让水系统更加智能和普及,我们需要“get MAD”

To make water systems smarter and available for all, we need to get MAD

by Gustaf Olsson, Lund University, Sweden; IWA Journal Editor

When is a water system smart? At a minimum, if it produces an acceptable product while minimizing energy and other resource requirements. It’s a system that should respond rapidly to disturbances and recover quickly after a major upset. Instrumentation, control and automation are the key ingredients of a smart system, enabling a simple framework that a control engineer calls the feedback loop. We call it the MAD approach to smart water management: M is for Measure; A for analysis; and D for Decision-making.

To measure is to know and this requires adequate data in space and in time. Data analysis is critical to understand and interpret data in a way that will turn it into useful information. This is the basis for making decisions, manually or automatic.

Measurement

Sensors and instruments that provide adequate data are the basis of “smart”. Measured or observed phenomena are the foundation for all feedback. Flow rates, and a multitude of concentrations and quality parameters, are the foundation for all operations in water systems. Instrumentation must be robust, easy to maintain and cost effective. This is even more important in an unmanned process.

For a long time, instrumentation was considered the bottleneck for control and automation in water systems. This is no longer the case. The development of nutrient sensors in the last two decades has been impressive, and there is an interesting progress towards “smart” sensors with multiple heads, able to be placed anywhere in a process.

Analysis

Unlike humans, computers are infinitely attentive and can detect abnormal patterns in operating data. Monitoring the key parameters and operational state of a process or a machine via online instrumentation reduces the risks for operational problems and other errors. Consistent monitoring of the “product quality” will prevent problems growing too large. By rapidly detecting deviations from “normal”, it’s possible to minimize the costs of abnormal behaviour.

Monitoring the machinery and the plant equipment forms the basic level of diagnosis. Simple indicators can warn if a motor is not running or if pressure is getting too high or too low. Alarms triggered by rapidly changing equipment behavior or basic physical parameters – like flowrates, pressures, or levels – are essential pieces of information.

At the other extreme, biological parameters will change slowly. For example, floc settling properties depend, among other things, on the species of organisms. It is important to detect early signs of flow settling changes. Once they are apparent we may have sludge bulking, and it‘s too late to make simple corrections. Early warning systems are critical in biological wastewater treatment.

Any monitoring system must determine whether the acquired data are meaningful and correct. Before any analysis can be made it is crucial to rectify or screen the data so that false conclusions are avoided. Irrelevant information – noise or extreme data points – must be removed.

Decision (control)

Having obtained data that is getting screened and analysed, a decision can be made, either automatically or manually. Decisions can then be made based on the defined goal or purpose of the system, before being translated to action via an actuator, typically a motor, a pump, a valve or a compressor.

By adopting MAD thinking it’s possible to make water systems smarter. MAD principles are functional in all timescales, from equipment operation in the time scale of seconds, to the management of a plant in the order to months or longer.

How do we meet the other criteria for a smart system: minimizing energy and other resource requirements?

Two parallel developments have the potential to significantly transform water supply and wastewater treatment systems: renewable energy and decentralization. Renewable energy, primarily solar and wind power, is already revolutionizing the availability of affordable clean energy. The growing development of decentralized water systems is accelerating smart solutions, using adequate sensors, control and automation becomes critical.

The water sector is energy intensive, and available, affordable electricity is critical to pump and treat water. Approximately 84% of the global population has access to electricity, implying that almost 1.2 billion people are still without it. In many regions with energy poverty there are abundant renewable energy sources. In Africa and Asia particularly, a lot of rural areas are not connected to any grid infrastructure. Here solar and wind power offer huge opportunities, providing energy for pumping, for water re-use and purification using different technologies in decentralized systems.

Smart water supply and treatment systems that take advantage of affordable renewable energy in combination with adequate automation, present a real opportunity to satisfy two of the UN Sustainable Development Goals: clean water and energy for all.

(0)

相关推荐

  • 永续耕种设计原理 | 能量循环 (中英文对照)

    回复"教程"送你一篇特别的推送 良好的设计,在意于使用基地上所产生的自然能源,并能确保完整的能量循环.--比尔·莫里森 6. Energy Cycling 6. 能量循环 The ...

  • Op

    Credit: boozallen.com From analyzing the terrain on Mars to enhancing communications between satelli ...

  • 智能电视普及暴露了一个严重问题,系统用3...

    智能电视普及暴露了一个严重问题,系统用3-4年后会卡顿,用6年后开机都卡顿,只能考虑换新电视.哪怕外接一台网络视频盒子也无法解决问题,因为开机找到视频输入界面也要5分钟.为此,有网友说,以后的智能汽车 ...

  • 汽轮机本体疏水系统[汽轮机本体疏水系统]

    在汽轮机组启机.停机及变负荷工况运行时,蒸汽与汽轮机本体和蒸汽管道接触,蒸汽被冷却或加热.当蒸汽温度被冷却到低于其压力所对应的饱和温度时,部分蒸汽会凝结成水.由于蒸汽和水的密度和流速不同,管道对它们的 ...

  • 消防水系统温度大总结

    一. 消防给水及消火栓系统 <消防给水及消火栓系统>GB50974-2014规定: 5.2.5 高位消防水箱间应通风良好,不应结冰,当必须设置在严寒.寒冷等冬季结冰地区的非采暖房间时,应采 ...

  • 大型中央空调系统原理介绍,冷冻水系统详解

    今天我们一起来学习下大型中央空调系统中的冷冻水系统. 在空调系统中它包括冷却水系统.冷冻(媒)水系统和冷凝水排水系统. 我们的水系统的作用是为我们的空调机组提供冷热量. 空调冷冻水:通过冷冻水泵,把蒸 ...

  • 加大秦岭水系统安全南水北调工程生态气候科教国际合作

    中科院水系统安全-东胜实业秦岭水系统安全院士专家研究项目 2021年5月15日 "终南阴岭秀,碧嶂插遥天:太白有鸟道,秦塞绝人烟."古人的诗词,勾勒了巍峨而厚重的秦岭--西起甘肃, ...

  • 全球首款搭载华为鸿蒙系统的智能空调首发上市!美的创造

    全球首款采用华为鸿蒙系统的智能空调来了!日前,美的空调正式对外宣布,首款搭载华为鸿蒙系统的智能空调中国尊鸿蒙艺术柜机,将于今年5月起上市销售,于今年空调旺季市场上掀起一轮全新的主动智能.新风无风感的智 ...

  • 消防水系统沟槽连接技术详解

    来源:建筑水电知识平台 如有侵权,请联系删除 正文如下: 前言 管道沟槽连接技术兴起于20世纪50年代的美国,90年代末引入中国.此后,以其安装便捷.质量可靠.经济环保等突出优点,迅速被国内市场所接受 ...

  • 有关水系统的4℃和5℃,你是不是分不清?

    筑龙暖通 公众号 来源:消防工程师共享服务 如有侵权,请联系删除 <消防给水及消火栓系统>GB50974-2014 5.2.5 高位消防水箱间应通风良好,不应结冰,当必须设置在严寒.寒冷等 ...

  • 看图识中央空调水系统

    筑龙电气 公众号 来源:暖通南社.奥特斯 如有侵权,请联系删除 机 电 工 程 联 盟 ◀