Tuesday, May 5, 2020
Identification of Continuing Professional Development
Question: Write an essay on Identification of Continuing Professional Development. Answer: I was a Reservoir engineer based in Aberdeen, with 10 years experience in various aspects of reservoir and petroleum engineering. I have competencies in expertise in EP Field Development Planning, Production Optimisation, Reservoir Management, Simulation, Performance and Production forecasting, Reservoir Model Building and Development, Reservoir Fluid Characterization. I moreover have experience in Classical Reservoir Engineering, Pressure Transient Analysis and Design, Uncertainty Analysis Management, and Economic Evaluation of projects. Academic Experience Masters of Science (Petroleum Engineering) from Heriot-Watt University, Institute Of Petroleum Engineering, Edinburgh, in the year 2009-2010 with distinction Bachelor of Engineering (Petroleum Engineering) from University Of Benin, Benin City, Nigeria, in the year 2005 in Second Class Upper Division Skill profile Simulator: CMG / IMEX, ECLIPSE, VIP, NEXUS, Petroleum Expert Tools (MBAL, PROSPER and GAP) Well-test Analysis: SAPHIR, PANSYSTEM, PIE, and ECLIPSE WELLTEST 200 Miscellaneous: MS Office, MS Excel, Power Point, Visio, Outlook and Access Geo-modeling / Visualization: RMS, CoViz, PETREL PVT: Winprop and PVTP MS Office Tool: Microsoft Excel, Word, PowerPoint, Microsoft Project Programming: VBA, Perl, and XML Moreover, I am a team player with Analytical, Problem solving, and Communication and Interpersonal skills as well. Professional Certificate I had attended several trainings and courses in my professional and academia career. Some of the events are the following. Event Name Year Schlumberger Petrel Training 2015 Water Flood Principle and Practices (BP) 2014 Option Evaluation Using Top Down Reservoir Modelling (BP) 2014 Applied Reservoir Simulation (BP) 2014 Classical Reservoir Engineering (BP) 2013 Subsurface uncertainty and Risk management (SURM) 2013 Basic Water Flood Awareness (BP) 2012 Applied Reservoir Engineering (Petroskills) 2012 Integrated asset modelling (IAM) with petroleum Expert Tool Kit (PROSPER, MBAL GAP), BP 2011 Intermediate Nexus Course, Landmark, (Reservoir simulation) 2011 Reservoir Fluids and Basics of EOS, BP 2011 Fundamentals of Reservoir Surveillance, BP 2011 Integrated Reservoir Modelling, Institute of Petroleum Engineering 2010 Workshop on Uncertainty Management, Institute of Petroleum Engineering 2010 Field Development Best Practices, Institute of Petroleum Engineering 2010 Reservoir Monitoring Management in Laser Engineering 2007 Technical report Writing and Presentation Skills in Laser Engineering 2008 Working Experience From 2012 until date: BP, Aberdeen-United Kingdom I was employed as a Reservoir Engineer with Reservoir Simulation and Depletion Planning in Support of Clair phase1 Field Development job description. Some of the other responsibilities were as Economic Evaluation of infill options Develop alternative Field Development Scenarios and perform Economic Evaluation on these options. Reservoir Engineering/Simulation studies in support of infill wells (producers/injectors) Provide Reservoir Engineering input for evaluating the value of 4D seismic acquisition in Clair Phase 1. Until 2011 BP, Aberdeen-United Kingdom I was employed as an Offshore Reservoir Engineer with Daily production Optimisation of Clair field Wells. I followed other roles as Coordinate all reservoirs and well work activities that ensure optimal reservoir recovery as well as higher well productivity on the Clair field. Communicate the significance and value of reservoir management and surveillance strategy to the offshore Acquire, analyze and interprets surveillance data for reservoir and well limits. Until 2010 BP, Aberdeen-United Kingdom Post: Reservoir / Petroleum Engineer From 2008 until 2009 Laser Engineering Resources Consultants Limited / Laser Geo-science Training and Research Centre), Port Harcourt Post: Reservoir Engineer / Lecturer During 2007 to 2008 Shell Petroleum Development Company, Warri, Nigeria (Consultant Staff representing Laser Engineering Resources Consultants Limited), Port Harcourt Post: Reservoir Engineer / Consultant Well Test Analyst During 2006 to 2007 Ankor Pointe Integrated (API) Port Harcourt Post: Petroleum Engineer Declaration I declare that afore mentioned competencies and skill information are genuine and proper. I have completed Bachelors and Masters in Petroleum Engineering and I have sufficient expertises to belong to several organizations. I ensure the concerned authority that I am aware of the relevant workplace code of ethics to work with sustainability and at the same time with reliability. Name: Date: Place: Career Episode 1 1.1 Introduction Name of the Project: Alternative Field Development Options in a Water-Flood Field Duration of Project: Please Fill Project Location: Please Fill Name of the