manhattan gmat guide catalog 2

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manhattan gmat guide catalog 2Requirements are specific to each course and may include a combination of attendance, daily assessments, activities, quizzes, or knowledge checks. Requirements are specific to each certification and may include a combination of exams, application, course completion, work experience and proof of educational achievements. Please visit the CP 3 and CP 4 certification page for more details. The CP3 course builds on the technology presented in the CP2 course with a strong focus on interpretation of CP data, trouble shooting, and migration of problems that arise in both galvanic and impressed current systems, including design calculations for these systems. Requirements are specific to each course and may include a combination of attendance, daily assessments, activities, quizzes, or knowledge checks. Requirements are specific to each certification and may include a combination of exams, application, course completion, work experience and proof of educational achievements. The upcoming available times are: The upcoming available times are: The upcoming available times are: A voucher needed to schedule the CBT exam is included as part of your initial course registration. The work experience requirement for renewals for all certifications is one and half (1.5) years for the most recent three (3) year period. Additionally, some certifications have other requirements related to responsibility in charge. Your work experience and PDH's will be submitted as part of your renewal application but you can input PDH's at any time. See the certification renewal guide for PDH's requirements, our sample training PDH guide, and our PDH how-to videos. All application fees are non-refundable. To avoid processing delays or forfeiture of fees, please ensure that the application is complete, meets all the requirements and payment has been received. Co-Author of Technical Seminar for Cathodic Protection to GOGC. Cathodic Protection CATHODIC PROTECTION PROTECTION SYSTEM - ExPG.pdf?http://pragatiestate.com/userfiles/ensoniq-zr-76-manual.xml

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cathodic protection system should be made during REMOTE MONITORING - Cathodic Protection Company Clearly the best protection. Cathodic Protection Co Refining Corrosion Technologist NACE-RCT-001 Cathodic Protection Technologist. The exam consists of 70 multiple-choice questions that are based on the Cathodic. The scope, desired learning outcomes and performance criteria were prepared by the NACE Cathodic Protection Subcommittee under the auspices of the NACE Certification and Education Committees. Special thanks go to this subcommittee. Cathodic Protection Subcommittee Paul Nichols Brian Holtsbaum Don Mayfield Steve Nelson Kevin Parker David A. Schramm Steve Zurbuchen Shell Global Solutions, Houston, Texas CC Technologies, Calgary, Alberta Dominion Transmission, Delmont, Pennsylvania Columbia Gas Transmission, Charleston, West Virginia CC Technologies, Mt. Pleasant, Michigan ENEngineering, Woodridge,Illinois OneOK Inc., Topeka, Kansas This group of NACE members worked closely with the contracted course developers, Rob Wakelin, CorrEng Consulting Service, Inc., (Downsview, Ontario), Bob Gummow, CorrEng Consulting Service, Inc., (Downsview, Ontario) and Tom Lewis, Loresco International (Hattiesburg, Mississippi). IMPORTANT NOTICE: Neither the NACE International, its officers, directors, nor members thereof accept any responsibility for the use of the methods and materials discussed herein. No authorization is implied concerning the use of patented or copyrighted material. The information is advisory only and the use of the materials and methods is solely at the risk of the user. Printed in the United States. All rights reserved. Reproduction of contents in whole or part or transfer into electronic or photographic storage without permission of copyright owner is expressly forbidden. The Nernst Equation. Common Reference Electrodes. Effect of Temperature on Reference Electrode Potentials. Circuit Resistance Changes. (a) Increase in Resistance in a