Campus | Start Date | Tuition/Fees |
---|---|---|
Moncton | September 2025 (Blended Delivery) | Domestic | International |
The Welding Engineering Technology (Co-op) program is designed to train learners in the weld design, analysis, and communication of industry quality procedures and technology. This diverse engineering discipline involves metallurgy, quality control, inspection, welding processes, power source technology, production procedures, and weld design. Graduates of this program gain the knowledge and skills to effectively communicate the varied practice of welding engineering technology to engineers, designers, and other stakeholders.
The program provides opportunities for learners to use modern equipment, software, and technology. Throughout the program, learners apply their knowledge of industry quality procedures, material science, metallurgical testing methods, fabrication technology, heat treatment applications, and possible failure modes of welds. Additionally, skills are developed in computer applications, communication, documentation, critical thinking, problem-solving, and teamwork to support the engineering activities of an organization.
The first year of training covers the basics of welding technology and assessing engineering drawings, codes, and specifications while applying industry standards to welding and steel fabrication. Immediately following the second term, learners engage in a capstone project which involves one week of preparation followed by a two-week applied steel fabrication project. In the second year of studies, courses specialize in advanced welding processes, metallurgical sciences, weld inspection methods, and weld design.
Dynamic work-integrated learning opportunities, teamwork, practical application, and capstone project presentation are aspects of this program. Graduates will be well-prepared for various career paths in the practice of welding engineering including effectively communicating quality control procedures and the applications of welding engineering technology.
The requirements for this diploma program may be achieved within two years of full-time study.
Profile B
NB Francophone High School Math Equivalencies
International Student Admission Equivalencies
Graduates of this program gain employment in a wide range of technical and industrial positions related to the design, maintenance, development, and quality control of welding engineering principles, processes, and systems. Employment could be gained in various sectors including civil engineering, mechanical, industrial machinery, pulp and paper, hydropower generation, mining, petrochemical, and construction.
Graduates of this program may find employment as engineering assistants, welding inspectors, laboratory technicians, welding consultants, welding instructors, robotic welding programmers, and welding foremen or supervisors in various areas.
Technology Requirements
ÐÇ¿Õ´«Ã½ is a connected learning environment. All programs require a minimum specification, including access to the internet and a laptop. Your computer should meet your program technology requirements to ensure the software required for your program operates effectively. Free wifi is provided on all campuses.
Courses are subject to change.
This course is designed to help students strengthen their fundamental skills in writing clear, effective sentences and paragraphs, and enable them to create organized, unified and coherent documents. The writing process is introduced. Students will recognize the importance of writing for the intended purpose and audience.
This course introduces students to the fundamentals of technical writing and research. Students will learn how to write a variety of technical documents and business correspondence suitable to a specific audience and purpose as well as learn how to conduct research and document sources.
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This course introduces students to ethical principles and codes of conduct applicable to Professional Engineering Technology practice. It prepares students for being engineering technology professionals by exploring critical thinking, ethical behavior, and the legal and professional accountabilities that apply in the workplace. The industry's code(s) of ethics and practical case studies are used as the learning focus.
Learning is achieved through lectures, case studies, and team projects.
The overall program goal of the co-op experience is to complement academic studies with related work experience. Co-op students can gain enriched understandings of their academic program through practical application. Moreover, the co-op experience can motivate students to further education as well as lead to relevant employment after graduation. Through their work experiences, students will develop and refine employability skills, gain an understanding of career opportunities in their field, and realities of the workplace. Students are required to follow guidelines as stipulated in the “ÐÇ¿Õ´«Ã½ Co-op Education” process.
This course is the first phase of the Work-Integrated Learning (WIL) capstone projects in Welding Engineering Technology. This course provides learners with an opportunity to work with a team on a selected engineering project. The goal of the work-integrated learning experience is to complement academic studies with real-world application. Learners gain practical experience through supervised, and industry partner involvement. Learners will integrate the knowledge and skills acquired during the program to develop a project scope, identify the necessary documentation based on industry standards, and submit it for instructor and industry partner approval. Upon instructor approval, learners will design, and develop a project plan that outlines the specifications and tasks to be completed in time and within the budget for the proposed project. Learners are expected to produce deliverables and project management documents based on the project plan to facilitate the second and third phases of the capstone project.
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This course is the second phase of the Work-Integrated Learning (WIL) capstone projects in Welding Engineering Technology. Learners will evaluate their project plan in the previous course, ETTG1038, and follow workplace safety procedures to complete their applied project work. This capstone project offers learners the chance to put their year one coursework into practice by creating a weldment that meets specific welding standards, delivering quality assurance throughout. Through this capstone project, learners gain valuable preparation for real-world scenarios in the fabrication field. Following completion of the metal fabrication project, learners will deliver a presentation outlining objectives, methods, and outcomes.