Organisation: Please Fill Role and Designation: Please Fill 1.2 Background 1.2.1 Criteria of Overall Engineering Project The primary focus of the project was to develop an alternative field option in water flood field for appropriately planning of water resource projects. The engineering project was intended to identify ways of utilization of available water for field development purposes. For successful accomplishment of the project, it required a proper application of the major skills and knowledge of reservoir and petroleum engineering technologies. The project further involved sufficient concepts of geological modelling as well as employing effective water flooding mechanisms. The initial design of the project involved estimation of different parameters based on the location and number of wells required to be drilled per injection location. Furthermore, the water flood patterns and selective injection design was utilized for determining the water flow regulators (WFRs). 1.2.2 Project Objective The primary objective of the project is to establish effective means to identify alternative field development options with advanced reservoir and petroleum engineering skills and knowledge. For this purpose, we built the field development team for undertaking the pattern establishment based on achievable measures of areal sweep efficiency. Moreover, for accomplishing the goal of the project, I collaborated with my team members to conduct a suitable drilling campaign for planning and placement of the producers and injectors. Additionally, the project essentially involved the objective of identifying and establishing alternative field development options for water flood field. The particular objectives are: To identify field development options for water flood field To study optimized ways for effective water flooding management using water flow regulators To recognize the reservoir pressure and permeability influence the water flow To estimate a proper design for field development To present the project with well-documented end results to the project supervisor 1.2.3 Criteria of my Work in Particular Area My particular area of work in this project was based on identifying the primary design and requirement specifications for executing the project in an efficient manner. For this specific purpose, I identified the undeveloped areas of the field and arranged the field water flow in a proper way. Furthermore, I reviewed and managed the water flood program with injectors and producers of water channelling following an adequate mobility ratio. In addition to that, I also significantly contributed in the process of determining the effectiveness of water flow from the injector wells and configuring the design in accordance with the requirements. 1.2.4 Individual People Associated with this Project 1.2.5 Statement of My Responsibilities In this project, the specific duties and responsibilities that I have performed are listed underneath: I identified the major project requirements for formulating the alternative water flood program I maintained all the safety and security requirements throughout the project I took the responsibility of design and placement of wells I undertook an in-depth study on reservoir management guidelines for successful accomplishment of the plan I divided the project deliverables into subtasks and assigned them into individual teammates according to their area of expertise I successfully contributed some creative ideas in the project implementation phase I took the responsibility of developing the primary budget plan of the project 1.3 Personal Engineering Activity 1.3.1 Understanding and Approach I applied my skills and knowledge particularly gained in the area of reservoir and petroleum engineering to develop the primary strategy to be followed for actualizing the project. Furthermore, I have understood the use of alternative as well as the stand by injection wells. The confinement process was to be understood to keep the injected produced water within the horizons specifications. Apart from this, the project sufficiently focused on basic alternative strategies in case injection is suspended for extended time or even the injection operation is terminated. Additionally, the injection well abandonment operations require effective plugging strategies. For avoiding any unwanted circumstances, it is important to incorporate continuous monitoring of the injection pressure. To execute the injection and monitoring operations, the key parameters are identified that also involve the use of new well diagnostics tools. Figure: Enhanced Recovery Flood Pattern 1.3.2 Claim of My Engineering Skills and Knowledge I performed all of the necessary reservoir and petroleum engineering activities to develop the water flood program and identify the appropriate pattern for the injector and producer design. I collaborated, coordinated with my fellow team members for the field development activities, including areal sweep efficiency, and organized the proper drilling campaign for planning and placement of injectors and producers. I employed advanced reservoir management and engineering approaches to monitor the overburden and horizontal stress and fracture closure pressure. I also conducted an extensive study to identify the applicable regulations, codes and standards to be adhered for the project development process. 