Corrosion Cell.http://culture-agencement.com/data/epiccare-emr-manual.xml (b) Decrease in Resistance in a Corrosion Cell. Effect of Driving Voltage on a Corrosion Cell. Effect of Time on a Corrosion Cell. Randles Circuit Model for an Electrode Interface in a Corrosion Cell. Polarization Shift Criterion (100 mV). Activation and Concentration Polarization. Conductive Coupling Due to Faults. a. Description. b. Deleterious Effects. c. Prediction and Mitigation. Electrostatic (Capacitive) Coupling. a. Description. b. Deleterious Effects and Mitigation. Experience on Similar Structures in Similar Conditions. Determining Current Requirements on a Coated Structure by Estimating the Percentage Bare. 4:9 4:11 Minimum Voltage Drop Method. a. Field Test to Determine Current Required on a Pipeline Based on Minimum Voltage Drop. b. Using Pipe-to-Earth Resistance to Determine Current Required by the Voltage Drop Method. c. Calculation of Current Required to Achieve a Minimum Voltage Drop on a Coated Structure Based on Coating Resistance. 4:13 Polarization Test Method. Polarization Shift Method. 4:17 4:20 4.4 Calculation of Cathodic Protection Circuit Resistances. 4:21 4.3.4 4.3.5 4.3.6 4.4.1 4.4.2 4.4.3 4.4.4 4.4.5 4.4.6 Resistance of a Single Rod Shaped Anode Positioned Vertically in the Earth. Resistance of Multiple Vertical Anodes Connected to a Common Header Cable or Structure. Resistance of a Single Rod Shaped Anode Positioned Horizontally in the Earth. Resistance of Multiple Horizontal Anodes Connected on a Common Header Cable. Calculating Pipe Resistance to Remote Earth. Attenuation. Effect of Coating on Current Distribution. Effect of Anode-to-Structure Spacing on Current Distribution. Effect of Structure Arrangement on Current Distribution. Effect of Electrolyte Resistivity Variation on Current Distribution. Effect of Current Distribution on Holidays on a Coated Structure. Effect of Polarization (Time) on Current Distribution. Buried Reference Electrodes. Polarity Considerations. The Potential Measurement Circuit and Measurement Error 5.https://www.informaquiz.it/petrgenis1604790/status/flotaganis27062022-02282 Voltage Drop Errors External to the Metering Circuit. 5.2.1 5.2.2 Voltage Drop Errors in the Potential Measurement due to Current in the Earth. Voltage Drop Errors in the Potential Measurement due to Current in the Pipeline. 5.3 Methods of Minimizing Voltage Drop Errors in the Potential Measurement. 5.3.1 5.3.2 5:2 5:4 5:5 5:6 5:10 5:10 5:13 5:14 Current Interruption Method. Step-Wise Current Reduction Method of Determining the Amount of Soil IR Drop in the On-Potential. Reference Electrode Placement Close to the Structure. Zero Resistance Ammeter. Clamp-on Ammeter. Pipeline Current Measurements. 5:33 5:34 5:35 5:36 5.6 Close Interval Potential Survey. 5:38 5.7 Coating Condition Surveys. 5:43 5.7.1 Voltage Gradient Method of Detecting Holidays in a Pipe Coating. 5.7.2 Coating Conductance Method of Evaluating Coating Quality 5.8 Troubleshooting Cathodic Protection Systems. 5.8.1 5:43 5:44 5:48 Polarization Changes. a. Structure Depolarization. Anode Polarization. Increased Resistance. Power Supply Changes. a. Zero Current and Voltage Outputs. b. Zero Current Output with Unchanged Voltage Output. c. Significant Current Change with Unchanged Voltage. d. Significant Changes in Both Voltage and Current Outputs. e. Transformer-Rectifier Efficiency. Cathodic Protection Troubleshooting Flow Chart. 5:48 5:48 5:50 5:51 5:54 5:57 5:58 5:58 Class Exercise 5-1: Evaluating Cathodic Protection Performance. 5:62 5.8.2 5.8.3 5.8.4 5.8.5 5:59 5:59 5:60 Appendices Appendix A Appendix B Appendix C Appendix D Appendix E Appendix F Anode Specifications Pipe Data Table Metric Conversion Table Shunt Table Glossary NACE Standards. Unit Cell Atomic Arrangement in Metal Crystal Structures. Corrosion Forming Ferrous Hydroxide. Pourbaix Diagram for Iron in Water at 25?C Showing Corrosion Rates. Measurement of Metal Potential with respect to a Reference Electrode. Standard Hydrogen Electrode. Reference Electrode Conversion Scale. Iron Corrosion Cell. Direction of Conventional Current (positive charge flow). Charge Movement in a Corrosion