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This course is the third phase of the Work-Integrated Learning (WIL) capstone projects in Welding Engineering Technology. This course is a continuation of the capstone projects: Welding Engineering Technology I and Welding Engineering Technology II. Learners will analyze, organize, and combine findings to complete a finalized report. Following completion of the capstone project, learners will deliver a presentation to relative industry partners.
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This course is designed to provide learners with the skills and strategies for managerial and supervisory roles within various industries. Throughout the course, learners will examine key topics such as effective communication, motivation, performance management, and leadership development.
This course is designed to study the codes and specifications relevant to the welding industry in Canada. Learners research code-related solutions to identified industrial situations and, through this, they will recognize how regulatory systems serve to create a framework for establishing and maintaining an environment that is safe, resilient, sustainable, and efficient.
This course is designed to study codes and specifications relevant to the welding industry internationally. Learners research code-related solutions to identified industrial situations and, through this, they will recognize how regulatory systems serve to create a framework for establishing and maintaining an environment that is safe, resilient, sustainable, and efficient.
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This course is designed to introduce the metallurgical engineering discipline of materials science, emphasizing the metallurgical principles governing the characteristics and properties of metals following exposure to different heating and cooling rates. Learners will gain knowledge of heat treatment procedures, phase diagrams, and mechanical tests used to identify various types of metals and their respective properties. Additionally, learners engage in calculating rates of expansion and contraction while also examining strategies for controlling distortion.
This course provides learners the opportunity to perform a range of metallurgical testing to identify physical and mechanical properties of metals. Learners will conduct mechanical tests mandated by industry codes/standards, which is crucial for generating Procedure Qualification Reports (PQRs), pivotal documents in the welding and fabrication sector. Through laboratory experiments using metallographic techniques, learners will identify steel microstructures, examine the various zones of a weldment, and create technical reports that reflect the objectives and outcomes of each lab experiment.
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This course is designed to instruct learners about the metallurgical principles governing the behavior of metals under various (stress) conditions caused by loading, atmospheric factors, welding, and heat treatment methods. Topics include the relationship between metal structure and mechanical properties across diverse manufacturing processes, the weldability of different metals, and the effects of heating and cooling on microstructure and mechanical properties. Learners will also be exposed to the fundamental principles of failure analysis.
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This course provides learners the opportunity to perform various weld inspection methods to ensure quality, safety, and reliability. Learners will develop non-destructive examination (N.D.E.) procedures to determine material/product compliance as regulated by industry codes/standards. Reports will be generated to detail the results and outcomes of each laboratory exercise.
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This course is designed to provide learners with a comprehensive understanding of the material classification systems and their pivotal role in upholding quality and integrity within the fabrication industry. Learners will be introduced to various classification and numbering systems that categorize metals and alloys based on their composition, properties, and characteristics.
This knowledge will enable the learner to effectively communicate with engineers, designers, and manufacturers involved in fabrication processes and/or the various stakeholders within the metals industry.
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This course forms the foundations of technical mathematics. Topics covered include fundamental numerical calculations, manipulation of algebraic expressions, and solving equations, system of equations, and word problems. Learning is achieved through lectures, classroom examples and working out problems.
This course is designed for students to learn more advanced algebra, trigonometry, and geometry. Topics include quadratic equations, trigonometry, logarithms, and vectors.
Learning will be achieved through lectures and classroom examples and work. Learning is achieved through lectures and in-class activities.
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This course provides an introduction to the meaning of community service. Students learn how community service can enhance a student’s educational experience, personal growth, employability, and civic responsibility. Students participate in one day of volunteering to enhance their understanding of civic responsibility and to help the New Brunswick Community College realize its vision of transforming lives and communities.
This workshop introduces students to the process of finding employment. It explores the various strategies and resources available, and examines the role of social media.
This course is designed to provide learners with fundamental skills in blueprint sketching and interpretation, equipping them with essential skills to extract vital information from blueprints effectively. Additionally, the course will introduce learners to the proper dimensioning techniques of various structural shapes.
This course is designed to provide learners with the knowledge and skills required to understand the specifics of diverse types of structural engineering drawings. Learners will gain insight into the correct steel erection techniques necessary to uphold quality assurance standards throughout the steel erection process.