1.3.3 Task allocation and execution I actively participated in the field development team to carry out the primary activities involved in the project. For this purpose, I coordinated with my team members and kept a constant contact with them through phone calls and emails for exchanging important information during the project development phase. Apart from that, I identified the major project deliverables and scheduled appropriate resources and time duration for each of the subtasks. I also demonstrated adequate competency in recognizing and developing a concept of the individual areas of strengths and weaknesses of each of team members and thereby contributed to assigning some tasks to the best person to perform the specific activity. 1.3.4 Identified Problems and Solution 1.3.4.1 Problems Significant problems were encountered regarding the well specifications activities. The initial state of the model before executing water flood program and in the early phase of the project initiation, the field development team faced difficulties and complexities in the process of specifying the five-spot pattern reservoir model along with the different marginal positions so as to ensure best outcomes that demonstrates the individual impact of the different parameters. 1.3.4.2 Solutions I, along with my teammates, have been successfully able to overcome the specific issues encountered during the project with the special help and guidance from our project supervisor. Apart from that, I performed some exhaustive analysis and research on the reservoir flow management methods and techniques, which in turn helped me significantly, identify the sources of problems. Thereafter, we conducted a reservoir simulation for predicting the overall vertical as well as areal extent of the injected produced water on a field scale. 1.3.5 Applied approaches to design original and creative work In this project, the phase in water flood design was performed in accordance with the codes and standards applicable. The reservoir management activities were required to follow the minimum economic and technical criteria for an appropriate water-flood design implementation. In addition to that, the surface facilities to handle the produced water for the reservoir are to adhere to a design using adequate flexibility. Similarly, for injection water requires specific surface facilities and maintains high water quality as well. The injection water treatment is focused on preventing the reservoir from being inoculated with bacteria. I specifically undertook the responsibility of performing all the major engineering and technical calculations for a successful water flood field development using a great detailed approach. More precisely, my area of activity also involved looking into different relevant literature sources for conducting a full range of geosciences and engineering studies. Figure: Possible Injection Water Sources 1.3.6 Collaboration with Team Members I have performed my duties as a reservoir engineer and maintained a consistent approach throughout the project development process. I effectively coordinated with my fellow team members in the process of developing the Gantt chart and allocating appropriate time and resources for each of the subtasks involved in the project. . Apart from that, I confidently approached our team leader, the project supervisor with any issues or confusion faced, and they have actively assisted and supported our effort throughout the process. 1.4 Summary 1.4.1 Outcomes of the Overall Project The project was successfully completed with the alternative strategies for field development adequately affecting the efficiency of the water flood program. With the accomplishment of the project, we also potentially discovered the additional reservoir methods and techniques using the newly acquired data. I personally acquired advanced practical skills in the reservoir engineering technologies to execute the major activities of field development options for water flood field. 