میزان شباهت دو سیگنال به وسیله همبستگی متقابل آن دو تعریف میشود که بهصورت تابعی از تاخیرزمانی هست که به یکی از آنها اعمال میشود. یعنی بهازای تاخیرزمانی که به یکی از توابع داده میشود، میزان تطابق دو سیگنال و نهایتا انتگرال زیر رابطه همبستگی متقابل، محاسبه میشود. شکل زیر نشان دهنده همبستگی متقابل و خودهمبستگی دو سیگنال f و g است.
محتوای ارایه شده شامل گزارش کار کامل به همراه کد متلب مربوطه می باشد.
جهت خرید شبیه سازی همبستگی متقابل و خودی دو سیگنال با استفاده از نرم افزار متلب ، به مبلغ استثنایی فقط 14700 تومان و دانلود آن بر لینک پرداخت و دانلود در پنجره زیر کلیک نمایید.
!!!تخفیف ویژه!!!
با خرید حداقل 20000 (بیست هزارتومان) از محصولات فروشگاه اینترنتی گنجینه دانشجو برای شما کد تخفیف ارسال خواهد شد. با داشتن این کد از این پس می توانید سایر محصولات فروشگاه را با 20% تخفیف خریداری نمایید. کافی است پس از انجام 20000 تومان خرید موفق عبارت درخواست کد تخفیف و ایمیل که موقع خرید ثبت نمودید را به ایمیل ganjdaneshjo@gmail.com ارسال نمایید. همکاران ما پس از بررسی درخواست، کد تخفیف را برای شما ارسال خواهند نمود.
این فایل شامل کد متلب توزیع دما می باشد که به زبان بسیار ساده نوشته شده و براحتی قابل آنالیز می باشد. همچنین شما میتوانید با یکبار خواندن کد معادله مورد نظر خودتان را در آن جایگذاری کنید. بهمراه توضیحات خط به خط در کد ...!خروجی بصورت راه حل و نمودار و پاسخ مییاشد.
Companion Guide to the ASME Boiler & Pressure Vessel Code THIRD EDITION VOLUME 1
Criteria and Commentary on Select Aspects of the
Boiler & Pressure Vessel and Piping Codes
Publisher: ASMEPublish Date: 2009Pages: 887Language: English
ناشر : موسسه ASME
سال انتشار : 2009
فرمت کتاب: PDF
سرفصلهای آموزشی کتاب:
Dedication to the First Edition
Robert E. Nickell and William E. Cooper
Acknowledgements (to the First Edition)
K. R. Rao and Robert E. Nickell
Acknowledgements (to the Second Edition)
K. R. Rao
Acknowledgements (to the Third Edition)
K. R. Rao
Contributor Biographies
Preface to the First Edition
Preface to the Second Edition
Preface to the Third Edition
Introduction
Organization and Operation of the ASME
Boiler and Pressure Vessel Committee
PART 1: POWER BOILERS — SECTIONS I & VII
OF B&PV CODE
CHAPTER 1 Introduction to Power Boilers
Lloyd W.Yoder and John R. MacKay
1.1 Introduction
1.2 History and Philosophy of Section I
1.3 The Organization of Section I
1.4 Scope of Section I: Pressure Limits and
Exclusions
1.5 Distinction Between Boiler Proper Piping and
Boiler External Piping
1.6 How and Where Section I is Enforced and
Effective Dates
1.7 Fundamentals of Section I Construction
1.8 References
1.9 Design Exercises
CHAPTER 2 Section VII—Recommended
Guidelines for the Care of Power Boilers
Edmund W.K. Chang and Geoffrey M. Halley
2.1 Introduction
2.2 The Preamble
2.3 Fundamentals—Subsection C1
2.4 Boiler Operation—Subsection C2
2.5 Boiler Auxiliaries—Subsection C3
2.6 Appurtenances—Subsection C4
2.7 Instrumentation, Controls, and Interlocks—
Subsection C5
2.8 Inspection—Subsection C6
2.9 Repairs, Alterations, and Maintenance—
Subsection C7
2.10 Control of Internal Chemical Conditions—
Subsection C8
2.11 Preventing Boiler Failures—Subsection C9
2.12 Final Notes
2.13 References
PART 2: SECTION II OF B&PV CODE
CHAPTER 3 PART 2, Section II—Materials and
Specifications
Domenic A. Canonico, Elmar Upitis, Richard A. Moen,
Dennis Rahoi, and Marvin L. Carpenter
3.1 History of Materials in the ASME Boiler and
Pressure Vessel Code
