Orynyak I.V., Borodii M.V., Batura A.S.

Slides:

Advertisements

Similar presentations

3 – Fracture of Materials

Advertisements

Fracture Mechanics Overview & Basics

Explosive joining of dissimilar metals: experiment and numerical modeling Anan’ev S.Yu., Andreev A.V., Deribas A.A., Yankovskiy B.D. Joint Institute for.

First Wall Heat Loads Mike Ulrickson November 15, 2014.

Batura A.S., Orynyak I.V. IPS NASU Pisarenko’ Institute for Problems of Strength, Kyiv, Ukraine National Academy of Sciences of Ukraine Pisarenko’ Institute.

Sensitivity Analysis In deterministic analysis, single fixed values (typically, mean values) of representative samples or strength parameters or slope.

Presented by Robert Hurlston UNTF Conference 2011 Characterisation of the Effect of Residual Stress on Brittle Fracture in Pressure Vessel Steel.

Engineering materials lecture #14

1 CONSTRAINT CORRECTED FRACTURE MECHANICS IN STRUCTURAL INTEGRITY ASSESSMENT Application to a failure of a steel bridge Anssi Laukkanen, Kim Wallin Safir.

Erdem Acar Sunil Kumar Richard J. Pippy Nam Ho Kim Raphael T. Haftka

Prediction of Load-Displacement Curve for Weld-Bonded Stainless Steel Using Finite Element Method Essam Al-Bahkali Jonny Herwan Department of Mechanical.

Design of an Aerospace Component

ENGINEERING PROJECT PROPOSAL MASTER OF ENGINEERING IN MECHANICAL ENGINEERING DAN FLAHIVE Analytical Method to Predict Primary Side Steam Generator Pressure.

Unit 3: Solid mechanics An Introduction to Mechanical Engineering: Part Two Solid mechanics Learning summary By the end of this chapter you should have.

Fracture of Divertor Structures Jake Blanchard ARIES Meeting April 2011.

Bearing Capacity Theory

ASPECTS OF MATERIALS FAILURE

Pressure Vessels.

Effect of finite size of component The SIF derived earlier is for cracks in an infinite body. However the finite size, geometry of the component, loading.

Orynyak I.V., Radchenko S.A. IPS NASU Pisarenko’ Institute for Problems of Strength, Kyiv, Ukraine National Academy of Sciences of Ukraine Pisarenko’ Institute.

Engineering Doctorate – Nuclear Materials Development of Advanced Defect Assessment Methods Involving Weld Residual Stresses If using an image in the.

Miskolc, Hungary Miskolc, Hungary April2006 April 2006 Numerical Modelling of Deformation and Fracture Processes of NPP Equipment Elements Моделирование.

FAILURE INVESTIGATION OF UNDERGROUND DISTANT HEATING PIPELINE

CRISM “Prometey”, Saint-Petersburg, Russia 1 ПОСТРОЕНИЕ РАСЧЕТНОЙ ТЕМПЕРАТУРНОЙ ЗАВИСИМОСТИ ВЯЗКОСТИ РАЗРУШЕНИЯ КОРПУСНЫХ РЕАКТОРНЫХ МАТЕРИАЛОВ: ОБЩИЕ.

Professor V.I. Makhnenko, scientist A.S. Milenin E.O. Paton Electric Welding Institute of National Academy of Sciences of Ukraine 1 Remaining Time Assessment.

Orynyak I.V., Borodii M.V., Batura A.S. IPS NASU Pisarenko’ Institute for Problems of Strength, Kyiv, Ukraine National Academy of Sciences of Ukraine Pisarenko’

API 6HP Process1 API 6HP Example Analysis Project API E&P Standards Conference Applications of Standards Research, 24 June 2008.

Application of the Direct Optimized Probabilistic Calculation Martin Krejsa Department of Structural Mechanics Faculty of Civil Engineering VSB - Technical.

G.S.Pisarenko Institute for Problems of strength National Academy of Sciences, Ukraine G. V. Stepanov Decrease of residual stresses in structure elements.

High strength materials are being increasingly used in designing critical components to save weight or meet difficult service conditions. Unfortunately.

1st Ukrainian-Hungarian Seminar “Safety, Reliability and Risk of Engineering Plants and Components”, Miskolc April 2006 Intergranular stress corrosion.

AMML Effect of rise, peak and fall characteristics of CZM in predicting fracture processes.

1 Optimization of Reinforcement Methods for Non-round Pressure Vessels By Shawn McMahon A Presentation of a Thesis In Partial Fulfillment of the Requirements.

IPS NASU DYNAMICAL ANALYSIS AND ALLOWABLE VIBRATION DETERMINATION FOR THE PIPING SYSTEMS. G.S. Pisarenko Institute for Problems of Strength of National.

Preparing for the Hydrogen Economy by Using the Existing Natural Gas System as a Catalyst // Project Contract No.: SES6/CT/2004/ NATURALHY is an.