1.4.2 Personal Contribution to the Project For successful execution of the project, I undertook significant responsibilities throughput the project life cycle, especially in project initiation and implementation phases. I identified the major requirements and estimated the primary or initial budget plan required for the project. To be more precise, I recognized the suitable injection properties as well as the confinement zone geo-mechanical properties for formulating the well specifications. Besides, I effectively coordinated and collaborated with my team members for accomplishing the project goal and objectives in a proper manner. Career Episode 2 2.1 Introduction Name of the Project: Planning of Wells for Infill Drilling Campaign on Clair Field Duration of Project: PLEASE FILL Project Location: PLEASE FILL Name of the Organisation: PLEASE FILL Role and Designation: PLEASE FILL 2.2 Background 2.2.1 Criteria of Overall Engineering Project Clair Oilfield is an offshore field potential of oil asset in Scottish territory. It is situated 75 kilometres west of Shetland with water depth of 460 ft. The filed extends to 220 square kilometres with coverage of five licence blocks. The aim of this infill campaign is to research over the selected site for recommending well construction. The well pattern will accelerate the oil recovery or check for recovery techniques. This was the project criteria as well the project description for certain objectives. The research is performed in Clair field for well planning for infill campaign. A handful numbers of major study had been conducted over the infill campaign and as per the previous results, the mature production was in deepwater from Neocene age as in Miocene, Pliocene, and Pleistocene reservoirs. The below graph depicts the oil recovery factors in non-water flooded Neocene age reservoirs. Figure: Oil recovery factors in non-water flooded Neocene age reservoirs 2.2.2 Project objectives The project is mainly centred in the planning of well construction for oil recovery in Clair filed. The objectives were the following: To research over the site Clair field To provide overall report to the authority for infill campaign and well planning To identify the oil recovery factors in this site To manage the project with assigning tasks to the other teammates 2.2.3 Criteria of my Work in Particular Area I worked as a project manager in particular project with allocating tasks to the members levelling the resources. The Gantt chart design will be helpful to tackle the challenging work of management. The Gantt chart utilizes timeline with available slack management and hence, the scheduling was flawless. On the other hand, I had to research on the site and characteristics. Therefore, I could grasp the entire project activity with my understanding of work. In most of the cases, the deepwater reservoirs are identified as the oil resources; therefore, I had to review the site with analyzing the underwater depth. I had to identify the IOR processes to add substantial reserves in the Clair field site. 2.2.4 People associated with this Project 2.2.5 My duties statement In the project, I had several duties as well. The project deliverables were to deepwater asset characterization for reservoir properties determination, search for key causes of captured hydrocarbons, gaps in leading recoveries determination, and concepts to secure gaps. I was the project manager and team leader in the project team. I had followed the duties as follows. I had to identify the IOR processes to add substantial reserves in the Clair field site. I identified the technical issues and lack of study in IOR processes application. I moreover recommended the future RD programs that can be implemented in order to minimize the technical limitations 2.3 Personal Engineering Activity 2.3.1 Understanding and Approach The understanding of the entire project is depicted in the below diagram with two phases of activities. Figure: Stages of work in Project After approval from the concerned authority on the entire project activity, the project is advanced with the above conceptual framework. Once the approval phase is over, the project is conducted with preparing a detailed Gantt chart including all the significant activities with timeline. The activities were included as research work, IOR review, data collection from the industry expertises, oil-trapping techniques, project management planning, IOR evaluation, gap identification, advisory meeting, reporting, and sign-off. The entire project was conducted in systematic way with each activity completion. 2.3.2 Claim of my engineering skills and knowledge The site is viewed for start-up oil reservoirs and their existence in the area. The overall view is shown below. The two phases are identified with respect to the fractured oil reservoirs in Clair field. Figure: Clair Field infill campaign sit I Figure: Clair Field infill campaign sitemap The Neocene prioritized IOR concepts are identified in the following table. The table is included for identification of IOR processes. IOR Process Low High Field Count Target OOIP of the field (MMSTB) Technical Readiness level Process ranking Conventional Water Injection 4% 25% 14 10021 7 1 Seafloor Water Injection 4% 18% 18 10350 4 2 Inà ¢Ã¢â ¬Ã Well ESP 3% 7% 13 12221 6 5 Inà ¢Ã¢â ¬Ã Well Gas Lift 3% 7% 21 10518 6 6 Hydrocarbon Gas Injection 3% 12% 5 7096 5 7 Nitrogen Injection 3% 12% 8 7980 4 9 Low Cost Wells 4% 9% 74 29748 0 18 Table: Identified IOR processes In this activity completion, I had to apply my knowledge of reservoir simulation, well test analysis, and oil field development. The engineering knowledge was applicable with project managerial activities. 