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相关概念视频

Pipe Flowrate Measurement01:28

Pipe Flowrate Measurement

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In pipe flow measurement, orifice, nozzle, and Venturi meters are commonly used to determine fluid flowrates by constricting the flow area, which increases fluid velocity and reduces pressure. This pressure difference, governed by Bernoulli's principle and adjusted for real-world conditions, is essential for calculating flowrate. Each meter type is suited to specific applications based on accuracy, efficiency, and compatibility with various flow conditions.
The orifice meter is a simple,...
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Measurement of Fluid Pressure01:16

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Fluid pressure is commonly measured using devices called manometers, which rely on liquid columns to indicate pressure differences. The height of a liquid column in a manometer reflects the pressure exerted by the fluid, providing a simple yet effective means of measurement. Different types of manometers serve specific purposes based on their configurations and the type of fluids involved.
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Air content measurement in concrete is critical for ensuring structural integrity and durability of concrete structures, especially in environments prone to severe weather conditions. Accurate air content analysis optimizes concrete's resistance to freeze-thaw cycles and enhances its workability and strength. Several methods are standardized under ASTM guidelines to measure the air content in fresh concrete, each suitable for different concrete types and conditions.
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Pipe Flowrate Measurement: Problem Solving01:28

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A spray tank system is engineered to uniformly distribute a pest-control liquid across plants by using a pressurized mechanism. The tank, pressurized to 150 kPa, holds the pesticide at a height of 0.80 meters. Liquid flows from the tank through a 1.9 meter pipe with a diameter of 0.015 meters, angled at 0.698 radians, ultimately reaching a 0.007 meter nozzle that sprays the pesticide. Accurate calculation of the system's flow rate is crucial to ensure uniform application, and this is...
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基于振动的智能传感器用于高流量尘埃测量.

Anibal Reñones1, Cristina Vega1, Mario de la Rosa1

  • 1CARTIF Technology Center, Av. Francisco Vallés, 4, 47151 Boecillo, Spain.

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概括

研究人员开发了一种原型,用振动分析来测量青混合物中的填料流量. 这项创新精确量化了工业环境中的细颗粒,提高了青生产质量.

关键词:
自动化自动化自动化自动化数字化转型数字化转型尘埃尘埃的尘埃,就是我们的尘埃.填充剂 填充剂 填充剂 填充剂工业设施 工业设施 工业设施工业4.0 工业4.0 工业4.0 工业4.0 是什么?创新 创新 创新 创新 创新工艺工业工业工业过程工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业工业传感器 传感器 传感器信号处理 信号处理 信号处理智能感应感应是一种智能感应.振动 振动 振动是一种振动.

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科学领域:

  • 土木工程 土木工程是指土木工程.
  • 材料科学 材料科学 材料科学
  • 机械工程 机械工程

背景情况:

  • 青混合物含有聚合物,添加剂和,其中微细的填充颗粒 (<0.063毫米) 对于混合物特性至关重要.
  • 在青混合物生产过程中,精确量化填料流量至关重要,但现有的传感器不适合恶劣的工业条件.

研究的目的:

  • 通过振动分析来测量填料流量的新型原型.
  • 为了解决需要一个可行的传感器来量化填充剂在青厂内的冷聚合物.
  • 模拟和验证原型的性能在现实的袋屋吸气条件下.

主要方法:

  • 开发了一种原型系统,该系统使用振动分析来测量填充剂流量.
  • 在实验室环境中模拟了工业袋屋的吸入过程.
  • 使用位于管道外的加速度计来检测由填充物颗粒撞击钢杆引起的振动.

主要成果:

  • 该原型准确地复制了工业袋屋中发现的填充剂流量和颗粒度条件.
  • 外部加速度计成功检测到管道内的填充液流量,即使吸入条件不同.
  • 结果表明,实验室发现有可能推断到现实世界的袋屋模型.

结论:

  • 开发的原型为在青生产中测量填料流量提供了可行的解决方案.
  • 振动分析方法在具有挑战性的工业条件下有效量化细颗粒.
  • 这些发现支持将这项技术应用于各种吸收过程,特别是那些涉及袋屋的过程.