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Cooling Water Treatment Principles and Practices: Charts and Notes For Field Use; Is the companion field guide handbook to Cooling Water Treatment Principles and Practices by Colin Frayne. In this handbook you will find many helpful formulas for use in the field such as formulas for: Refrigeration in cooling towers, Conductive heat flow, General industrial and cooling water makeup contents, Coagulants and flocculants, Filter types, Water softeners, Commonly found corrosion types, Mineral and silica deposit types, Equations for solving pH, Common bacteria and Fungi types, Inhibitor components, A suggested biocide selection chart for comfort cooling systems, A cleaning and disinfection program for cooling systems, and Cooling water control parameters. The charts and formulas contained in this field handbook provide an overview of many situations encountered in the field and will aid in the diagnosis and solution of many water issues you will encounter on the job. Also provided are two separate sections for keeping notes on specific issues. Other titles by author Colin Frayne: 0-8206-0371-6 Boiler Water Treatment, Principles and Practice, Vol. I 0-8206-0400-3 Boiler Water Treatment, Principles and Practice, Vol. II
Table of Contents: About the Author - Saturated steam temperatures at various boiler pressures - Boiler Energy and Power Units - Typical gross heating values of common fuels (based on approximately 80% fuel to steam efficiency) - Typical energy consumption and output ratings for a fire tube boiler - Steam tables suitable for pressure deaerators - Calculating Blowdown - Coefficients of thermal conductivity for some heat-exchanger metals and boiler deposits - Types of water or steam commonly employed in most HW heating and steam generating plants - Commonly occurring minerals in natural MU water sources - Specific waterside / steamside problems affecting MPHW and HPHW boiler plants - Salt concentration indicators - Summary of waterside / steamside problems affecting LPHW and LP steam heating boiler plants - FW contamination from MU water - FW contamination from returned condensate - Problems associated with the final FW blend - Deposition of boiler section waterside surfaces by alkaline earth metal salts, other inorganic salts and organics - Silica and silicate crystalline scales and deposits affecting boiler section waterside surfaces - Iron oxide and other boiler section corrosion debris deposits - Boiler section corrosion problems involving oxygen, concentration cells and low pH - Stress and high temperature related corrosion - Steam purity, quality and other operational problems - Specification for grades of high-quality water suitable for higher pressure WT boilers - Practical considerations for a RW ion-exchange softener - Types of Internal Treatment Program - Carbonate Cycle Requirement Calculations - Phosphate-Cycle Requirement Calculations - A Guide to Tannin Residuals in BW - Carbonate-Cycle Program. BW Carbonate Reserve Requirements by Pressure and Sulfate Concentration - Carbonate-Cycle Coagulation and Precipitation Program. Recommended BW Control Limits for Non-Highly-Rated FT Boilers Employing Hard or Partially Softened FW - Phosphate-Cycle Coagulation and Precipitation Program. Recommended BW Control Limits for Non-Highly-Rated FT Boilers Employing Hard, Partially Softened, or Fully Softened FW - Phosphate-Cycle Coagulation and Precipitation Program. Recommended BW Control Limits for Non-Highly-Rated WT Boilers Employing Hard, Partially Softened, or Fully Softened FW - Chelant demand (ppm product) per 1ppm substrate EDTA Chelant or All-Polymer/All-Organic Program. Recommended BW Control Limits for Fired WT Boilers Employing Demineralized or Similar Quality FW - Oxygen Solubility at Atmospheric Pressure - Properties of Oxygen Scavengers - Carbon Dioxide Evolution from FW Alkalinity - Amine Requirement to Reach a Stable Condensate pH - Amine Basicity Dissociation Constants - Neutralizing Amine Summary Notes - Some DR values for CO2, NH3 and neutralizing amines at various pressures - Calculating Alkalinity Feed-Rate Requirements - [ASME Consensus table 1: Suggested water chemistry limits. Industrial watertube, high duty, primary fuel fired, drum typeMakeup water percentage: Up to 100% of feedwater. Conditions: Includes superheater, turbine drives or process restriction on steam purity] - [ASME Consensus table 2: Suggested chemistry limits. Industrial watertube, high duty, primary fuel fired, drum type] - [ASME Consensus table 3: Suggested chemistry limits. Industrial firetube, high duty, primary fuel fired] - [ASME Consensus table 4: Suggested water chemistry limits. Industrial coil type, watertube, high duty, primary fuel fired rapid steam generators] - [ASME Consensus table 5: Suggested water chemistry limits. Marine propulsion, watertube, oil fired drum type] - [ASME Consensus table 6: Suggested water chemistry limits. Electrode, high voltage, forced circulation jet type] - Notes