2.3.3 Task allocation and execution In this project, the bulk of task was assigned to us from the site managers. The site managers include the team members for serving one or more than one specific purposes, therefore, I had to decompose the task into several smaller activities. The smaller activities were assigned to the teammates for faster completion within time. As I was accomplished with project management knowledge, therefore, it was never an issue to me to allocate activities to the team members with assessing their individual capabilities. 2.3.4 Identified Problems and Solution 2.3.4.1 Problems The problems were identified in the project as with the project completion within time and as well with deviating from the primary scope of the project. The scope was to recommend for wells in the selected site and oil reservoirs. The problems were as follows The teammates became deviated from the primary project scope; they were involved in the analysis for field data for oil trapping mechanisms. The problem turns out to be shortage of time, as they allocated more effort to the single activity. Again, the second issue turn out to be the misunderstanding between the team members. I was the team leader however, to some extent; I was unable to resolve their issues. Final issue was to derive the technical gap analysis in this project aspect. The gap analysis was to be performed under the secondary research, however, we lacked in the data collection part. 2.3.4.2 Solutions We approached to the project advisor and supervisor for reporting about the identified issues in the project activity. They helped us for mitigating the problems. First, they conducted a counselling session in between the team members for resolving the individual issues to enhance team integrity for improvement or teamwork. They additionally restructured the project scope to minimize the scope related deviation. The technical gap analysis issue was resolved with providing relevant studies for the purpose. Their effort was outstanding and supportive in this issue scenario. 2.3.5 Applied approaches to design original and creative work In the project, the locations for fractured oil reservoirs are identified as in the figure. Figure: The reservoir location The Infill Campaign result summary is included in the location details. The phase II infill drilling campaign is conducted with reusing the slots to tie in six new wells. The rig platform should be supported with Tender Support Vessel for drilling services. Location Field type First production Water depth (m) 206/8-15 Oil Q4 / 2013 2000 206/8-1A Oil Q4 / 2014 2400 206/8-11A Oil Q4 / 2014 2500 206/13A-2 Oil Q4 / 2015 2300 Table: Infill Campaign result 2.3.6 Collaboration with Team Members Ultimately, after resolving the team issues, we felt coordination within team for improving the project work. I learnt the idea of compact teamwork and support from my practical experience in this project. I realized that their effort was effective in order to commence the project with relevant revision to the scope. They followed the scheduling process as well and the scheduling helped us to devise the project within time. 2.4 Summary 2.4.1 Outcomes of the Overall Project I had achieved experience of teamwork, team maintenance as well as Reservoir Simulation knowledge application from this project. The outcome of the project was a report depicting well construction planning infill campaign in Clair field. I utilized ECLIPSE WELLTEST 200 software for well test analysis in this context. The project was appraised from the concerned authority with admiring our effort in enormous hard work within time. I was admired as best leader in the team, serving role of project management as well as reservoir engineer. I was happy to complete the project with confidence and adaptability. My project supervisor and advisor published the project report online and presented the paper later in project Expo. 2.4.2 Personal input to the Project I worked as a team leader and project manager to the project. Therefore, my responsibility was greater rather than any of my teammate with role comparison. I managed the pressure in the project activities in order to complete the project within time and meeting all objectives. Career Episode 3 3.1 Introduction Name of the Project: Reservoir Model Build and History Matching in support of Production Forecasting Duration of Project: PLEASE FILL Project Location: PLEASE FILL Name of the Organisation: PLEASE FILL Role and Designation: PLEASE FILL 3.2 Background 3.2.1 Criteria of Overall Engineering Project The primary criterion of the overall project is to matching the production forecasting data for reservoir modelling. The reservoir model will be developed as per the simulated models in software interfaces. The quality and accuracy of uncertain production forecasting is dependent over the reservoir models in oil and gas production organizations. The two principle approaches of production forecast were on the stochastic and probabilistic. The probabilistic decisions were considered in the criteria of the project. The oil reservoir model should be according to the production forecasting prior to the model building. The project criteria was somewhat complex for relating with the uncertainty and reality. 