PROBLEMS OF LIFETIME ASSESSMENT OF WATER-STEAM CIRCUIT ELEMENTS OF WATER-STEAM CIRCUIT ELEMENTS OF POWER UNITS OF POWER UNITS I. M. DMYTRAKH and V. V.

THE MODELING OF THE LIMIT STATE OF DUCTILE THICK-WALLED PIPES WITH AXIAL SURFACE DEFECTS Orynyak I.V., Ageyev S.M. G.S. Pisarenko Institute for Problems.

2 nd Hungarian-Ukrainian Joint Conference on SAFETY-RELIABILITY AND RISK OF ENGINEERING PLANTS AND COMPONENTS ASSESSMENT OF SUB-CLAD FLAWS, J-INTEGRAL.

Chapter 7 Fatigue Failure Resulting from Variable Loading

Frame with Cutout Random Load Fatigue. Background and Motivation A thin frame with a cutout has been identified as the critical component in a structure.

LIMIT LOAD CALCULATION MODEL OF DUCTILE FAILURE OF DEFECTIVE PIPE AND PRESSURE VESSEL Orynyak I.V. G.S. Pisarenko Institute for Problems of Strength, National.

I. M. DMYTRAKH and V. V. PANASYUK Karpenko Physico-Mechanical Institute, National Academy of Sciences of Ukraine 5 Naukova Street, Lviv, 79601, UKRAINE.

1 Effects of Error, Variability, Testing and Safety Factors on Aircraft Safety Erdem Acar, Amit Kale and Raphael T. Haftka

Reactor pressure vessels of WWER (materials and technology) Janovec, J

Bay Zoltán Foundation for Applied Reseach Institute for Logistics and Production Systems BAY-LOGI Assessment of crack like defect in dissimilar welded.

CRACK GROWTH IN NOTCHED SPECIMEN UNDER REPETITIVE IMPACTS Presented By: Gayan Abeygunawardane-Arachchige Gayan Abeygunawardane-Arachchige Prof. Vadim Silberschmidt.

Thermal screen of the cryostat Presented by Evgeny Koshurnikov, GSI, Darmstadt September 8, 2015 Joint Institute for Nuclear Research (Dubna)

NEW CHARACTERISTICS OF METAL DEGRADATION IN THE COURSE OF OPERATION V.P. Shvets G.S. Pisarenko Institute for Problems of Strength National Academy of Sciences.

1 ROAD & BRIDGE RESEARCH INSTITUTE WARSAW Juliusz Cieśla ASSESSSMENT OF PRESTRESSING FORCE IN PRESTRESSED CONCRETE BRIDGE SPANS.

1 Electrochemical Machining (ECM). 2 Electrochemical Machining Uses an electrolyte and electrical current to ionize and remove metal atoms Can machine.

REACTOR PRESSURE VESSEL

SECTION 7 DESIGN OF COMPRESSION MEMBERS

Kalol Institute Of Technical & Research Center

DEPARTMENT OF MECHANICAL AND MANUFACTURING ENGINEERING

The Thick Walled Cylinder

Date of download: 10/21/2017 Copyright © ASME. All rights reserved.

Optimal design of composite pressure vessel by using genetic algorithm

Date of download: 11/4/2017 Copyright © ASME. All rights reserved.

Date of download: 11/13/2017 Copyright © ASME. All rights reserved.

The Thick Walled Cylinder

Methods to Maximize Design Life

Choosing of materials Higher Product Design.

Date of download: 12/28/2017 Copyright © ASME. All rights reserved.

Date of download: 1/2/2018 Copyright © ASME. All rights reserved.

Thermal analysis Friction brakes are required to transform large amounts of kinetic energy into heat over very short time periods and in the process they.

Tutorial Irradiation Embrittlement and Life Management of RPVs

Mechanics of Materials Lab

Mechanical Properties: 2

Simple Stresses & Strain

Choosing of materials Higher Product Design.

Presentation transcript:

Orynyak I.V., Borodii M.V., Batura A.S. IPS NASU SOFTWARE FOR ASSESSMENT OF BRITTLE FRACTURE OF THE NPP REACTOR PRESSURE VESSEL USING THE FRACTURE MECHANICS METHODOLOGY Orynyak I.V., Borodii M.V., Batura A.S. Pisarenko’ Institute for Problems of Strength , Kyiv, Ukraine National Academy of Sciences of Ukraine

IPS NASU Software “REACTOR” This program is intended for calculation of reactor pressure vessel residual life and safety margin with respect to brittle fracture. Residual life is calculated deterministically and probabilistically (MASTER CURVE approach) for various points of crack front

IPS NASU Software advantages The sizes of stress and temperature fields' aren't bounded Number of time moments is bounded only by the computer memory size Cladding is taken into account Welding seam and heat-affected area are taken into account Deterioration is taken into account not only as shift of the material fracture toughness function but also as its inclination Original feature of the software is using of the author variant of the weight function method. It allows to set loading on the crack surface in the form of table.