BOILER WATER TREATMENT, PRINCIPLES AND PRACTICE VOLUME 1 of Two Volumes by COLIN FRAYNE. Vol. I: Boiler Basics and Steam Water Chemistry, ISBN: 0-8206-0371-6 This comprehensive reference is the most practical field guide ever written on steam and boiler water treatment. In this two-volume handbook, Colin Frayne (Cooling Water Treatment, Principles and Practice, also by Chemical Publishing) analyzes the whole spectrum of boiler systems, including those used in residential complexes, commercial and institutional buildings, and industrial facilities. The breadth of the book covers: All types of boilers plants, from small cast iron units to large utility and nuclear power plants. Boiler subsystems, appurtenances, and auxiliaries Boiler maintenance and troubleshooting, fuel treatments, combustion gas analysis, pre-treatment processes, chemicals, and operational management Historical and modern program design and control in accordance with international standards Introduction; The Function of Boiler Water; Treatment and Its Marketing Steam Generation; Boiler Types and Applications; Boiler Plant Subsystems, Appurtenances, and Auxiliaries; Waterside and Steamside Problems: The Basics; Waterside and Steamside Problems: Hot Water Heating and Low-Pressure Steam Boiler; Waterside and Steamside Problems: Pre-Boiler Section Specifics; Waterside and Steamside Problems: Boiler Section Specifics; Waterside and Steamside Problems: Post-Boiler Section Specifics; Pre-Boiler and Post-Boiler Treatment Processes; Internal Treatment Programs; Adjuncts and Conjuctional Treatments; Control of Boiler Water Chemistry; Operational Control of Waterside Surfaces; Control of Fireside Conditions and Surfaces. Appendix I Useful Data; Appendix II Glossary; Bibliography. Index. This book is Volume 1 of a 2 Volume set. Other titles by author Colin Frayne: Cooling Water Treatment: Principles and Practice ISBN 978-0-8206-0370-4; Cooling Water Treatment Principles and Practices: Charts and Notes For Field Use ISBN 978-0-8206-0003-1
PARTIAL CONTENTS - PART - I. BOILER BASICS - Chapter 1. Boiler - An Introduction - Chapter 2. Classification of Boilers - Chapter 3. Common Terms and Explanation - PART - II. BOILER WATER TROUBLES - Chapter 4. Impurities in Water and Their Effects - Chapter 5. Boiler Water Troubles - A Prelude - Chapter 6. Scale Formation - Chapter 7. Silica Carryover - Chapter 8. Scale Formation in Economizers - Chapter 9. Super Heater and Turbine Deposits - Chapter 10. Corrosion - Basic Information - Chapter 11. General Corrosion (Overall Corrosion / Acidic Corrosion) - Chapter 12. Dissolved Oxygen Corrosion (Pitting Corrosion) - Chapter 13. Carbondioxide Corrosion - Chapter 14. Corrosion caused by Unstable Salts - Chapter 15. Corrosion caused by Other Substances - Chapter 16. Corrosion caused by Chelants (Chelant Corrosion) - Chapter 17. Caustic Embrittlement and Caustic Gouging - Chapter 18. Hydrogen Embrittlement - Chapter 19. Condensate Corrosion - Chapter 20. Preboiler Corrosion - Chapter 21. Economizer Corrosion - Chapter 22. Super Heater and Turbine Corrosion - Chapter 23. Foaming, Priming & Carryover - PART - III. WATER QUALITY REQUIREMENTS AND TREATMENT PROGRAMS - Chapter 24. Quality Requirements for Feed Water and Boiler Water - Chapter 25. Objectives of Boiler Water Treatment - Chapter 26. External Treatment and Internal Treatment - Chapter 27. Water Treatment programs - Guidelines - PART - IV. EXTERNAL TREATMENT - Chapter 28. External Treatment - A Prelude - Chapter 29. Coagulation (Removal of Color, Turbidity and Suspended Matter) - Chapter 30. Filtration - Chapter 31. Softening by Chemical Method (Lime - Soda Softening) - Chapter 32. Ion Exchange Resins and Treatment Methods - Chapter 33. Softening by Ion-Exchange Method - Chapter 34. Dealkalization - Chapter 35. Demineralization (Deionization) - Chapter 36. Mixed Bed Deionization - Chapter 37. Reverse Osmosis - Chapter 38. Evaporation - Chapter 39. Silica Removal - Chapter 40. Oil Removal - Chapter 41. Condensate Treatment (Condensate Polishing) - Chapter 42. Deaeration (Mechanical Removal of Oxygen) - PART - V. INTERNAL TREATMENT - Chapter 43. Internal Boiler Water Treatment - A Prelude - Chapter 44. Organic Polymers and Their Role as Scale Inhibitors, Dispersants and Sludge Conditioners in Boiler Water Treatment - Chapter 45. Internal Treatment - Chemical Feeding - Chapter 46. Prevention of Scale Formation - Chapter 47. Sludge Conditioning - Chapter 48. Prevention of Corrosion - An Introduction - Chapter 49. Prevention of Corrosion Due to Low pH - Chapter 50. Prevention of Pitting Corrosion Using Oxygen Scavengers (Chemical Removal of Oxygen) - Chapter 51. Prevention of Caustic Embrittlement and Caustic Gouging - Chapter 52. Prevention of Chelant Corrosion - Chapter 53. Prevention of Condensate Corrosion - Chapter 54. Prevention of Pre-Boiler Corrosion - Chapter 55. Prevention of Economizer Corrosion - Chapter 56. Prevention of Foaming, Priming & Carryover - Chapter 57. Prevention of Silica Carryover - Chapter 58. Boiler Blow Down - PART - VI. BOILER WATER TREATMENT - IMPORTANT CALCULATIONS - Chapter 59. Basic Conversion Factors - Chapter 60. Water Softening - Calculations - Chapter 61. Cycles of Concentration, Blowdown, Feed Water and Makeup Water - Calculations - Chapter 62. Determination of Dosage of Chemicals - PART - VII. BOILER START UP, CLEANING, LAY UP AND MAINTENANCE - Chapter 63. Boiler Startup (Pre-operational Cleaning) - Chapter 64. Descaling and Boiler Cleaning - Chapter 65. Boiler LayUp - Chapter 66. Boiler Maintenance - PART - VIII. CHEMICALS HANDLING, SOLUTION PREPARATION AND FEEDERS - Chapter 67. Chemicals Handling and Storage - Chapter 68. Preparation of Solutions and Suspensions - Chapter 69. Chemical Feeders - PART - IX. ANALYSIS OF WATER AND STEAM - See Website for full TOC