Cell. Open Circuit Corrosion Cell. Closed Circuit Corrosion Cell. Evans’ Diagram for a Corrosion Cell. Evans’ Diagram for a Corrosion Cell Under Anodic Control and Mixed Control. Simple DC Circuit Representing a Corrosion Cell. Polarization Diagram for a Corrosion Cell. Corrosion Potential Measurement to a Remote Reference Electrode. Corrosion Potential Indicated on the Polarization Diagram. Measurement of Corrosion Potential (Mixed Potential). Measurement of Corrosion Potential on a Pipeline with Two Holidays. Polarization Diagram Showing Charge Transfer Reactions. Effect of Depolarization at Both Anode and Cathode. Cathode Depolarization in a Corrosion Cell. Anode Depolarization in a Corrosion Cell. Increased Polarization at Both the Anode and Cathode of A Corrosion Cell. Increase in Resistance in a Corrosion Cell. Soil Resistivity vs. Moisture Concentration. Resistivity vs. Temperature for Four Soil Types. Decrease in Resistance in a Corrosion Cell. Effect of Driving Voltage (EMF) on a Corrosion Cell. Application of CP Current. Corrosion Stopped. Range of Polarized Potentials for Protection at Each Site. Range of Polarization for Protection at Each Site. Polarization Curves for Iron Corrosion in Acid. Evans’ Diagram for Corrosion Cell. Evans’ Diagram for Corrosion Cell with CP. Polarization Curves in Aerated and Deaerated Solutions of pH7. Effect of Increasing Oxygen Concentration. Effect of Increasing Agitation. Laminar Flow Versus Turbulent Flow. Effect of Increasing Temperature. Effect of Decreasing pH. Effect of Increasing Surface Area. Effect of Increasing Surface Area (Current Density). Variation of pH with Distance. Current Capacity Vs. Current Density for Aluminum. Current Capacity of AZ63 Magnesium Alloy vs. Current Density. Polarization Diagram for Galvanic Anode System. Current Discharge Paths from Anode Surface. Single-Phase Bridge Rectifier Circuit. Three-Phase Bridge Rectifier Circuit. Single-Phase Diode Bridge. Input and Output Signals from Single-Phase Diode Bridge. Silicon-Controlled Rectifier (SCR). Single-Phase SCR Controlled Bridge. Full-Wave SCR Bridge Output Waveforms. Block Diagram for Switching-Mode and Standard Rectifiers. Parallel Current Paths in a Pipeline Cathodic Protection Section. Parallel Current Paths in Vertically Stratified Soil Conditions Parallel Current Paths in Horizontally Stratified Soil Conditions. Stray Current in a Metallic Structure Parallel to a Cathodically Protected Structure. Voltage vs. Distance from a Vertically Oriented Anode. Voltage Gradient in the Earth Around a Cathodically Protected Bare Pipeline. Cathodic Protection Circuit Model. Cathodic Protection Circuit Model with Foreign Structure Intercepting the Anode Gradient. Stray Current in a Foreign Metallic Structure that Intercepts both the Anodic and Cathodic Voltage Gradient. Cathodic Protection Circuit Model with Foreign Structure Intercepting both Anodic and Cathodic Voltage Gradient. Stray Current in a Foreign Metallic Structure that Intercepts the Cathodic Protection Gradient. Cathodic Protection Circuit Model for Foreign Structure Intercepting the Cathodic Voltage Gradient. Typical Potential Profile on an Interfered-with Structure that Intersects both Anodic and Cathodic Voltage Gradient with the Current Source Interrupted. Solid-State DC Decoupling Device. Interaction of Solar Particles on the Earth’s Magnetic Field. Schematic of Geomagnetic Induction Directly into a Pipeline and the Resulting Change in Pipeline Potential that is Produced. Example Day of Geomagnetically Induced Potential Fluctuations on a Pipeline. Typical Geomagnetically Induced Potential Profile on a Well Coated and Poorly Coated Pipeline. Typical Pipe-to-Soil Potential Measurement Situation Where Telluric Current Activity is Present. Current Flow and Calculated Off Potentials During a GIC Incident. Example Test Station in Which Coupon Does Not Require Disconnection to Minimize IR Drop Error in the Potential Measurement. Example of Difference in Potential-time Recording Between Reference Electrode at Grade and Inside a Soil Tube with a Coupon (e.g. Figure 3-82). Pipe-to-Soil Potential Measurement Method to Compensate for Telluric