MC-PIG管道检测仪表速度控制的形态自适应

Sujet Phodapol, Tachadol Suthisomboon, P. Kosanunt, Ravipas Vongasemjit, P. Janbanjong, P. Manoonpong
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引用次数: 0

摘要

被动和主动混合式管道检测仪表(pig)已被用于管道内检测。被动PIG无法控制其速度,而混合版本可以通过使用专门设计并嵌入PIG的集成阀来实现这一目标。本研究提出了一种通用的新方法来适应猪的速度(称为MC-PIG),通过引入一个通用的、模块化的、可控的外部阀单元附加组件,以最小的变化连接到现有的传统(被动)猪。MC-PIG方法是基于形态计算和闭环控制的原理。它是通过调节/计算PIG的形态来实现的(例如,一个模块化的旋转阀单元附加组件),以控制旁通流量。调节阀角度的调整可以影响通过PIG的流量,从而产生调速能力。采用计算流体力学(CFD)数值模拟方法,对采用比例积分(PI)控制的阀单元模拟清管器在不同管内压力条件下的速度进行了研究和分析。我们在三种管道尺寸(直径为16″、18″和22″)的不同操作条件下进行了仿真实验,以证明具有模块化阀门单元附加组件和PI控制的PIG的速度适应性。结果表明,PIG可以有效地进行实时自适应(即调整其阀门角度)以保持所需的速度。阀门设计可从5度(阀门关闭,导致运动速度高)调节到最大45度(阀门全开,导致运动速度低)。在16″管道中,在4.38 m/s(管内流体速度)、2500 kPa(工作压力)、62℃(工作温度)条件下,PIG的速度可在0.59 ~ 3.88 m/s范围内调节。最后,MC-PIG方法在6″管道中使用3d打印原型进行验证。通过调查,我们发现有两个因素影响速度适应;清管器与管道的压降系数和摩擦力。综上所述,仿真结果与样机结果接近,误差在可接受范围内。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Morphological Adaptation for Speed Control of Pipeline Inspection Gauges MC-PIG
Passive and active hybrid pipeline inspection gauges (PIGs) have been used for in-pipe inspection. While a passive PIG cannot control its speed, the hybrid version can achieve this by using an integrated valve specifically designed and embedded in the PIG. This study proposes a generic new method for speed adaptation in PIGs (called MC-PIG) by introducing a generic, modular, controllable, external valve unit add-on for attaching to existing conventional (passive) PIGs with minimal change. The MC-PIG method is based on the principle of morphological computation with closed-loop control. It is achieved by regulating/computing the PIG's morphology (i.e., a modular rotary valve unit add-on) to control bypass flow. Adjustment of the valve angle can affect the flow rate passing through the PIG, resulting in speed regulation ability. We use numerical simulation with computational fluid dynamics (CFD) to investigate and analyze the speed of a simulated PIG with the valve unit adjusted by proportional-integral (PI) control under various in-pipe pressure conditions. Our simulation experiments are performed under different operating conditions in three pipe sizes (16″, 18″, and 22″ in diameter) to manifest the speed adaptation of the PIG with the modular valve unit add-on and PI control. Our results show that the PIG can effectively perform real-time adaptation (i.e., adjusting its valve angle) to maintain the desired speed. The valve design can be adjusted from 5 degrees (closed valve, resulting in high moving speed) to a maximum of 45 degrees (fully open valve, resulting in low moving speed). The speed of the PIG can be regulated from 0.59 m/s to 3.88 m/s in a 16″ pipe at 4.38 m/s (in-pipe fluid velocity), 2500 kPa (operating pressure), and 62 °C (operating temperature). Finally, the MC-PIG method is validated using a 3D-printed prototype in a 6″ pipe. Through the investigation, we observed that two factors influence speed adaptation; the pressure drop coefficient and friction of the PIG and pipeline. In conclusion, the results from the simulation and prototype show close characteristics with an acceptable error.
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