Introduction

Summer in Australia and New Zealand presents a unique challenge for water infrastructure, particularly with increasing water main breaks. In this blog post, we delve into the reasons behind these breaks and explore practical strategies such as pipeline condition assessment, pressure transient monitoring, and active leak detection to mitigate these issues.

Why Do Water Main Breaks Occur More in Summer?

  1. Thermal Expansion: High temperatures cause the ground to dry out and shift in the summer. This movement can place additional stress on water pipelines, especially older ones made of cast iron and ductile iron, commonly found in Australia and New Zealand. These materials, while durable, are less flexible and more prone to cracking under stress.
  2. Increased Water Demand: Summers are characterised by higher water usage for gardening and filling swimming pools. This increases water pressure and flow rate within the mains, stressing the system, especially in older pipelines.
  3. Ageing Infrastructure: Many areas in Australia and New Zealand have water systems with ageing infrastructure. Cast and ductile iron pipes, which have been in service for decades, are susceptible to corrosion and degradation, increasing the risk of breaks.

Mitigation Strategies

Active Leak Detection

Active leak detection involves regularly inspecting the water distribution system to identify and repair leaks before they lead to major breaks. This proactive approach uses technologies like acoustic sensors and correlators to detect the sound of water escaping from the pipes, which also helps reduce non-revenue water and operate more efficiently.

Pipeline Condition Assessment

This involves evaluating the current state of the water distribution infrastructure to prioritise maintenance and replacement. Pipeline condition assessment technologies such as Dynamic Response Imaging, electromagnetic inspection and wall thickness measurements are widely used all year round to help water authorities proactively repair, replace and rehabilitate sections of water mains at risk of failure.

Pressure Transient Monitoring

Pressure transients are rapid changes in pipeline pressure caused by operations like pump startups, network operations, or large customer usage profiles. Monitoring these transients helps identify conditions that may lead to pipeline failures, allowing network calming initiatives to be initiated.

Real-Time Pipeline Monitoring

Implementing real-time pipeline monitoring systems allows for immediate detection and response to abnormal conditions in the pipeline network — such as when a burst occurs. This includes monitoring flow rates, pressure transient, and even the chemical composition of the water.

Accelerating Reactive Response to Water Main Breaks: Effective Strategies

In addition to proactive measures to prevent water main breaks, having a rapid and efficient reactive response plan is crucial, especially during the challenging summer months in Australia and New Zealand. Here are some strategies to ensure a faster reactive response to such incidents:

Maintaining a Ready Inventory of Spare Parts

Flexible Procurement Strategies

Engaging Specialist Third-Parties for Assistance

Mobile Repair Units

Community Engagement and Communication

Conclusion

With the challenges posed by summer conditions in Australia and New Zealand, especially with ageing infrastructure like cast iron and ductile iron pipes, adopting a proactive approach to pipeline management is essential. Techniques such as active leak detection, pipeline condition assessment, pressure transient monitoring, and real-time pipeline monitoring play a crucial role in reducing water main breaks and ensuring the reliability of water supply systems. These strategies not only enhance the efficiency of water distribution but also contribute to sustainable water management in these regions.

Aqua Analytics is a specialist provider of water network management solutions that help New Zealand and Australian water authorities reduce system losses and prevent water main breaks. Contact us today for a free consultation about how we can assist your team in managing their pipeline network today.

In the quest for improved water leakage management, pressure transient monitoring has emerged as an effective strategy. This approach provides a thorough understanding of water systems, enabling us to reduce water loss effectively. In this blog, we will explore the intricacies of pressure transient monitoring and its significant role in water conservation in our drinking water systems.

Understanding the Concept of Pressure Transient Monitoring

Pressure transients, also called water hammers, are abrupt variations in water pressure within a system. If left unchecked, these changes can significantly damage pipelines, potentially causing catastrophic failures. Pressure transient monitoring allows for rapid detection of these potentially damaging high-speed pressure changes in the pipelines under our cities and towns. Key aspects that make pressure transient monitoring a critical tool in water management include:

  • Rapid Detection: One of the standout benefits of pressure transient monitoring is its ability to immediately identify pressure spikes in a water system quickly. This swift detection enables timely intervention, reducing the likelihood of pipe bursts and system failures.
  • Real-time Data: Pressure transient monitoring provides detailed, real-time data about the water system. This data can offer invaluable insights, allowing for more informed decision-making and improved planning and forecasting.
  • Proactive Response: Through the analysis of the patterns and timing of pressure transients, preventive strategies can be implemented to mitigate the adverse effects. This proactive approach, in turn, can significantly reduce water loss.

The Science Behind Pressure Transients

Understanding the mechanism behind pressure transients or water hammers can help understand why monitoring them is critical. When the flow of water is abruptly stopped or changed, it creates a sudden shift in momentum. It causes a wave of high pressure to ripple through the system. This phenomenon is known as a pressure transient. Such events can be triggered by various factors, such as:

  • Rapid valve operations
  • Pump start-ups or shut-downs
  • Unexpected power failures
  • Quick changes in demand

A Closer Look at Pressure Transient Monitoring Devices

Pressure transient monitoring devices are critical elements in detecting and managing water hammers in reticulation networks. These devices are designed to measure sudden pressure changes and relay this data for analysis via cellular communications and cloud servers. Key features of these devices include:

  • High Sensitivity: The devices can detect minute pressure changes, ensuring no event goes unnoticed.
  • Data Logging: They have built-in memory to log data over time, providing a comprehensive view of the system’s performance.
  • Durability: These devices are often designed to withstand harsh environments, ensuring reliable operation over extended periods.

The Steps to Implementing Pressure Transient Monitoring

Pressure transient monitoring is utilised in various settings, including industrial and commercial properties (major transport facilities) and water supply networks. Below are the typical steps for implementing pressure transient monitoring:

  • Design of Deployment: Reviewing the project site, facilities and available appurtenances allows for a deployment design to be completed to ensure the efficiency in field operations.
  • Installation of Monitoring Devices: The initial field phase involves the placement of pressure monitoring devices within the water system. These devices are designed to measure and monitor pressure changes effectively in excess of 100 times per second.
  • Data Collection and Analysis: Once installed, these devices gather a vast amount of data. This data is then meticulously analysed to reveal patterns and identify potential issues within the system.
  • Implementation of Preventive Measures: The insights from the data analysis are then employed to create effective strategies. These strategies, when implemented, work to mitigate the effects of pressure transients and consequently reduce water loss.

The Impact of Pressure Transient Monitoring

Minimising water loss is more than just an environmental concern. Pressure transient monitoring yields a range of benefits that extend beyond water conservation:

  • Conservation of Resources: Reducing water loss leads to significant savings in energy, as well as in the costs associated with water treatment and distribution. When we minimise water loss, we can efficiently utilise these valuable resources.
  • Enhanced System Longevity: Regular monitoring and management of pressure transients can prevent undue stress on water systems. By mitigating these risks, water systems’ lifespan and overall performance can be significantly improved.
  • Robust Monitoring and Management: The constant vigilance provided by pressure transient monitoring allows for more robust management of water systems. A comprehensive understanding of water pressure variations allows for proactive planning and system management.
  • More Liveable Cities: Fewer burst water mains and disruptions to service in our cities, towns and communities through the proactive monitoring and intervention of pressure transients, leading to a calmer water supply network.

Pressure Transient Monitoring Solutions

At Aqua Analytics, we provide high-quality pressure transient monitoring solutions to alleviate network disruptions effectively. The data gathered from these monitoring operations is invaluable, providing insights that can help optimise maintenance schedules. Reach out to us today!

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