3.2.2 Project objectives The project objectives were the following as regarding to the project deliverables. The objectives were approved from the concerned authority and then we could continue with it. Otherwise, the project may turn out to be a disaster afterwards. To gather the geophysical information about the geometry of the reservoir To collect data about the well-log with measurement within the well-bore To reduce uncertainty in reservoir modelling with production forecasting To identify the parameters that can be utilized to increase the multiple point statistics 3.2.3 Criteria of my Work in Particular Area My work in this project was as a project manager in particular project with allocating tasks to the members levelling the resources. On the other hand, I had to research about the production forecasting process. The Gantt chart design will be helpful to tackle the challenging work of management. The Gantt chart utilizes timeline with available slack management and hence, the scheduling was flawless. Therefore, I could grasp the entire project activity with my understanding of work. In most of the cases, the reservoir modelling is implemented with all aspects of production facility. 3.2.4 People associated with this Project Img 10 3.2.5 My duty statement In the project, I had several duties as well. The project deliverables were to deepwater asset characterization for reservoir properties determination, search for key causes of captured hydrocarbons, gaps in leading recoveries determination, and concepts to secure gaps. I was the project manager and team leader in the project team. I had followed the duties as follows. I had to gather the geophysical information about the geometry of the reservoir I had to compare collected data about the well-log with measurement within the well-bore I had to understand the uncertainty factors in reservoir modelling with production forecasting I had to identify all the parameters with teammates that can be utilized to increase the multiple point statistics 3.3 Personal Engineering Activity 3.3.1 Understanding and Approach The entire project activities are decomposed in to separate activities of nine deliverables as The project deliverables were critical in some cases as in dynamic data inclusion, history matching, defining of targets, and prediction of production, and decision management. Hence, the project deliverables were matched with the concerned authority for better guidance and help. The project guide incorporated the solution in order to mitigate the difficulties with including one separate deliverable omitting others. The new deliverable was to research the secondary studies for devising the ideas in the project. For history matching process, we took permeability of reservoir layers as low perm and high perm cases. The identified samples for the research were the customers those are interested with update their reservoir models. The update will be provided with prediction and decision management about the new production process. The proposed process will help the sample with accurate field performance data and clarifications in diverse modelling. The aim of the study was to performance evaluation, production data influence, handling the multiple objectives and history matching with uncertain estimation. The history matching is performed with the framework as below. The stochastic methods are improved with genetic algorithm analysis. The GA analysis was better in this project, as we were dealing with making certain decisions. The decision-making is entirely supported with Genetic Algorithm with considering separate solutions and their individual impact on the process. The history matching process is easier with GA analysis, and comparing several solutions. The evolutionary strategies are moreover supportive with the project aspects regarding history matching for production forecasting and reservoir modelling change management. 3.3.3 Task allocation and execution In this venture, the greater part of task was allocated to us from the site supervisors. The site supervisors incorporate the colleagues for serving one or more than one particular purposes, in this manner; I needed to disintegrate the activity into a few number of activities. The activities were allotted to the fellow team members for quicker utilization of time. As I was proficient with undertaking project leadership, along these scenarios, it was never an issue to me to allot activities to the colleagues with surveying their individual capacities. 