Current Effects During a Close Interval CP Survey. Mitigation of Telluric Current Discharge Effects Using Galvanic Anodes. Schematic of Potentially Controlled Cathodic Protection System Used to Mitigate Telluric Current Effects. Pipe Potential and Rectifier Current Output vs. Coupon Current Density as a Function of Off-Potential. Instant-off Potential vs. Current Density for Carbon Steel Electrode in Sand and Clay Soil from Long Term Polarization Test Results. FBE Coating Conductance vs. Bare Area Normalized for a Soil Resistivity of 1000 ohm-cm as Related to General Coating Quality in Table 4-4. Voltage Drop Method of Determining Current Requirements Cathodic Polarization Plot and Determination of Cathodic Protection Current (Icp) Required. Effect of Time on the Shape of a Dynamic Cathodic Polarization Curve. Current Density in Clay Soil for 100mV Polarization Shift vs. Bare on Coated Steel. Relative Economic Range for Galvanic and Impressed Current Systems as a Function of Current Required and Soil Resistivity. Electrical Schematic for an Operating Galvanic Cathodic Protection System. Electrical Schematic for an Operating Impressed Current Cathodic Protection System. Anode Placed Vertically in Earth at Grade. Multiple Vertical Anodes Connected to a Common Header Cable. Anode Placed Horizontally Below Grade. Multiple Horizontal Anodes in a Coke Trench Connected to a Common Header Cable. Multiple Horizontal Anodes Connected to a Common Header Cable. Resistance of a Horizontal Pipe Section. Polarization Diagram for a Galvanic Cathodic Protection System. Polarization Diagram for an Impressed Current Cathodic Protection System (cable resistances (Rc) are ignored). Single Groundbed Design. Typical Current Distribution with a Vertical Cylindrical Anode Current Path Resistances for Ideal Current Distribution. Current in Structure Under Ideal Conditions. Current Path Resistance Including Resistance of Pipeline. Current and Voltage Attenuation Away from the Drain Point. Effect of Attenuation Constant.Leakage Resistance to Remote Earth on a Coated Structure Current Distribution with a Close Anode-to-Structure Spacing. Anode-to-Anode Spacing to Achieve Relatively Uniform Current Distribution with Close Anode-to-Structure Spacing. Copper-Copper Sulfate Reference Electrode. Effect of Copper-Sulfate Concentration on CSE Potential. Structure-to-Soil Potential Measurements. Electrical Schematic of the Pipe-to-Soil Measurement Circuit Methods of Minimizing Reference Electrode Contact Resistance. Voltage and Current Lines Around a Pipeline Receiving Cathodic Protection Current. Electrical Schematic Illustrating Soil Voltage Drop in the Potential Measurement. Current and Voltage Lines Around a Holiday on a Coated Pipeline. Current and Voltage Lines in Immediate Vicinity of a Holiday. Voltage Drop in a Pipeline Carrying Current. Electrical Schematic to Illustrate Potential Measurement Error due to CP Current in a Pipeline. Graphical Illustration of the Current Interruption Method of Minimizing Voltage Drop Error in the Potential Measurement Example of Close Interval Potential Survey Data Plotted Vs. Illustration of Positive Spike in Potential when CP Current is Interrupted. Illustration of Re-circulating Current Activity after the Interruption of CP Current. Field Test Arrangement for the Step-Wise Current Reduction Method of Determining the Amount of IR Drop in the On-Potential. Data Plot for Step-Wise Current Reduction Technique. Reference Electrode Placed Close to Pipe Surface to. Reference Electrode Placed Close to a Bare Riser Pipe. Reference Electrode Placed Close to a Coated Pipe Surface Using a Soil Tube to Minimize IRe Drop in a Potential Measurement on Bare Pipe. Using a Steel Coupon to Simulate a Holiday on a Pipeline. Schematic of an Integrated Coupon Test Station. Difference Between Coupon Disconnected Potential and Coupon-Pipe Potential with ICCP Interrupted. Difference Between Coupon Disconnected Potential Measured with Reference on Grade Versus in the Soil Tube. Pipe vs. Coupon Off-Potential. Photo of Vertical IR Drop Coupon. Schematic of Vertical IR Drop Coupon. Potential vs. Time Plot for Determining Polarization Potential