The black-water regulating valve is very easy to be damaged due to the erosion of the key components, such as valve spool and valve seat. This work presents the failure analysis of the spool and seat of regulating valve in the black-water treatment system. Scanning electron microscopy and X-ray energy-dispersive spectrometer were used to detect the morphology and chemical compositions of failure valve samples. The computational fluid dynamics method was also adopted to simulate the medium flow characteristics in black-water regulating valve. The results show that most erosion areas of the valve occur at the spool-seat throttle zone. The erosion profile is mainly manifested in plastic deformation pits, cutting abrasions, furrows, pinhole pits and impact pits. The particles and cavitation bubbles move toward the throttle zone driven by black-water medium, causing particles impact and bubbles collapse. The particle flow velocity in the throttle zone of the valve is between 50 and 175 m/s, while the maximum velocity can reach 175 m/s. The valve suffered severe particle erosion and cavitation erosion under the particle impact and bubble collapse, finally resulting in its failure.
ZhengZOuGYiY, et al.A combined numerical-experiment investigation on the failure of a pressure relief valve in coal liquefaction. Eng Fail Anal2016; 60: 326–340.
2.
ZhengKHuHChenF, et al.Failure analysis of the blackwater regulating valve in the coal chemical industry. Eng Fail Anal2021; 125: 105442.
3.
OuGOuyangPZhengZ, et al.Investigation on failure process and structural improvement of a high-pressure coal water slurry valve. Eng Fail Anal2019; 96: 1–17.
4.
Laguna-CamachoJRMarquina-ChávezAMendez-MendezJV, et al.Solid particle erosion of AISI 304, 316 and 420 stainless steels. Wear2013; 301: 398–405.
5.
SahaGCKhanTIZhangGA. Erosion–corrosion resistance of microcrystalline and near-nanocrystalline WC–17Co high velocity oxy-fuel thermal spray coatings. Corros Sci2011; 53: 2106–2114.
6.
MaekaiIAHarmainGAZehab-ud-Din, et al.Resistance to slurry erosion by WC-10Co-4Cr and Cr3C2-25(Ni20Cr) coatings deposited by HVOF stainless steel F6NM. Int J Refract Met Hard Mater2022; 105: 105830.
7.
WuYHongSZhangJ, et al.Microstructure and cavitation erosion behavior of WC-Co-Cr coating on 1Cr18Ni9Ti stainless steel by HVOF thermal spraying. Int J Refract Met Hard Mater2012; 32: 21–26.
8.
ZhengZOuGYeH, et al.Investigation on failure process and structural optimization of a high pressure letdown valve. Eng Fail Anal2016; 66: 223–239.
9.
Assis SeverianoJSilvaASSussushiEM, et al.Corrosion damages of flow regulation valves for water injection in oil fields. Eng Fail Anal2019; 96: 362–373.
10.
LongYWuGFuAQ, et al.Failure analysis of the 13Cr valve cage of tubing pump used in an oilfield. Eng Fail Anal2018; 93: 330–339.
11.
YiJHuHZhengY, et al.Experimental and computational failure analysis of a high pressure regulating valve in a chemical plant. Eng Fail Anal2016; 70: 188–199.
12.
LinZYuHYuT, et al.Numerical study of solid-liquid two-phase flow and erosion in ball valves with different openings. Adv Powder Technol2022; 33: 103542.
13.
WenQLiuYChenZ, et al.Numerical simulation and experimental validation of flow characteristics for a butterfly check valve in small modular reactor. Nucl Eng Des2022; 391: 111732.
14.
YuanCSongJZhuL, et al.Numerical investigation on cavitating jet inside a poppet valve with special emphasis on cavitation-vortex interaction. Int J Heat Mass Tran2019; 141: 1009–1024.
15.
LuLXieSYinY, et al.Experimental and numerical analysis on the surge instability characteristics of the vortex flow produced large vapor cavity in u-shape notch spool valve. Int J Heat Mass Tran2020; 146: 118882.
16.
HanMLiuYWuD, et al.A numerical investigation in characteristics of flow force under cavitation state inside the water hydraulic poppet valves. Int J Heat Mass Tran2017; 111: 1–16.