IPS NASU Report sections Theoretical background and verification of the SIF calculation methods. Kinetics of the crack growth by fatigue or stress-corrosion mechanism. Software description and residual life calculation of the NPP pressure vessel using fracture mechanics methods

SIF calculation by Point Weight Function Method IPS NASU SIF calculation by Point Weight Function Method s x Q’ !!! The contribution in SIF 1/800 area nearby Q’ point correspondent to 1/4 value of SIF Q’- point on the front; - value SIF; -weight function; - loading; - crack surface; Q – load application point

IPS NASU We search weight function in the form - asymptotic WF (elliptic crack in infinite body) - correction coefficient, basic solution is used

Using our Point Weight Function Method in engineering applications IPS NASU Using our Point Weight Function Method in engineering applications Software for fracture design of the complex turbine engine component (Southwest Research Institute, San Antonio, USA, 2004) Our approach is used completely

Using our Point Weight Function Method in engineering applications IPS NASU Using our Point Weight Function Method in engineering applications 2. Modeling of elliptical crack in a infinite body and in a pressured cylinder by a hybrid weight function approach (France, Int. J. Pressure Vessel and Piping. 2005) Our approach to take for a basis

SIF along crack front (angle), homogeneous loading IPS NASU Check of the PWFM accuracy for semi-elliptic cracks SIF along crack front (angle), homogeneous loading 90

IPS NASU

IPS NASU

Dependence SIF from ratio a/l IPS NASU Dependence SIF from ratio a/l

Dependence SIF from ratio a/l IPS NASU Dependence SIF from ratio a/l

2. Kinetics of the crack growth by fatigue or IPS NASU 2. Kinetics of the crack growth by fatigue or stress-corrosion mechanism 1. Fatigue 2. Stress-corrosion

Complex damage IPS NASU where C1, C2 , v1 , v2 , - material constants t, - time, N – loading cycles, H – wall thickness T – unit time, k – number of cycles in unit of time

Using stable form crack growth IPS NASU Using stable form crack growth

IPS NASU 3. Residual Life calculation of the NPP pressure vessel using fracture mechanics methods Input Data 1) Stress field for time Table arbitrary size

IPS NASU Input Data 2) Temperature field for time Table arbitrary size

Input Data IPS NASU 3) Crack types a) Axial with weld seam weld seam heat-affected zone base material cladding crack b) circumferential base material cladding crack

4) The basic material characteristics IPS NASU 4) The basic material characteristics 1. Arctangents 2. Exponent 3. User (pointed) function Common shape of the crack growth resistance function is for user function A takes from coordinates of first point

IPS NASU 5) Shift and inclination conceptions 1. Shift 2. Shift + Inclination

6) Dependence of shift on radiation IPS NASU 6) Dependence of shift on radiation a)Analytical form b)Table form

IPS NASU Results Scenario – Break of the Steam Generator Collector WWER-1000 operated at full power It is given : - stress field, - temperature field, = 1000, 2000, 2800, 3000, 3160, 3600, 4000 sec - time points Axial crack. Half-length l - 40 мм., depth a - 50 мм.

IPS NASU a) Dependences of the calculated and critical SIF from temperature for time = 3000 sec SIF for base material --//-- for welding seam Critical SIF for base material --//-- for heat-affected area

IPS NASU b) History of the dependences calculated SIF from temperature for some points and all times intervals and critical SIF T history for base material --//-- for welding seam critical SIF for base material --//-- for heat-affected area

c) Table of the calculated temperature margin IPS NASU c) Table of the calculated temperature margin for all points of crack front and time points fields for chosen history points minimal margin margin for time points

d) Figure of the calculated margin IPS NASU d) Figure of the calculated margin calculated temperature margin shift of the temperature by user table shift of the temperature by analytical model

Results for other crack geometries IPS NASU Results for other crack geometries New geometry for axial crack Calculated temperature margin Half length l - 60мм Depth a - 40 мм

IPS NASU New geometry for axial crack Half length l - 40мм Calculated temperature margin Half length l - 40мм Depth a - 60 мм

IPS NASU New geometry for circumferential crack Half length l - 60мм calculated temperature margin Half length l - 60мм Depth a - 30 мм

Implementation MASTER CURVE Conception IPS NASU Implementation MASTER CURVE Conception 1. Failure probability calculation for structural element 2. Failure probability calculation for crack 3. Calculation parameters Pf = 63,2% Кmin = 20 В0 = 25 мм b = 4 4. In addition Кmin , K0(Т), В0, b - arbitrarily

Result for main scenario IPS NASU Result for main scenario Time point t4 = 3000 sec - the most dangerous time step Axial crack half length l - 40 мм., depth a - 50 мм. For time DT =0 failure probability equal 1.07*10-05 SIF dependences on angle

IPS NASU Dependences of logarithm probability on DT

IPS NASU Probability density for DT = 50

IPS NASU CONCLUSION 1. Efficient method of stress intensity factor (SIF) calculation is developed. 2. The computer software which reflected all modern requirements for brittle strength analysis of Reactor Pressure Vessel is created. 3. The program application were demonstrated by prediction residual life and temperature margins under modeling of the incident scenario.