PIV Measurement and Proper Orthogonal Decomposition Analysis of Annular Gap Flow of a Hydraulic Machine

Zhao, Yiming; Li, Yongye; Song, Xiaoteng

doi:10.3390/machines10080645

Cited by 10 publications

(13 citation statements)

References 30 publications

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“…Using the reduced-order method, the flow velocity field can be expressed by a few mode functions, and these mode functions can capture most of the flow turbulence characteristics and energy. The POD method process can be found in [21,28]. Here, we have only provided the velocity reduced-order model as:…”

Section: Reduced-order Methodsmentioning

confidence: 99%

“…The capsule moved through the measuring pipe, and the measuring devices measured the flow field around the motion capsule. The measuring device used particle image velocimetry (PIV), and the uncertainty analysis was conducted according to [21].…”

Section: Physical Experimental Systemmentioning

confidence: 99%

“…However, there is one problem with these time-averaged treatments of the pressure difference or friction stress. The pipe flow in an HCP system has a large Reynolds number, meaning that the flow around the capsule is fluctuating [21], and the wake vortex and the capsule motion speed show strongly transient characteristics. While the time-averaged treatment leads to steady results in terms of the fluid drag force and the capsule motion speed, there is a true necessity to model the fluid drag in terms of a transient view.…”

Section: Introductionmentioning

confidence: 99%

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Transient Model for the Hydrodynamic Force in a Hydraulic Capsule Pipeline Transport System

Zhao,

Li,

Sun

2023

Sustainability

Self Cite

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The hydraulic capsule pipeline (HCP) is an eco-friendly and sustainable pipeline transport option. The freight-carrying capsule is driven by hydraulic pipe flow. Fluid drag is generated by the principal dynamic force effect on the capsule, which could influence the capsule’s motion speed. To make the HCP more efficient, a transient model for the hydrodynamic force in an HCP was developed in this study. From a numerical simulation, the coherent vortex structures of fluctuating modes were observed, and the velocity iso-surfaces of the coherent vortex of the wake flow exhibited an annular trend in circumferential connection. Then, the hydrodynamic force was analyzed: the steady component and transient component were resolved, and the general trend in forces in terms of the transient components was that the maximum amplitude of forces reduced with an increase in mode order. Through short-term Fourier transform, the frequency components and their variations in terms of the entire time range could be acquired. The transient model in this study provided a perspective to build the connection between the flow structures and the hydrodynamic force. By the transient model, the transient component of hydrodynamic force can be explained as the fluctuation of coherent vortex structures.

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Section: Reduced-order Methodsmentioning

confidence: 99%

Section: Physical Experimental Systemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Transient Model for the Hydrodynamic Force in a Hydraulic Capsule Pipeline Transport System

Zhao,

Li,

Sun

2023

Sustainability

Self Cite

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“…In fluid flow, slot flow is a kind of flow widely existing in machinery, such as annular clearance between plunger and cylinder, shaft and bearing [5,6]. Due to different geometric shapes, the flow laws of slot flow are usually not universal.…”

Section: Introductionmentioning

confidence: 99%

Research on Prediction Model of Interlayer Leakage in Separate Injection Wells in Offshore Oilfields

Gao,

Chen,

Liu

et al. 2023

J. Phys.: Conf. Ser.

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In order to ensure effective layered water injection, it is of great significance to establish the functional relationship among the equivalent diameter of damage, leakage and pressure of sealing cylinder. In this paper, the experimental and numerical simulation experiments were carried out to study the relationship between gap flow rate, pressure drop and equivalent diameter of sealing cylinder under the conditions of uniform corrosion, fracture non-uniformity and random groove non-uniform distribution and scratches in different tubing, equivalent diameters and gap widths. Through a lot of data analysis, the relationship between the damage state and the leakage quantity is established and evaluated by physical simulation test. The research shows that the error between the established model function relation and the test data is no more than 10%. By simulating the damage condition of the shock sealing cylinder and quantitatively detecting the defect of the sealing cylinder, the model function relation can well predict the corresponding damage situation. Therefore, this model function can be used to solve sealing cylinder inspection problem, so as to judge the seal defect and leakage quantity which is independent of the experience of the person in charge of the site and able to use the data as a basis for judgment. This research provides a new technology for the effective prediction of the damage of sealing cylinder, and provides theoretical guidance for selecting matching sealing tools and realizing layered mining.

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“…Jia et al [17] and Zhang et al [18] studied the pressure drag of moving wheeled capsules. Zhao et al [19] used the proper orthogonal decomposition method to analyze the fluid stresses and flow-induced vibration characteristics of the flow field of a wheeled capsule, and they claimed that the forces on the capsule are decided by the flow characteristics. In fact, the threshold of motion of the capsule is initiated by the pipe flow making the drag a little larger than the maximum static friction of the capsule.…”

Section: Introductionmentioning

confidence: 99%

Wheeled Capsule Threshold of Motion at Different Locations in a Horizontal Bend Pipeline Based on Hydraulic Capsule Pipeline Transportation

Zhao

Yuan

et al. 2022

Water

Self Cite

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As the process before the transporting of the capsule in a hydraulic capsule pipeline system, the capsule’s threshold of motion process is often tested in the horizontal straight pipe. However, the result of the physical test in this work shows that the wheeled capsule more easily start-moves in a horizontal bent pipe. Thus, the numerical simulation and the theory analysis were used to study the wheeled capsule’s threshold of motion process in the bent pipe. The simulation results demonstrate that the velocity magnitude of the water flow was asymmetric between the inner part and the outer part of the section closing on the wheeled capsule. This was unlike the water flow of the section in the straight pipe. From this result, a new mechanical model was proposed that divides the wheeled capsule into two parts. The two parts of the mechanical model correspond to the two parts of the section. Then, the deduction has shown that the bolsters of the inner part of the wheeled capsule in the bent pipe endured lower maximum static friction than those in the straight pipe. The whole wheeled capsule was more unstable in the bent pipe than in the straight pipe because of the additional drag force induced by the centrifugal effect of the bent pipe’s water flow.

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PIV Measurement and Proper Orthogonal Decomposition Analysis of Annular Gap Flow of a Hydraulic Machine

Cited by 10 publications

References 30 publications

Transient Model for the Hydrodynamic Force in a Hydraulic Capsule Pipeline Transport System

Transient Model for the Hydrodynamic Force in a Hydraulic Capsule Pipeline Transport System

Research on Prediction Model of Interlayer Leakage in Separate Injection Wells in Offshore Oilfields

Wheeled Capsule Threshold of Motion at Different Locations in a Horizontal Bend Pipeline Based on Hydraulic Capsule Pipeline Transportation

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