3.2 Basis for Acceptance of Materials for Code
Construction— Section II, Part A: Ferrous
Material Specifications
3.3 Basis for Acceptance of Materials for Code
Construction—Section II, Part B: Nonferrous
Material Specifications
3.4 Section II, Part C: Specification for Welding
Rods, Electrodes, and Filler Metals
3.5 Basis for Acceptance of Materials for Code
Construction— Section II, Part D: Properties
PART 3: SECTION III — RULES FOR CONTRUCTION
OF NUCLEAR POWER PLANT COMPONENTS
CHAPTER 4 A commentary for understanding and
Applying the Principles of the ASME Boiler and
Pressure Vessel Code
Roger F. Reedy
4.1 Introduction
4.2 Design Factors Used in the ASME Code
4.3 Design Specifications and Design Reports
4.4 Section III Versus Section VIII
4.5 Design Life and Commutative-Usage Factors
4.6 Service-Level Loadings
4.7 Seismic Evaluations
4.8 Engineers, Design, and Computers
4.9 Containment Vessels
4.10 Tolerances, Significant Figures, and Nominal
Dimensions
4.11 Corrosion and Erosion
4.12 Forming Operations
4.13 Post–Weld Heat Treatment
4.14 Nondestructive Examination
4.15 Hydrostatic Test
4.16 Quality Assurance
4.17 Design Loadings and Stresses Compared to
Actual Conditions
4.18 Post-Construction Postulated Loadings and
Stresses
4.19 Maintenance of Design Margins
4.20 Thermal Relief Devices
4.21 Code Cases
4.22 ASME Interpretations
4.23 Code Simplification
4.24 Future Considerations for Cyclic Service
4.25 New ASME Code–2007 Edition of Section VIII,
Division 2
4.26 Summary
4.27 References
CHAPTER 5 Subsection NCA—General
Requirements for Division 1 and Division 2
Richard W. Swayne
5.1 Introduction
5.2 Article NCA-1000 Scope of Section III
5.3 Article NCA-2000 Classification of Components
and Supports
5.4 Article NCA-3000 Responsibilities and Duties
5.5 Article NCA-4000 Quality Assurance
5.6 Article NCA-5000 Authorized Inspection
5.7 Article NCA-8000 Certificates, Nameplates,
Code Symbol Stamping, and Data Reports
5.8 Article NCA-9000 Glossary
CHAPTER 6 Subsection NB—Class 1 Components
David P. Jones and Greg L. Hollinger
6.1 Introduction
6.2 Design
6.3 Analysis
6.4 Primary Stress Limits
6.5 Primary-Plus-Secondary Stress Limits
6.6 Fatigue
6.7 Special Procedures
6.8 Elastic-Plastic FEA
6.9 References
6.10 Summary of Changes
CHAPTER 7 Section III: Subsections NC and
ND—Class 2 and 3 Components
Marcus N. Bressler
7.0 Introduction to Chapter 7.0
7.1 Articles NC-1000 and ND-1000
7.2 Articles NC-2000 and ND-2000, Material
7.3 Articles NC-3000 and ND-3000 (Design)
7.4 Articles NC-4000 and ND-4000 (Fabrication and
Installation)
7.5 Articles NC-5000 and ND-5000 (Examination)
7.6 Articles NC-6000 and ND-6000 (Testing)
7.7 Articles NC-7000 and ND-7000 (Overpressure
Protection)
7.8 Articles NC-8000 and ND-8000 (Nameplate,
Stamping, and Reports)
7.9 Summary of Changes
7.10 Summary of Changes
7.11 References
CHAPTER 8 Subsection NB, NC, ND-3600 Piping
Donald F. Landers
8.1 Background
8.2 Nuclear Class 1, NB-3600
8.3 Nuclear Class 2 and 3 NC/ND-3600
8.4 Design Process
8.5 Design Specification Discussion
8.6 References
CHAPTER 9 Subsection NE—Class MC
Components
Kamran Mokhtarian and Roger F. Reddy
9.1 Introduction
9.2 Scope of Subsection NE
9.3 Boundaries of Jurisdiction of Subsection NE
9.4 General Material Requirements
9.5 Certified Material Test Reports
9.6 Material Toughness Requirements
