La gestion des ressources

AST

Réservoirs de stockage aériens (AST) : Un composant crucial dans le traitement de l'environnement et de l'eau

Les réservoirs de stockage aériens (AST) jouent un rôle essentiel dans l'industrie du traitement de l'environnement et de l'eau, offrant un stockage sûr et efficace pour une large gamme de substances. De l'eau potable aux produits chimiques dangereux, ces réservoirs constituent une solution vitale pour gérer et distribuer des ressources essentielles tout en minimisant l'impact environnemental.

Que sont les AST ?

Les AST, comme leur nom l'indique, sont de grands conteneurs construits au-dessus du niveau du sol pour stocker divers fluides. Ils sont généralement fabriqués à partir de matériaux durables tels que l'acier, le béton ou la fibre de verre et sont disponibles dans diverses tailles, formes et configurations en fonction des besoins spécifiques de l'application.

Applications dans le traitement de l'environnement et de l'eau :

1. Stockage d'eau potable : Les AST sont largement utilisés pour stocker l'eau potable dans les usines de traitement des eaux municipales, assurant un approvisionnement constant en eau potable propre aux communautés.

2. Traitement des eaux usées : Ces réservoirs peuvent stocker les eaux usées traitées avant leur rejet dans l'environnement, permettant une désinfection et une surveillance appropriées de la qualité de l'eau.

3. Stockage de produits chimiques : Les AST sont essentiels pour stocker en toute sécurité les produits chimiques utilisés dans les processus de traitement de l'eau, tels que les coagulants, les désinfectants et les agents de réglage du pH. Cela prévient les déversements et les fuites accidentels, protégeant ainsi la santé humaine et l'environnement.

4. Gestion des eaux pluviales : Les AST peuvent être intégrés dans les systèmes de gestion des eaux pluviales pour capturer et stocker les eaux de ruissellement provenant des précipitations, réduisant ainsi le risque d'inondation et permettant une libération progressive, minimisant ainsi la charge sur les systèmes d'égouts.

5. Eau de process industrielle : Les AST sont utilisés dans divers processus industriels nécessitant de grandes quantités d'eau, tels que la production d'énergie et la fabrication, assurant un approvisionnement régulier pour les opérations.

Principales caractéristiques et avantages des AST :

  • Sécurité : Les AST sont conçus pour répondre à des normes de sécurité strictes, minimisant le risque de fuites et de déversements, protégeant ainsi la santé humaine et l'environnement.
  • Efficacité : Ils constituent une méthode fiable et efficace de stockage et de distribution des fluides, assurant un approvisionnement régulier pour diverses applications.
  • Durabilité : Fabriqués à partir de matériaux robustes, les AST sont conçus pour résister à des conditions environnementales difficiles et à une utilisation prolongée.
  • Flexibilité : Ils sont disponibles dans une large gamme de tailles et de configurations pour répondre à des besoins de stockage divers.
  • Accessibilité : Les AST sont facilement accessibles pour l'inspection, la maintenance et le nettoyage, assurant des performances et une sécurité optimales.

Règlementation et conformité :

Les AST sont soumis à une réglementation et à des normes de conformité strictes pour garantir leur sécurité et la protection de l'environnement. Ces réglementations incluent souvent des exigences pour :

  • Construction et conception du réservoir : Les matériaux, l'épaisseur et l'intégrité structurelle sont rigoureusement surveillés.
  • Détection et prévention des fuites : Des systèmes et des procédures de surveillance sont en place pour détecter et prévenir les fuites.
  • Protection contre la corrosion : Des revêtements et des traitements sont appliqués pour empêcher la corrosion et prolonger la durée de vie du réservoir.
  • Confinement des déversements : Des systèmes de confinement secondaires sont souvent nécessaires pour prévenir une contamination généralisée en cas de fuite.
  • Inspections et maintenance régulières : Des contrôles et une maintenance réguliers sont essentiels pour garantir l'intégrité et la sécurité des AST.

Conclusion :

Les réservoirs de stockage aériens sont des actifs indispensables dans l'industrie du traitement de l'environnement et de l'eau, offrant des solutions de stockage sûres et fiables pour une large gamme de substances. En concevant, en entretenant et en réglementant soigneusement ces réservoirs, nous pouvons garantir la gestion responsable des ressources essentielles tout en protégeant la santé humaine et l'environnement.