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This course is designed to provide learners with the knowledge and skills required to conduct quality control measures to ensure the integrity of welds. This course introduces various forms of non-destructive examination techniques. Learners will perform visual inspection using quality control procedures to determine any discontinuities deemed unacceptable to applicable standards. Learners also make use of codes and standards to identify any necessary corrective actions.
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This course introduces students to basic computer applications and tools that are integral to all engineering disciplines, including word processing, presentation, spreadsheet, and electronic file management and data sharing.
Students learn how to select and use appropriate computer applications to perform tasks such as research, data analysis, data presentation and sharing, and preparation of technical documents and reports within their discipline. An emphasis is placed on the data security, and safe use and management of files in a collaborative networked environment. Learning is achieved through practical application of skills during hands-on class activities and assignments.
A safe and healthy workplace is the responsibility of the employer and the employee. This course introduces students to the importance of working safely and addresses how employers and employees can control the hazards and risks associated with the workplace. Students will also learn about the roles and responsibilities of key stakeholders including WorkSafeNB, the employer and the employee in ensuring workplaces are safe.
This course is designed to provide learners with the essential knowledge and skills to craft a test plate assembly meeting industry standard proficiently. An emphasis is on understanding welding symbols and abbreviations, alongside mastering fabrication industry best practices for interpretation and application. Practical instruction is on safely and effectively utilizing diverse material preparation equipment.
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This course provides a comprehensive introduction to the fundamental principles and techniques of metal fabrication. With a primary focus on safety protocols, learners effectively select, utilize, and maintain hand and power tools essential to the fabrication process. Learners will gain hands-on experience operating various metal fabrication machinery, such as power shears, press brakes, and rolling equipment enabling them to develop practical skills crucial for success in this field.
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This course explains the various principles of the shielded metal arc welding process and the basic welding power source operation. The emphasis is on safety practices, and the operating principles of equipment, electrical theory, and testing.
This course provides learners with the knowledge and skill to safely perform basic Shielded Metal Arc Welding (SMAW) techniques and conduct basic destructive testing to identify weld quality. This course is designed for learners to apply the various aspects of the welding process including correct manipulative skills and welding techniques. Learners are also exposed to basic multi-meter operation to maintain proper electrode conditions.
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This course is designed to introduce learners to the gas metal arc welding (GMAW) process. An emphasis is placed on utilizing safe practices and procedures of GMAW equipment. Learners also acquire knowledge in consumable selection, process application, and the various modes of metal transfer.
This course is designed to extend knowledge and skill of gas metal arc welding (GMAW) and provide opportunities for learners to establish the proper manipulative skills to achieve quality welds.
This course also introduces the following welding processes: flux-cored arc welding (FCAW), metal-cored arc welding (MCAW), and gas tungsten arc welding (GTAW). Learners apply the principles of each welding process including equipment setup and consumable selection.
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This course is designed to instruct learners on the operational principles and safety procedures of modern/advanced welding applications. The course blends theoretical knowledge with extensive practical training to determine the best practices to produce quality weldments. Topics include inverter power sources, welding consumables, and process applications. An emphasis is placed on understanding the complexities of each process and applying them to achieve precise and reliable welds. Learners create technical reports that reflect the objectives and outcomes of the weld applications.
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This course provides the skills to safely operate, program, and edit weld schedules and procedures associated with mechanized/automated welding equipment. The course blends theoretical knowledge with extensive practical training to determine the best practices to produce quality weldments. Topics include Submerged Arc Welding, welding robotics, and Orbital Gas Tungsten Arc Welding. Learners create technical reports that reflect the objectives and outcomes for each lab experiment.
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62100 - Technical sales specialists - wholesale trade
90010 - Manufacturing managers
Institution: University of New Brunswick Saint John - Faculty of Business
Information: Bachelor of Applied Management Degree
ÐÇ¿Õ´«Ã½ graduates of any 2 year diploma program with a GPA of 70% or greater receive 2 years full credit toward this degree and will be eligible to enter year 3 of the 4 year Bachelor of Applied Management (BAM) program.
Welding Engineering Technology (Co-op) graduates may have an opportunity to acquire the following external certifications upon meeting the external agencies certification requirements and paying any required fees to the external agency:
Institution: NBSCETT - New Brunswick Society of Certified Engineering Technicians and Technologists
External Certification: Professional Technologist
Information: Certification by the New Brunswick Society of Certified Engineering Technicians and Technologists.
Disclaimer: This web copy provides guidance to prospective students, applicants, current students, faculty and staff. Although advice is readily available on request, the responsibility for program selection ultimately rests with the student. Programs, admission requirements and other related information is subject to change.