3.3.4 Identified Problems and Solution 3.3.4.1 Problems The problems were identified in the project as with the project completion within time and as well with deviating from the primary scope of the project. The scope was to change the modelling of reservoirs with reduce uncertainty. The problems were as follows The teammates became deviated from the primary project scope; they were involved in the analysis for collect data about the well log. The problem turns out to be shortage of time, as they allocated more effort to the single activity. Again, the second issue turns out to be the misunderstanding between the team members. I was the team leader however, to some extent; I was unable to resolve their issues. Final issue was to identify the parameters that can be utilized to increase the multiple point statistics. The parameter identification was to be performed under the secondary research, however, we lacked with multiple point statistics. 3.3.4.2 Solutions We approached to the project advisor and supervisor for reporting about the identified issues in the project activity, they helped us for mitigating the problems. First, they conducted a counselling session in between the team members for resolving the individual issues to enhance team integrity for improvement or teamwork. They additionally restructured the project scope to minimize the scope related deviation. The Parameter Identification Process problems were resolved with providing relevant studies for the purpose. Their effort was outstanding and supportive in this issue scenario. 3.3.5 Applied approaches to design original and creative work The applied approach in the project was as in the researching methods. The creative work of the project was about identification of the parameters and factors. The certain parameters are identified with the production forecasting. The production forecasting is probabilistic with respect to the reservoir modelling. The entire project was innovative, as we had devised genetic algorithm for optimizing the production process in business. The project outcome was with reporting the organization. The evolutionary strategies are important with the project completion within timeline. 3.3.6 Collaboration with Team Members Eventually, in the wake of determining the group issues, we felt coordination is essential inside of group for enhancing the venture work. I learnt the thought of minimized collaboration and inefficient lack from my reasonable involvement in this venture. I understood that their teamwork was compelling with keeping in mind that the primary criterion was to begin the venture with applicable correction to the extension. They considered the planning process necessary and the management helped us to devise the venture inside timeline. 3.4 Summary 3.4.1 Outcomes of the Overall Project The outcome of the project was reservoir model building with production forecasting matching. The production forecasting process was a challenging task in the project whereas, the scenario helped me well to deal with the process. On the other I was experienced with production management process, therefore, I had to match the reservoir model specification for better outcomes. I had achieved experience of teamwork, team maintenance as well as Reservoir Simulation knowledge application from this project. The project was appraised from the concerned authority with admiring our effort in enormous hard work within time. I was admired as best leader in the team, serving role of project management as well as reservoir engineer. I was happy to complete the project with confidence and adaptability. 3.4.2 Personal input to the Project I worked as a team leader and project manager to the project. Therefore, my responsibility was greater rather than any of my teammate with role comparison. I managed the pressure in the project activities in order to complete the project within time and meeting all objectives. Professional Engineering: Summary statement Competency Element A brief summary of how you have applied the element Paragraph number in the career episode(s) where the element is addressed PE 1: KNOWLEDGE AND SKILL BASE PE 1.1 Comprehensive, theory based understanding of the underpinning natural and physical sciences and the engineering fundamentals applicable to the engineering discipline I had attenuated my knowledge of Petroleum Engineering in the infill projects. I had also gained experience of teamwork in projects. CE 1.2.3, CE 1.3.1 and CE 1.3.2 CE 2.3.1 and CE 2.3.3 CE 3.2.1, CE 3.3.1 and CE 3.3.2 PE1.2 Conceptual understanding of the mathematics, numerical analysis, statistics, and computer and information sciences which underpin the engineering discipline I had technical