Test Your Knowledge

ASTs Quiz:

Instructions: Choose the best answer for each question.

1. Which of the following is NOT a typical material used for constructing an Aboveground Storage Tank (AST)?

a) Steel

Answer

This is a common material for ASTs.

b) Concrete

Answer

Concrete is also frequently used in AST construction.

c) Plastic

Answer

While plastic is used for some storage containers, it's less common for large-scale ASTs.

d) Fiberglass

Answer

Fiberglass is another suitable material for AST construction.

2. What is a primary advantage of using ASTs for storing potable water?

a) Easier access for cleaning and maintenance.

Answer

This is a key advantage of ASTs, facilitating inspection and upkeep.

b) Lower construction costs compared to underground tanks.

Answer

While ASTs might be less expensive in some cases, this isn't the primary advantage for potable water storage.

c) Improved resistance to seismic activity.

Answer

While ASTs can be designed to withstand seismic activity, it's not the primary advantage for potable water storage.

d) Greater resistance to ground contamination.

Answer

This is a key advantage as ASTs are less susceptible to contamination from the surrounding soil.

3. What is the primary role of a secondary containment system for an AST?

a) To prevent spills from reaching the ground.

Answer

This is the primary function of a secondary containment system - preventing spills from contaminating the environment.

b) To increase the overall storage capacity of the tank.

Answer

Secondary containment systems are not designed to increase storage capacity.

c) To reduce the risk of corrosion on the tank's exterior.

Answer

Corrosion protection is achieved through coatings and treatments, not secondary containment.

d) To improve the aesthetic appearance of the tank.

Answer

Aesthetic considerations are not the primary focus of secondary containment systems.

4. Which of the following is NOT a common application of ASTs in the environmental and water treatment industry?

a) Storing treated wastewater before discharge.

Answer

ASTs are commonly used for this purpose in wastewater treatment plants.

b) Storing rainwater for irrigation purposes.

Answer

ASTs can be used to store rainwater for various purposes, including irrigation.

c) Storing hazardous materials like nuclear waste.

Answer

While ASTs are used for storing chemicals, nuclear waste requires specialized storage due to its radioactivity.

d) Storing chemicals used in water treatment processes.

Answer

ASTs are essential for safely storing chemicals used in water treatment.

5. Which of the following is a key aspect of AST regulations that contributes to environmental protection?

a) Requiring the use of specific types of pumps for fluid transfer.

Answer

Pump types are important but not the primary focus of regulations for environmental protection.

b) Implementing regular inspections and maintenance schedules.

Answer

This is a critical aspect of regulations, ensuring the tank's integrity and preventing leaks.

c) Restricting the use of ASTs in certain geographical locations.

Answer

While regulations might have restrictions, they are not the main focus for environmental protection.

d) Mandating the use of specific types of paint for the tank's exterior.

Answer

While paint type can play a role, it's not the primary focus for environmental protection regulations.

ASTs Exercise:

Scenario: A municipal water treatment plant is planning to install a new AST for storing potable water. The tank needs to hold a maximum of 1 million gallons of water.

Task: Research and suggest two different types of ASTs that could be suitable for this project. For each type, describe the following:

  • Material: (e.g., steel, concrete, fiberglass)
  • Advantages and Disadvantages: (e.g., durability, cost, maintenance requirements)
  • Typical Applications: (e.g., potable water, wastewater, chemical storage)

Exercice Correction:

Exercice Correction

Here are two potential AST types suitable for storing 1 million gallons of potable water:

Option 1: Steel AST with Epoxy Lining

  • Material: Steel with epoxy lining
  • Advantages:
    • High strength and durability.
    • Relatively low cost compared to other materials.
    • Wide range of sizes and configurations available.
  • Disadvantages:
    • Susceptible to corrosion without proper protection.
    • Requires regular inspection and maintenance of the lining.
  • Typical Applications: Potable water, wastewater, chemical storage

Option 2: Concrete AST

  • Material: Reinforced concrete
  • Advantages:
    • Extremely durable and long-lasting.
    • High resistance to corrosion and chemicals.
    • Low maintenance requirements.
  • Disadvantages:
    • More expensive than steel tanks.
    • Can be more complex to construct.
    • Limited in terms of shape and configuration.
  • Typical Applications: Potable water, wastewater, industrial process water

The best choice between steel and concrete will depend on factors like budget, site conditions, and specific requirements for the project. It's recommended to consult with an engineering firm specializing in AST design for a comprehensive assessment.