Industrial Wastewater Treatment, Recycling and Reuse is an accessible reference to assist you when handling wastewater treatment and recycling. It features an instructive compilation of methodologies, including advanced physico-chemical methods and biological methods of treatment. It focuses on recent industry practices and preferences, along with newer methodologies for energy generation through waste. The book is based on a workshop run by the Indus MAGIC program of CSIR, India. It covers advanced processes in industrial wastewater treatment, applications, and feasibility analysis, and explores the process intensification approach as well as implications for industrial applications. Techno-economic feasibility evaluation is addressed, along with a comparison of different approaches illustrated by specific case studies. Industrial Wastewater Treatment, Recycling and Reuse introduces you to the subject with specific reference to problems currently being experienced in different industry sectors, including the petroleum industry, the fine chemical industry, and the specialty chemicals manufacturing sector. - Provides practical solutions for the treatment and recycling of industrial wastewater via case studies - Instructive articles from expert authors give a concise overview of different physico-chemical and biological methods of treatment, cost-to-benefit analysis, and process comparison - Supplies you with the relevant information to make quick process decisions
Practical techniques for handling industrial waste and designing treatment facilities Practical Wastewater Treatment is designed as a teaching and training tool for chemical, civil, and environmental engineers. Based on an AIChE training course, developed and taught by the author, this manual equips readers with the skills and knowledge needed to design a wastewater treatment plant and handle various types of industrial wastes. With its emphasis on design issues and practical considerations, the manual enables readers to master treatment techniques for managing a wide range of industrial wastes, including oil, blood and protein, milk, plating, refinery, and phenolic and chemical plant wastes. A key topic presented in the manual is biological modeling for designing wastewater treatment plants. The author demonstrates how these models lead to both more efficient and more economical plants. As a practical training tool, this manual contains a number of features to assist readers in tackling complex, real-world problems, including: * Examples and worked problems throughout the manual demonstrate how various treatment plants and treatment techniques work * Figures and diagrams help readers visualize and understand complex design issues * References as well as links to online resources serve as a gateway to additional information * Practical design hints, stemming from the author's extensive experience, help readers save time and avoid unwanted and expensive pitfalls * Clear and logically organized presentation has been developed and refined based on an AIChE course taught by the author in the United States, Mexico, and Venezuela Whether a novice or experienced practitioner, any engineer who deals with the treatment of industrial waste will find a myriad of practical advice and useful techniques that they can immediately apply to solve problems in wastewater treatment.
Principles of Water Quality Control is the definitive student text in its field for 25 years, this new edition takes an environmental perspective that is highly relevant in the context of current public policy debates. New material also includes EU regulations and changes in the UK water industry since privatisation. The latest technological developments are also taken into account. As before, the book is intended for undergraduate courses in civil engineering and the environmental sciences, and as preliminary reading for postgraduate courses in public health engineering and water resources technology. It will also be a vital text for post-experience training and professional development, in particular for students preparing for the examinations of the Institute of Water Pollution Control and the Institution of Public Health Engineers. - 25 Years worth of students can't be wrong - International relevance - Long established Pergamon title
Legionnaires' disease, a pneumonia caused by the Legionella bacterium, is the leading cause of reported waterborne disease outbreaks in the United States. Legionella occur naturally in water from many different environmental sources, but grow rapidly in the warm, stagnant conditions that can be found in engineered water systems such as cooling towers, building plumbing, and hot tubs. Humans are primarily exposed to Legionella through inhalation of contaminated aerosols into the respiratory system. Legionnaires' disease can be fatal, with between 3 and 33 percent of Legionella infections leading to death, and studies show the incidence of Legionnaires' disease in the United States increased five-fold from 2000 to 2017. Management of Legionella in Water Systems reviews the state of science on Legionella contamination of water systems, specifically the ecology and diagnosis. This report explores the process of transmission via water systems, quantification, prevention and control, and policy and training issues that affect the incidence of Legionnaires' disease. It also analyzes existing knowledge gaps and recommends research priorities moving forward.