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Utilizing Computational Flow Modeling for Enhanced Combined Sewer Overflow System Design
技术
- 传感器 - 液体检测传感器
- 传感器 - 电表
适用行业
- 可再生能源
- 公用事业
适用功能
- 采购
- 产品研发
用例
- 智慧城市供水管理
- 泄漏与洪水监测
服务
- 系统集成
挑战
美国东北部的城市正在探索安装新型组合式下水道溢流 (CSO) 处理装置,采用先进的水力涡流分离器 (HDVS) 和自清洁筛网,例如 Hydro International 生产的装置。传统上,HDVS 被用作高速固液分离器;直到最近,它们作为接触室对 CSO 进行高效消毒的潜在用途才得以实现。使用混合盆对 CSO 进行传统消毒,需要大约 15 分钟的接触时间。然而,一份报告表明,这些系统只需三分钟的接触时间即可提供有效的高效率消毒。虽然更短的联系时间可以为市政当局节省高达 50% 的总体项目成本,但监管机构仍然期望根据旧系统的性能要求看到更长的联系时间。 Hydro International 面临的挑战是了解较短接触时间的基础,并验证高效消毒是较长传统消毒方法的可接受替代方案。
关于客户
Hydro International 是一家提供创新、环境可持续产品和服务的全球供应商,这些产品和服务满足不断变化的雨水、合流下水道溢流和废水控制和处理法规。该公司的产品系列为控制数量和改善水质提供了经济的解决方案。他们致力于为客户提供更便宜、高性能的解决方案,以满足合并下水道溢出的要求。
解决方案
Hydro International 与卡迪夫大学合作,使用 ANSYS Fluent 流动建模软件开发 Storm King HDVS 的计算模型。他们通过与全面实验室实验相对应的一系列流速运行模型,并使用结果计算接触时间并将这些值与实验结果进行比较。通过将物理实验与计算程序相结合,Hydro International 成功证明了 Storm King 系统中模拟的停留时间和消毒杀灭率与全面的实验室观察结果一致。他们深入了解了观察到的消毒效果的基础,并证实消毒杀灭率相当于(或在某些情况下优于)传统水箱的杀灭率。这些结果用于支持监管机构放宽 CSO 消毒 15 分钟接触时间规定的提案。
运营影响
数量效益
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