Shift. Measurement of CP Current Using an Ammeter. Current Measurement in Parallel Drain Conductors. Use of Shunts for Current Measurements in Parallel Conductors. Current Measurement Using a Zero Resistance Ammeter (ZRA). Using a Clamp-on Ammeter to Measure Current. Schematic of the Hall Effect for Conventional Current Direction. Swain Meter. Calibrating a Pipeline Current Span. Length of Pipe Sampled in a Pipe-to-Soil Potential Measurement. Length of Bare Pipe Over Which Potentials are Averaged as a Function of Burial Depth. Relative Circumferential Sampling Distance as a Function of Pipe Diameter-to-Pipe Depth Ratio. Error in Potential Measurement Introduced by Reference Electrode Lead Conductor Contacting the Earth. Error in Potential Measurement Introduced by Current in the Pipeline. Error in Potential Measurement due to Interaction with a Parallel Interconnected Pipeline. Coating Holiday Detection Using Voltage Gradient Method. Arrangement for a Pipeline Coating Resistance (Conductance) Test. Structure Depolarization in a Galvanic CP System. Increased Anode Polarization in an Impressed Current System. Increased Anode Polarization in a Galvanic System. Table 1-3 Common Reference Electrodes and Their Potentials and Temperature Coefficients. Table 1-4 Theoretical Consumption Rates of Various Metals and. Substances on An Ampere-Yr. Basis. Table 1-5 Electrochemical and Current Density Equivalence with Corrosion Rate. 1:1 1:9 1:11 1:23 1:25 Chapter 2 Cathodic Protection Theory Table 2-1 Table 2-2 Table 2-3 Table 2-4 Table 2-5 Table 2-6 Table 2-7 Table 2-8 Table 2-9 Table 2-10 Table 2-11 Table 2-12 Table 2-13 Table 2-14 Potential Criteria from British Standard BS 7361. Potential Criteria from German Standard DIN 30676. Factors Controlling Polarization Response. Factors Controlling Exchange Current Density, iO. Factors Controlling Limiting Current Density, iL. Aluminum Anode Alloys. Magnesium Anode Alloys. Zinc Anode Alloys. Galvanic Anode Backfills. Massive-Type Impressed Current Anodes. All answers MUST be bubbled in on the ParSCORETM Score Sheet. Answers recorded on the actual exam will NOT be counted. If changing an answer on the ParSCORETM sheet, be sure to erase completely. Bubble only one answer per question and do not fill in more answers than the exam contains. PART B EXAM GUIDELINES OBJECTIVE: To determine the student’s experience level and specific cathodic protection knowledge. EXAMINATION RESULTS POLICY AND PROCEDURES It is NACE policy to not disclose student grades via the telephone, e-mail, or fax. Students will receive a grade letter, by regular mail or through a company representative, in approximately 6 to 8 weeks after the completion of the course. However, in most cases, within 7 to 10 business days following receipt of exams at NACE Headquarters, students may access their grades via the NACE Web site. WEB Instructions for accessing student grades on-line: Go to: www.nace.org Choose: Education Grades Access Scores Online Find your Course ID Number (Example 07C44222 or 42407002) in the drop down menu. For In-House, Licensee, and Section-Registered courses, a Temporary ID number will be assigned at the course for the purposes of accessing scores online only. For In-House courses, this information may not be posted until payment has been received from the hosting company. Information regarding the current shipment status of grade letters is available upon the web upon completion of the course. Processing begins at the receipt of the paperwork at NACE headquarters. When the letters for the course are being processed, the “Status” column will indicate “Processing”. Once the letters are mailed, the status will be updated to say “Mailed” and the date mailed will be entered in the last column. Courses are listed in date order. Examination This course will conclude with a written final examination. A combined score (Part A and Part B combined) of 70 or greater is required for successful completion of this course. The final examination is open book and students may bring reference materials and notes into the examination room. The final examination will be given on Friday. Non-communicating, battery-operated, silent, non-printing