Solid Particle Erosion Models and their Application to Predict Wear in Pelton Turbine Injector

Bajracharya, Tri Ratna; Shrestha, Rajendra; Timilsina, Ashesh Babu

doi:10.3126/jie.v15i3.32221

Cited by 6 publications

(2 citation statements)

References 26 publications

(45 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Erosion models are deduced by either theoretically by energy balance for particle-target wall collision or experimentally by formulating empirical relations or by dimensional analysis (Bajracharya et al, 2020). The first proposed erosion model to evaluate progressive loss of material was by Finnie in 1960(Finnie, 1960.…”

Section: Erosionmentioning

confidence: 99%

Numerical modelling of the sand particle flow in pelton turbine injector

Bajracharya

Shrestha

Timilsina

2021

J. Eng. Iss. Solut.

Self Cite

View full text Add to dashboard Cite

Pelton turbine is commonly employed high head impulse type turbine. Pelton turbine injector is an integrated part of the Pelton turbine machine which serves the purpose of converting entire pressure energy of water to kinetic energy and also regulates the water flowrate, with partial opening hence governing the power production. Severe erosion in Pelton turbine injector is reported from field setting research studies. Since the jet is atmospheric pressure jet, there is few chances of occurrence of cavitation hence it can be understood that impact of sand particles is the major cause of erosion. Furthermore, with turbine operating in partial flow condition, more erosion is reported in the needle of injector. For a long spear type injector, this study explores the cause of erosion by modeling the motion of the sand particle flow in steady state jet. For numerical modeling of the flow, the realizable k-epsilon model is used and for modeling the particle flow, the Discrete Phase Model (DPM) is used. Three different operating condition of the injector is considered and 77000 particles were injected to the flow domain. It is observed from the numerical simulations that the more sand particle hits the nozzle-needle surface with partial opening of the injector.

show abstract

Section: Erosionmentioning

confidence: 99%

Numerical modelling of the sand particle flow in pelton turbine injector

Bajracharya

Shrestha

Timilsina

2021

J. Eng. Iss. Solut.

Self Cite

View full text Add to dashboard Cite

show abstract

“…Multiple pieces of literature have reviewed Pelton turbine erosion with different conclusive results [3,4,17,18,[20][21][22]25]. Figure 1 shows typical erosion areas in a Pelton turbine.…”

Section: Introductionmentioning

confidence: 99%

Modelling of Hydroabrasive Erosion in Pelton Turbine Injector

Bajracharya

Shrestha

Sapkota

et al. 2022

International Journal of Rotating Machinery

Self Cite

View full text Add to dashboard Cite

Sand particle-led erosion in the turbine parts of hydropower projects (excluding storage type projects) based on Himalaya-originated Rivers is one of the key operational challenges for concerned hydropower stations. Researchers have made multiple attempts to understand the nature of erosion and its combating technique by using numerical and experimental modelling techniques. This study relates to numerical and experimental modelling of sand particle-led erosion in the injector of the most preferred high head turbine, i.e., the Pelton turbine, followed by a comparative analysis of both techniques. This article attempts to compare erosion qualitatively and quantitatively, thus adding to the current state of the art of turbine erosion modelling. The results direct that the erosion-prone area is the needle seat in the nozzle and the region between the needle tip and nozzle exit in the needle, similar to findings reported by authors performing field setting research. The innovative aspect of the study is that by mapping the shape of the initial and eroded needle, mass lost in the erosion-prone area (as indicated by numerical erosion modelling) is calculated and compared against numerical modelling results. With the Oka erosion model employed for numerical modelling, the error in computation is about 31%. The nature of erosion in a partially open injector reveals that erosion in the needle increases with the nozzle’s partial opening. Nozzle erosion spreads away from the needle seat to the whole nozzle body. As commonly understood, the erosion of turbine parts gives rise to mechanical vibrations (especially in rotating parts) and energy loss. Numerical modelling results of injector erosion’s effect on jet energy are also presented. With uniformly spread erosion of 0.5 mm in both the needle and nozzle, loss in jet energy is 5.63%.

show abstract