application of software in designing of engineering modules with quality measurement and analysis. CE 1.3.1 CE 2.3.2, CE 2.3.3 and CE 2.3.4 CE 3.3.1 PE1.3 In-depth understanding of specialist bodies of knowledge within the engineering discipline I had used every possible resource in the team. I had also assigned the tasks with suitable capability assessment. CE 1.3.1 CE 2.3.1, CE 2.3.4, CE 2.2.5 and CE 2.4.2 CE 3.3.1.1, CE 3.3.3 PE1.4 Discernment of knowledge development and research directions within the engineering discipline I had practical knowledge of the normal calculation for the data analysis in the project. CE 1.2.5, CE 1.3.1.2, CE 1.4.2 and CE 1.4.3, CE 2.3.2, CE 2.3.4 and CE 2.4.1, CE 3.3.2, CE 3.3.3 and CE 3.4.1 PE1.5 Knowledge of contextual factors impacting the engineering discipline. I had to undertake the project with understanding the project objectives and aim. CE 1.2.1, CE 2.2.1, CE 3.2.1, CE 1.2.2, CE 2.2.2, CE 3.2.2 PE1.6 Understanding of the scope, principles, norms, accountabilities and bounds of contemporary engineering practice in the specific discipline It was the main criteria of being in a team and maintaining responsibilities in a team. CE 1.2.3, CE 1.3.1, CE 1.3.4, CE 1.3.2, CE 2.2.3, CE 2.3.1, CE 2.3.1.1, CE 2.3.2, CE 3.2.3, CE 3.3.1, CE 3.3.1.1 and CE 3.3.2 PE 2 ENGINEERING APPLICATION ABILITY PE2.1 Application of established engineering methods to complex engineering problem solving I had the ability to use my practical knowledge in the project whereas the complex problem analysis. I had to resolve the issues with every problem understanding. CE 1.2.4, CE 1.3.1, CE 1.4.2 and CE 1.4.3 CE 2.3.3, CE 2.3.4 and CE 2.4.1, CE 2.4.2 CE 3.3.1, CE 3.3.2 and CE 3.4.2 PE2.2 Fluent application of engineering techniques, tools and resources It was the main criteria of being in a team and maintaining responsibilities in a team. CE 1.3.3, CE 1.3.2, CE 1.3.1.1 and CE 1.3.3 PE2.3 Application of systematic engineering synthesis and design processes I had the ability to use my practical knowledge in the project whereas the complex problem analysis. I had to resolve the issues with every problem understanding. CE 1.2.3, CE 1.3.1, CE 1.3.1.1 and CE 1.3.2 CE 2.3.3 and CE 2.3.4 CE 3.2.2 PE2.4 Application of systematic approaches to the conduct and management of engineering projects I had designed reservoirs as per the organization project requirements CE 1.3.1, CE 1.3.1.1, CE 1.3.1.2 and CE 1.3.2 CE 2.2.3, CE 2.3.1, CE 2.3.2 and CE 2.3.3 CE 3.3.1.1, and CE 3.3.2 PE 3: PROFESSIONAL AND PERSONAL ATTRIBUTES PE3.1 Ethical conduct and professional Accountability I can communicate with others as well as with the companys chief authority for any meeting and discussion. I am enriched with both personal and interpersonal communication skills. CE 1.2.3, CE 1.3.3 and CE 1.4.1 CE 2.2.3, CE 2.3.5, CE 2.4.2 and CE 2.4.3 CE 3.3.3, CE 3.4 PE3.2 Effective oral and written communication in professional and lay domains I had also managed the tasks with my colleagues ability to work. CE 1.2.3, CE 1.3.3 and CE 1.4.1 CE 2.2.3, CE 2.3.5, CE 2.4.2 and CE 2.4.3 CE 3.3.3, CE 3.4 PE3.3 Creative, innovative and pro-active demeanor I had capacity of understanding the project as well with innovative approach of the implementation. CE 1.3, CE 1.4 and CE 1.5 CE 2.3, CE 2.4 CE 2.5 and CE 2.4.3 CE 3.2, CE 3.3 PE3.4 Professional use and management of information I understood ethical value of any project work with complete professional environment support. CE 1.2.3, CE 1.2.5, CE 1.4.2 CE 2.2.3, CE 2.2.5, CE 2.4.2 CE 3.2.3, CE 3.2.5, CE 3.4.2 PE3.5 Orderly management of self and professional conduct I had the ability to make out the teamwork as well with team leading and team collaboration. CE 1.4.3, CE 1.3.1.1 and CE 1.3.2 CE 2.4.3, CE 2.3.2, CE 2.3.3 and CE 2.3.4 CE 3.4.3, CE 3.3.1.1 and CE 3.3.2 PE3.6 Effective team membership and team leadership I had the professional ability of develop the project outcomes and all by myself. I also had several appraisements for my behaviour. CE 1.4.1, CE 1.4.3, CE 2.4.1, CE 2.4.3, CE 3.4, CE 3.4.1, CE 3.4.3 Bibliography Abdollahzadeh, A., Reynolds, A., Christie, M., Corne, D.W., Williams, G.J. and Davies, B.J., 2013. Estimation of distribution algorithms applied to history matching.SPE Journal,18(03), pp.508-517. Al-Hajeri, N. and Anthony, E., 2015, October. Tandem ESP-Packer Dumpflood Completion Application in North Kuwait Field-A Successful Alternative to Conventional Encapsulated ESP systems-Case Study. InSPE Kuwait Oil and Gas Show and Conference. Society of Petroleum Engineers. Al-Obaidy, R.T., Gringarten, A.C. and Sovetkin, V., 2014, October. Modeling of Induced Hydraulically Fractured Wells in Shale Reservoirs Using BranchedFractals. InSPE Annual Technical Conference and Exhibition. Society of Petroleum Engineers. Al-Shamma, B.R., Gosselin, O., King, P., Christie, M. and Mendez, M., 2015, June. 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