calculators, including calculators with alphanumeric keypads, are permitted for use during the examination. Calculating and computing devices having a QWERTY keypad arrangement similar to a typewriter or keyboard are not permitted. Such devices include but are not limited to palmtop, laptop, handheld, and desktop computers, calculators, databanks, data collectors, and organizers. Also excluded for use during the examination are communication devices such as pagers and cell phones along with cameras and recorders. NACE INTERNATIONAL INSTITUTE CAN ASSUME NO RESPONSIBILITY FOR FORMS LOST IN TRANSIT. 2. All information requested on the accompanying forms must be legibly printed or typewritten in black ink, suitable for photocopying. Proctor Agreement Form NACE International Institute Certification Program 2 Important Information Before submitting this application, check to be sure you have completed ALL of the following: Completely filled out this Application. Provided all information requested. Do not, however, submit documentation in excess of that requested. Documentation in excess of that requested will not be considered as part of your application. Distributed Qualification Reference forms to at least two individuals who will complete and return the forms to NACE International Institute. Attached proof of NACE Education courses.Applications are processed strictly on a first-in, first processed basis. No exceptions will be made. All NACE exams are the sole possession of NACE International. Any copying or sharing of any portions of the exam(s) without the express written consent of NACE International is prohibited. Determinations regarding cheating shall be made in accordance with NACE policies and procedures, which NACE may amend in its sole discretion. Applicants acknowledge and agree that they are subject to these terms and conditions when taking any NACE exam. All fees are non-refundable. I understand that any information provided by me that is found to be false, incomplete or misrepresented in any respect, will be sufficient cause to cancel further consideration of this application. I expressly authorize, without reservation, NACE, its representatives or employees to contact and obtain information from all references (personal and professional), employers, public agencies, licensing authorities and educational institutions and to otherwise verify the accuracy of all information provided by me in this application. I hereby waive any and all rights and claims I may have regarding NACE and NACE Institute, its agents, employees or representatives, for seeking, gathering and using such information in the certification process and all other persons, corporations or organizations for furnishing such information about me. Signature: Date: Printed Name: NACE International Institute Certification Program 5 A.4 Previous NACE Courses Please list date of course completion for applicable courses below and please include copy of course certificate when submitting your certification application. NOTE 2: To expedite application please send copies of course certificates. NACE International Institute Certification Program 6 A.5 Qualification References A qualification reference is a person who will vouch for your technical competence. Two Qualification References are required, four are recommended. You are asked to give the names of persons (unrelated to you and not more than one from your company) who have personal knowledge of your cathodic protection experience and abilities or of your teaching in a cathodic protection-related field. Acceptable references are registered engineers, present supervisor, present clients, previous supervisors, previous clients, professors and instructors, and NACE International Institute Certificate holders of at least the same category for which you are applying. NOTE: You are to send these individuals a Qualification Reference form (Item D), which they must complete and return directly to NACE International Institute. This is your responsibility. You should follow up with these people to ensure that they correctly complete and return the Qualification Reference forms