Books

  • "Handbook of Aboveground Storage Tanks" by R.M. Holsworth - A comprehensive guide covering design, construction, operation, and maintenance of ASTs.
  • "Aboveground Storage Tank Systems: Design, Construction, Operation, and Maintenance" by R.C. Reid and R.A. Green - Offers practical guidance on various aspects of ASTs, including regulations and environmental considerations.
  • "Environmental Engineering: A Textbook for Students" by Davis and Cornwell - A general textbook covering environmental engineering concepts, with a section on storage and handling of hazardous materials.

Articles

  • "Aboveground Storage Tanks: A Guide to Design, Construction, Operation, and Maintenance" by the American Petroleum Institute (API) - A detailed technical guide with industry best practices.
  • "Environmental Regulations for Aboveground Storage Tanks" by the U.S. Environmental Protection Agency (EPA) - Explains regulations related to ASTs and their implementation.
  • "Aboveground Storage Tank Systems for Wastewater Treatment" by the Water Environment Federation (WEF) - A focus on AST applications in wastewater treatment facilities.

Online Resources

  • EPA's Aboveground Storage Tanks (AST) website: https://www.epa.gov/ast - Provides information on regulations, permits, and guidance for ASTs.
  • National Tank Association (NTA): https://www.natank.com - Industry association offering resources, training, and advocacy related to ASTs.
  • American Society of Civil Engineers (ASCE): https://www.asce.org - Provides technical information and resources on various engineering topics, including AST design and construction.

Search Tips

  • Use specific keywords like "aboveground storage tanks environmental regulations" or "AST wastewater treatment applications."
  • Combine keywords with location-based searches like "AST regulations California" or "aboveground storage tank companies Texas."
  • Utilize advanced search operators like quotation marks ("") for exact phrase matching and "-" for excluding specific terms.

Techniques

Aboveground Storage Tanks (ASTs): A Comprehensive Guide

This guide expands on the importance of Aboveground Storage Tanks (ASTs) in environmental and water treatment, delving into specific technical aspects, modeling techniques, relevant software, best practices, and real-world case studies.

Chapter 1: Techniques for AST Design, Construction, and Maintenance

This chapter focuses on the practical techniques involved in the lifecycle of an AST.

1.1 Design Techniques:

  • Material Selection: Choosing appropriate materials (steel, fiberglass, concrete) based on stored substance, environmental conditions (temperature, UV exposure, soil conditions), and regulatory requirements. Specific considerations for corrosion resistance, chemical compatibility, and structural integrity are crucial.
  • Structural Design: Calculations to ensure the tank can withstand hydrostatic pressure, wind loads, seismic activity, and potential overfilling. This includes considerations for tank geometry (cylindrical, rectangular), wall thickness, and support structures.
  • Leak Detection Systems: Discussion of various leak detection methods, including automatic tank gauging (ATG), ultrasonic leak detection, and interstitial monitoring. The selection process considers the stored substance, tank material, and regulatory requirements.
  • Secondary Containment: Design and implementation of secondary containment structures (e.g., concrete basins, berms) to prevent environmental contamination in the event of a primary tank failure. This includes considerations for capacity, drainage, and material compatibility.
  • Spill Prevention, Control, and Countermeasures (SPCC) Plan: Development and implementation of a comprehensive SPCC plan to minimize the risk of spills and effectively respond to potential incidents.

1.2 Construction Techniques:

  • Foundation Preparation: Proper site preparation, including soil analysis and foundation design to ensure stability and prevent settling.
  • Tank Erection: Safe and efficient methods for assembling and erecting the AST, ensuring proper alignment and sealing.
  • Piping and Instrumentation: Installation of piping systems, valves, instrumentation, and safety devices according to industry standards and regulatory requirements.
  • Testing and Commissioning: Thorough testing of the AST and associated systems to ensure leak-tightness, proper functionality, and compliance with design specifications.