9.7 General Design Requirements
9.8 Qualifications of Professional Engineers
9.9 Owner’s Design Specifications
9.10 Certified Design Report
9.11 Design by Analysis
9.12 Appendix F
9.13 Fatigue Analysis
9.14 Buckling
9.15 Reinforcement of Cone-to-Cylinder
Junction
9.16 Plastic Analysis
9.17 Design by Formula
9.18 Openings
9.19 Bolted Flange Connections
9.20 Welded Connections
9.21 General Fabrication Requirements
9.22 Tolerances
9.23 Requirements for Weld Joints
9.24 Welding Qualifications
9.25 Rules for Marking, Examining, and Repairing Welds
9.26 Heat Treatment
9.27 Examination
9.28 Qualifications and Certification of NDE Personnel
9.29 Testing
9.30 Overpressure Protection
9.31 Nameplates, Stamping, and Reports
9.32 Recommendations
9.33 References
9.34 Summary of Changes
CHAPTER 10 Subsection NF—Supports
Uma S. Bandyopadhyay
10.1 Executive Summary
10.2 NF-1000 Introduction
10.3 NF-2000 Materials
10.4 NF-3000 Design
10.5 NF-4000 Fabrication and Installation
10.6 NF-5000 Examination
10.7 NF-8000 Nameplates, Stamping, and Reports
10.8 NF Appendices
10.9 Code Cases and Interpretations
10.10 Summary of Changes
10.11 ASME B31.1 and B31.3 Supports
10.12 References
CHAPTER 11 Subsection NG—Core Support
Structures
John T. Land
11.1 Introduction
11.2 Jurisdictional Boundaries (NG-1130)
11.3 Distinctions Between Core Support Structures,
Internal Structures, Threaded Structural
Fasteners, and Temporary Attachments
11.4 Unique Conditions of Serivce
11.5 Materials of Construction (NG-2000)
11.6 Special Materials
11.7 Fabrication and Installation Rules and
Requirements (NG-4000)
11.8 Examination and Repair (NG-5000)
11.9 Design
11.10 Testing
11.11 Overpressure Protection
11.12 Nameplates/Stamping Effects (NG-8000)
11.13 Environmental Effects (NG-3124)
11.14 Special Bolting Requirements (NG-3230)
11.15 Code Cases (NCA-1140)
11.16 Interpretations for Subsection NG
11.17 Elevated Temperature Applications
11.18 Additional Considerations
11.19 Beyond the State-of-the-Art
11.20 References
11.21 Abbreviations and Nomenclature
11.22 Summary of Revisions
CHAPTER 12 Subsection NH—Class 1
Components in Elevated Temperature Service
Robert I. Jetter
12.0 Introduction and Scope
12.1 Article NH-1000, Introduction
12.2 Article NH-2000, Materials
12.3 Article NH-3000, Design
12.4 Article NH-4000, Fabrication and Installation
12.5 Article NH-5000, Examination
12.6 Article NH-6000, Testing
12.7 Article NH-7000, Overpressure Protection
12.8 Other Component Classes, Components,
and Materials
12.9 Current and Emerging Issues for Nuclear
Components in Elevated Temperature Service
12.10 Future ASME Code Considerations for Nuclear
Components in Elevated Temperature Service
12.11 References
12.12 Summary of Changes
CHAPTER 13 Nuclear Pumps and Valves
Marcus N. Bressler
13.1 Introduction
13.2 General Section III Requirements
13.3 Specific Pump Requirements
13.4 General Requirements for Class 1 Pumps
13.5 NC-3400 Class 2 Pumps
13.6 ND-3400 Class 3 Pumps
13.7 General Requirements for Class 2 and 3 Pumps
13.8 Specific Valve Requirements
13.9 NC-3500 and ND-3500, Class 2 and 3 Valves
13.10 Changes in the 2004 and 2007 Editions
13.11 References
13.12 Additional Documents of Interest
SECTION III DIVISION 2
CHAPTER 14 Code for Concrete Reactor
Vessels and Containments
Hansraj Ashar, Barry Scott, Joseph F.