17.
Cuamatzi-MeléndezRHernandez RojoMVázquez-HernándezA, et al.Predicting erosion in wet gas pipelines/ elbows by mathematical formulations and computational fluid dynamics modeling. P I Mech Eng J-J Eng2018; 232: 1240–1260.
18.
LiuJLiuZWuJ, et al.Visualization experiment and numerical calculation of the cavitation evolution inside the injector ball valve. Fuel2022; 329: 125500.
19.
YinYYuanJGuoS. Numerical study of solid particle erosion in hydraulic spool valves. Wear2017; 392-393: 174–189.
20.
ChenMLuHJinY, et al.Experimental and numerical study on gas-solid two-phase flow through regulating valve of pulverized coal flow. Chem Eng Res Des2020; 155: 1–11.
21.
LiuBZhaoJQianJ. Numerical analysis of cavitation erosion and particle erosion in butterfly valve. Eng Fail Anal2017; 80: 312–324.
22.
ShanBChenPQiaoX, et al.Failure analysis of pipeline in coal gasification black water treatment system based on experiment and CFD simulation. Surf Technol2019; 48: 247–256. in Chinese.
23.
ChenPCuiBLiJ, et al.Particle erosion under multiphase bubble flow in horizontal-vertical-upward elbows. Powder Technol2022; 397: 117002.
24.
SunJGeXZhouY, et al.Research on synergistic erosion by cavitation and sediment: a review. Ultrason Sonochem2023; 95: 106399.
25.
KrellaAKMarciszJBuszkoMH, et al.The degradation mechanisms of a nanobainitic steel under cavitation erosion conditions. Wear2024; 538-539: 205208.
26.
YanDWangJLiuF. Inhibition of the ultrasonic microjet-pits on the carbon steel in the particles-water mixtures. AIP Adv2015; 5: 077159.
27.
ZhaoLWuJJinZ, et al.Cavitation effect on flow resistance of sleeve regulating valve. Flow Meas Instrum2022; 88: 102259.
28.
PangYLiagLTangY, et al.Numerical analysis and experimental investigation of combined erosion of cavitation and sandy water erosion. P I Mech Eng J-J Eng2016; 230: 31–39.
29.
MelentievR. Physical theories of solid particle erosion and abrasive jet wear. J Manuf Process2023; 106: 422–452.
30.
HuZQuAZhongZ, et al.Study on pulverized coal gasification using waste heat from high temperature blast furnace slag particles. Int J Hydrogen Energ2021; 46: 26848–26860.
31.
CuiBChenPZhaoY. Numerical simulation of particle erosion in the vertical-upward-horizontal elbow under multiphase bubble flow. Powder Technol2022; 404: 117437.
32.
MaGLinZZhuZ. Investigation of transient gas-solid flow characteristics and particle erosion in a square gate valve. Eng Fail Anal2020; 118: 104827.
33.
JinHZhengZOuG, et al.Failure analysis of a high pressure differential regulating valve in coal liquefaction. Eng Fail Anal2015; 55: 115–130.
34.
ANSYS, Inc. Ansys fluent theory guide. Caonburg, PA: ANSYS, Inc., 2016.
35.
SinghalAKAthavaleMMLiH, et al.Mathematical basis and validation of the full cavitation model. J Fluid Eng2002; 124: 617–624.
36.
ZwartPJGerberAGBelamriT. A two-phase flow model for predicting cavitation dynamics. Int Conf Multiphas Flow2004; 152: 152.
37.
SchnerrGHSauerJ. Physical and numerical modeling of unsteady cavitation dynamics. Proceedings of 4th international Conference on Multiphase Flow. New Orleans, USA, 2001: 1–8.
38.
XuFLiuYChenM, et al.Continuous motion of particles attached to cavitation bubbles. Ultrason Sonochem2024; 106: 106888.
39.
TanKLYeoSH. Velocity estimation of micro-particles driven by cavitation bubble collapses through controlled erosion experiments. Int J Multiphas Flow2020; 127: 103271.
40.
ReuterFDeiterCOhlC. Cavitation erosion by shockwave self-focusing of a single bubble. Ultrason Sonochem2022; 90: 106131.