1.3 Maintenance Techniques:

  • Inspection and Monitoring: Regular inspections to identify potential problems, including corrosion, leaks, and structural damage. Methods for monitoring tank levels, temperature, and pressure.
  • Cleaning and Repair: Techniques for cleaning and repairing damaged tanks, including methods for removing sediment, repairing cracks, and recoating corroded surfaces.
  • Corrosion Protection: Strategies for mitigating corrosion, including the application of protective coatings, cathodic protection, and regular maintenance.

Chapter 2: Models for AST Performance and Risk Assessment

This chapter explores the use of models to predict AST behavior and assess risks.

2.1 Hydrostatic Pressure Models: Calculation of pressure exerted by the stored fluid on the tank walls and base. Factors affecting pressure, including fluid density, tank geometry, and filling level. 2.2 Stress Analysis Models: Finite element analysis (FEA) and other computational methods to assess the structural integrity of the tank under various loading conditions (hydrostatic pressure, wind, seismic). 2.3 Leak Detection Models: Mathematical models to predict the rate of leakage and the time required to detect a leak using different monitoring systems. 2.4 Spill Modeling: Simulation of spill scenarios to estimate the extent of contamination and the effectiveness of containment measures. 2.5 Risk Assessment Models: Quantitative risk assessment (QRA) techniques to evaluate the probability and consequences of potential accidents involving ASTs. This includes the use of fault tree analysis (FTA) and event tree analysis (ETA).

Chapter 3: Software for AST Design, Simulation, and Management

This chapter reviews relevant software tools.

  • Computer-Aided Design (CAD) Software: Use of CAD software for designing and drafting ASTs, including generating detailed drawings and specifications. Examples include AutoCAD, SolidWorks, and Revit.
  • Finite Element Analysis (FEA) Software: Software for performing stress analysis and structural simulations of ASTs. Examples include ANSYS, Abaqus, and Nastran.
  • Process Simulation Software: Software for simulating the flow of fluids within and around ASTs. Examples include Aspen Plus and Pro/II.
  • Leak Detection and Monitoring Software: Software for monitoring tank levels, pressure, and temperature, and for analyzing leak detection data.
  • Geographic Information System (GIS) Software: Use of GIS software for mapping AST locations and tracking maintenance activities. Examples include ArcGIS and QGIS.

Chapter 4: Best Practices for AST Operation and Management

This chapter details recommendations for safe and efficient AST operation.

4.1 Regulatory Compliance: Adherence to all relevant environmental regulations and industry standards related to AST design, construction, operation, and maintenance. 4.2 Preventative Maintenance: Regular inspections, cleaning, and repairs to prevent leaks and ensure long-term operational reliability. 4.3 Spill Prevention and Response: Implementation of comprehensive spill prevention and response plans, including employee training and emergency procedures. 4.4 Inventory Management: Effective tracking of stored substances to ensure proper inventory levels and prevent overfilling. 4.5 Safety Procedures: Establishment of strict safety procedures for all AST-related activities, including access control, lockout/tagout procedures, and personal protective equipment (PPE) requirements. 4.6 Personnel Training: Providing comprehensive training to personnel responsible for the design, construction, operation, and maintenance of ASTs.

Chapter 5: Case Studies of AST Applications and Incidents

This chapter presents real-world examples.

This section would include case studies illustrating successful AST installations and operations, as well as examples of incidents (leaks, spills, failures) and the lessons learned from those incidents. The case studies would highlight the importance of proper design, construction, operation, and maintenance in ensuring AST safety and environmental protection. Specific examples might include:

  • A case study of a successful AST installation for potable water storage in a municipal water treatment plant.
  • A case study of an AST failure and the resulting environmental consequences, highlighting the importance of preventative maintenance and regulatory compliance.
  • A case study demonstrating the effectiveness of a particular leak detection system.
  • A case study illustrating the challenges and solutions associated with storing specific hazardous chemicals in ASTs.

This comprehensive guide provides a detailed overview of Aboveground Storage Tanks, offering valuable insights for engineers, operators, and regulators involved in their design, construction, and management.

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  • ASTM ASTM : Un fondement pour les …
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