Artuso and John D. Stevenson
14.1 Introduction
14.2 Future Containment Development
14.3 Background Development of Concrete
Containment Construction Code Requirements
14.4 Reinforced-Concrete Containment Behavior
14.5 Concrete Reactor Containment Design
Analysis and Related Testing
14.6 Code Design Loads
14.7 Allowable Behavior Criteria
14.8 Analytical Models and Design Procedures
14.9 Special Design Features
14.10 Current Organization of the Code
14.11 Article CC-4000: Fabrication and Construction
14.12 Article CC-5000: Construction Testing and
Examination
14.13 Article CC-6000: Structural Integrity Test of
Concrete Containments
14.14 Article CC-7000: Overpressure Protection
14.15 Article CC-8000: Nameplates, Stamping,
and Reports
14.16 Practical Nuclear Power Plant Containment
Designed to Resist Large Commercial Aircraft
Crash and Postulated Reactor Core Melt
14.17 Items Which Should be Considered in Future
Revisions of the Code
14.18 Summary
14.19 References
SECTION III DIVISION 3
CHAPTER 15 Containments for Transportation
and Storage of Spent Nuclear Fuel and High-level
Radioactive Material and Waste*
D. Keith Morton and D.Wayne Lewis
15.1 Introduction
15.2 Historical Development
15.3 Scope of Subgroup Nupack
15.4 Code Development
15.5 General Provisions
15.6 Specified Loading Categories
15.7 Allowable Stress
15.8 Materials, Fabrication, Installation, Examination,
and Testing
15.9 Code Text Organization
15.10 Current Activities in Division 3
15.11 Suggested Enhancements for the Future
15.12 References
15.13 Summary of Changes
PART 4: CODES FOR B31.1 & B31.3 PIPING
CHAPTER 16 B31.1, Power Piping
Charles Becht IV
16.1 Background and General Information
16.2 Organization of B31.1
16.3 Design Conditions and Criteria
16.4 Pressure Design
16.5 Limitations on Components and Joints
16.6 Design Requirements for Specific Systems
16.7 Design for Sustained and Occasional Loads
16.8 Design Criteria for Thermal Expansion
16.9 Flexibility Analysis
16.10 Supports and Restraints
16.11 Requirements for Materials
16.12 Fabrication, Assembly, and Erection
16.13Examination
16.14 Pressure Testing
16.15 Nonmetallic Piping
16.16 Operation and Maintenance
CHAPTER 17 B31.3 Process Piping
Charles Becht IV
17.1 Background and General Information
17.2 Organization of ASME B31.3
17.3 Design Conditions and Criteria
17.4 Pressure Design
17.5 Limitations on Components and Joints
17.6 Design for Sustained and Occasional Loads
17.7 Design Criteria for Thermal Expansion
17.8 Flexibility Analysis
17.9 Supports
17.10 Requirements for Materials
17.11 Fabrication, Assembly, and Erection
17.12 Examination
17.13 Pressure Testing
17.14 Nonmetallic Piping Systems
17.15 Category M Piping
17.16 High-Pressure Piping
17.17 What’s Being Considered for Future Editions
of ASME B31.3
PART 5: HEATING BOILERS - SECTION IV
& VI OF B&PV CODE
CHAPTER 18 ASME Section IV: Rules for the
Construction of Heating Boilers
Geoffrey M. Halley and Edwin A. Nordstrom
18.1 Introduction
18.2 Part HG: General Requirements for all
Materials of Construction
18.3 Part HF: Requirements for Boilers Constructed
of Wrought Materials
18.4 Part HF, Subpart HW: Requirements for Boilers
Fabricated by Welding
18.5 Part HF, Subpart HB: Requirements for Boilers
Fabricated by Brazing
18.6 Part HC: Requirements for Boilers Constructed
of Cast Iron
18.7 Rules of Part HA: Hot Water Heating Boilers
Constructed Primarily of Cast Aluminum
18.8 Part HLW: Requirements for Potable-Water
Heaters
18.9 Considerations Likely to be in Future Code
Editions
18.10 What Should the ASME Code Committees and
Regulators Consider, Recognizing the Intent
of the ASME B&PV Code?
18.11 Summary of Changes
18.12 References
CHAPTER 19 ASME Section VI: Recommended
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