206 Index .................................................... 209 PREFACE Introduced to the technical aspects of forestry aerial spraying in the mid-1970's, we were immediately impressed by the complexity of the process of delivering pesticide to foliage. At that time, there was a vigorous public debate in New Brunswick about the ecological and public h~alth impacts of the annual spray program for the control of defoliation of spruce and fir trees by the spruce budworm. The forest industry is important to the province and changes to the established procedures of budworm control could have major economic implications. A rational debate required reliable information about the mechanics of the spraying process. There was a need to supply missing information as to required pesticide application rates, atomizer performance, off-target drift and deposit, and the effects of weather and aircraft operating factors. We were invited to initiate a research program in this domain by New Brunswick forest management officials, and what follows in this book is a logical and quantitative description of the overall process based on our own research and that of others over the intervening years. After a short introduction to aerial spraying, we begin (Chapter 2) by describing forest stands in terms of their interaction with suspended atmospheric particulate material carried along by the wind and susceptible to deposition on foliage. We introduce foliage simulators and their use in measuring the deposit of sprayed pesticide on foliage, the "biological interface" between pest and pesticide. Chapter 3 treats the relationship between toxic requirement for pest control and droplet size, and the effects of physico-chemical properties of the formulation on droplet size. In Chapter 4, in addition to a cursory discussion of spray aircraft types and wake behaviour, we present a detailed account of spray atomizer droplet characterization methods and equipment, with an innovative use of the Malvern droplet spectrometer for flux-based droplet spectrum measurements. Tables of droplet spectrum data are given in Appendix II. Chapter 5 summarizes spray field trial methods and management, with a discussion of the importance of the mass balance criterion in assessing the overall accuracy of results. All of the mechanisms of the spray generation and deposition process are brought together within the framework of the PKBW computer model in Chapter 6. This is a droplet trajectory model permitting the calculation of deposited droplet size and density on the biological interface, as well as size and concentration in the drift cloud. Long-distance drift calculations are presented, as are model validation results. x PREFACE The last three chapters cover recent USDA Forest Service research on spraying in complex terrain, a presentation of some recent spraying innovations, and a review of some government regulations relating to pesticide application. We claim here to have a unique quantitative treatment of the many mechanisms involved in the pesticide application process. With the methods described here, it is possible to get a detailed and accurate prediction, via computer simulation, of droplet deposition and downwind drift of pesticide droplets. This offers an unparalleled tool in the continued development of pesticide application technology. We strongly encourage scientists, regulators, and forest managers to use the technology presented here in the i.-:terest of environmentally conscious forest management. J.J.C. Picot, Fredericton, N.B. D.O. Kristmanson, Surrey, B.c. ACKNOWLEDGEMENTS We recognize here the central role played by Mr. H.J. (Bud) Irving, then Managing Director of Forest Protection Ltd. of Fredericton, N.B., in initiating our interest in spray technology research and continuing as a "pons or and mentor of our research activities over the years. Acting on the advice of Dr. Frank Webb, former Director of the Maritimes Forest Research Center, he was successful in getting the collaboration of scientists from a wide range of disciplines in addressing problems in pesticide application technology soon after assuming his responsibilities in 1975. Our early learning experiences in this domain were greatly enhanced by interaction with colleagues already active in various aspects of spray technology research. Principal among these were R.S Crabbe of the National Research Council (NRC), Ottawa (dispersion of atmospheric pollutants and field trials); John Reid, Environment Canada, Ottawa (modelling the transport of atmospheric particulates); W.I. Varty, Forestry Canada, Fredericton (first chairman of interdisciplinary committee on monitoring of spray drift in N.B.); R.H. Wickens, NRC, Ottawa (wind tunnel operation and design, aircraft vortex behaviour); and Charles Wiesner, N.B. Research and Productivity Council (RPC), Fredericton, N.B. (first coordinator of the New Brunswick Spray Efficacy Research Group (now known as SERG)). Later, we were given valuable assistance by J.W. Barry, USDA Forest Service, Davis, CA, and lE. Hirsh, Princeton Aeronautical Research Associates, Princeton, N.J. in the area of aircraft spray transport and wake modelling. We greatly benefited from discussions with Professors Norman Akesson and Wesley Yates of the University of California at Davis, and earlier with R. Courshee, S. Parkin, and V. Joyce of the Cranfield Institute of Technology, Cranfield, England. Our research team at the University of New Brunswick has included many talented and dedicated individuals. Mr. Alfred Knappe, Chief Technician in our Chemical Engineering Department, was responsible for constructing the SERG/ONAIR prototype atomizers, and our wind tunnel with his assistant Brian Hawkins. Excellent work was done by the following graduate students over the years: Bruce Smedley, Terry Tornney, Malcolm Thompson, Xavier Bontemps, Nusin Basak-Brown, Michael Pang, David Wallace, and Robert Goguen. Stability and continuity in our wind tunnel and field trial work were assured by the efforts of Research Engineer Mark van Vliet assisted by Gary Henderson, Research Technician.