in a timely manner. Attachments of more than two single-sided pages will not be reviewed. State, Province, or Country: Date: Certification Number: Specialty, if any: Is registration currently active. Yes No EIT Registration: Education Background: Please complete the following and attach a copy of your degree(s). I understand that if I knowingly provide, or cause to be provided, any false information in connection with my recognition under the NACE International Institute Certification Program, that it will be grounds for action against my standing in the program. I understand that the names of the categories within the NACE International Institute Cathodic Protection Certification Program are as follows: Highest Level Successfully Completed Category Name CP 1 CP1-Cathodic Protection Tester CP 2 CP2-Cathodic Protection Technician CP 3 CP3-Cathodic Protection Technologist CP 4 CP4-Cathodic Protection Specialist 4. NACE Institute has a firm policy regarding the use of its logos and certification numbers and titles. The certification number and category title may be used only by NACE CP 1-Cathodic Protection Testers, NACE CP 2-Cathodic Protection Technicians, NACE CP 3-Cathodic Protection Technologists, and NACE CP 4-Cathodic Protection Specialists, and may not be used by any other persons. All active CP card holders are permitted to use the term “NACE CP 1-Cathodic Protection Tester,” “NACE CP 2Cathodic Protection Technician,” “NACE CP 3-Cathodic Protection Technologist,” or “NACE CP 4-Cathodic Protection Specialist” (whichever level of recognition attained) and their certification number on business cards. This example illustrates how this information can be used by a NACE CP 1-Cathodic Protection Tester. John Smith NACE CP 1-Cathodic Protection Tester, Cert. No. 9650 ACE Inspections, Inc., Knoxville, TN NACE CP 1-Cathodic Protection Testers, NACE CP 2-Cathodic Protection Technicians, NACE CP 3-Cathodic Protection Technologists, and NACE CP 4-Cathodic Protection Specialists who are members in good standing of NACE International Institute may display the NACE Institute Logo for the purpose of identifying the individual as having achieved a NACE Institute Certification. I understand that violation of these rules will result in action against my standing in the program on the basis of violation of the NACE International Institute Cathodic Protection Program Attestation. 5. I (re)affirm the NACE International Institute Cathodic Protection Certification Program attestation and agree to abide by its provisions as long as I hold any level of recognition under the program. Signed: Date: NACE International Institute Certification Program 10 B.2. ATTESTATION I hereby: (1) Recognize and acknowledge that the proper control of corrosion can be critical to the safety and welfare of the general public and industrial facilities. (2) Recognize and acknowledge that the control of corrosion is obligatory to maximize conservation of our material resources, to reduce economic losses, and to protect the environment. (3) Recognize and acknowledge that the entire field of corrosion and its control encompasses the application of the knowledge and experience of many diverse disciplines and levels of technical competence which must often be consulted. (4) Recognize and acknowledge that only through continual association and cooperation with others in this field can the safest and most economical solutions be found to the many corrosion problems. (5) Recognize and acknowledge that the quality of my work reflects on the entire profession of corrosion control. I understand that my failure to comply with these requirements could result in disciplinary action. Signature: Printed Name: Date: NACE International Institute Certification Program 11 C. WORK EXPERIENCE DOCUMENTATION Directions: 1. Carefully read these directions before proceeding 2. Make as many copies of Work Experience Form 2: Individual Job Documentation as you need to document the work experience required. The applicant need not be in administrative or supervisory control of the work, however, it is necessary that the applicant be in technical control and have technical responsibility.