Keywords

1 Introduction

The globalisation of markets and rapid changes experienced by the industry through digital transformation are bringing significant changes in how to design and manufacture products, where the collaborative engineering plays an essential role.

The use of PLM tools to manage lifecycle is essential to achieve success and more and more of European companies increasing use of them. As a result demand has heightened significantly over the last several years. However, lack of professional skilled specialized in this area in order to respond companies requirements is limited.

In Spain, nowadays the use of PLM is based on different roles associated to several CAx PLM tools. However, does not exist a role or a specific profile such a PLM engineer to interact with the different tools each other and customize them according to business models requirements.

Actually, many of PLM courses are focus on the design of products and processes, using the standard configuration provided by software default. However, it is very difficult to find any company whose needs can fit the software.

The new generation of PLM systems allows a great customization and parameterization, enabling its adaptation to any business process and company. This competence has not been exploited, although it more is demanded every day.

Based on this problematic, arise an initiative to include in engineering studies subjects related to PLM Systems where collected fundamental requirements that should fulfill a PLM engineer to design and customize the systems according to business requirements.

The following paper describes the design, deployment and results achieved of introduction and customization PLM skills into aeronautical education engineering. The desired aim are cover knowledge:

  • Concepts and fundamentals of the PLM systems and its interaction with engineering

  • PLM Tools & customization

  • A use case based on acquired skills

  • Evaluation methods

This paper is organized as follows. Section 2 introduces others experience into PLM training into higher education, it focus on skill and curriculum. Section 3 describes competence or skills, design of contents, hardware architecture and evaluation method. Section 4 shows the deployment experience and the results. Finally, the paper presents the conclusions obtained.

2 Pedagogical Renewal. PLM & Industry 4.0

PLM systems are solutions that seek to manage the product life cycle and allow the companies connect all information improving the operational efficiencies as well as working faster (recovery and exchange of electronic information, reuse of data, automated capabilities, and data security).

PLM is not only a software. When a PLM System is described, must support business solutions in collaborative creation, management and product and process definition. In Industries PLM is commonly used for:

  • Centralize and organize product data

  • Design & management product development projects

  • Integrate design process & industrialization

PLM systems aim to connect and cover the entire cycle of a product (From conception to market debut). A set tools that provide a platform through a collaborative environment to optimize flow and information Exchange between different actors involved in lifecycle.

To achieve this purpose, these tools have the ability to customize and model their data, which allows companies to adapt them according to the different requirements of the business [7].

Currently, this is a gap to cover nowadays between industry and PLM systems. The lack of consultants and training engineers in this area makes it difficult a correct implementation and execution of PLM systems in a company.

From different educational institutions as well as PLM software companies are beginning to promote the use of CAX-PLM tools through subjects and training courses focusing on using tools to became a professional PLM engineer.

With that aim, in 2016 the project named ‘Accelerating the adoption of Industry of the Future (IoF) supporting technologies by Spanish universities’; was launched. It is an educational project, with a focus on manufacturing related competences and partially funded by La Fondation Dassault Systèmes [10].

Current educational cases dealing with CAX-PLM technologies in some spanish universities:

  • University Jaume I of Castellón. The educational model is based on projects or module assignments that integrate several courses. This case comprises a training module on the methodological use of CAX applications, integrating the product design and development process with a PLM application to support the collaborative teamwork [11, 12].

  • University of Cádiz. The I4.0 support technologies dealing with CAD/CAM/CAE and PDM/PLM systems are within the scope of the Manufacturing Processes Engineering Area [10].

  • Polytechnic University of Madrid – Industrial Engineering School. Currently, in the Degree and Master studies, only different CAX applications are used in different courses.

Therefore, there is no an integrating solution, based also on the use of a PLM system and the customization, that allows students developing a multidisciplinary collaborative project.

The aim of the project called ProVerStand (“Produktentwicklung über Verteilte Standorte” – “Product Development Involving Distributed Locations”) is to provide universities and similar institutions access to state of the art PLM systems, such as PDMS, CAE and CAD [4]. The Project defines a PLM scenario from preparatory level to master level (Fig. 1).

Fig. 1.
figure 1

PLM education scenario [4]

Research Institute of Aoyama Gakuin University in Japan has developed effective educational curriculum. The goal of this lesson is an understanding of effective PLM when a new product is developed using e-Learning as the educational tool [6]. The training focus on the business processes in PLM, designs the curriculum of the PLM education by e-Learning.

The content is structure in 5 subjects where it develop the following concepts: Product Design (EBOM), production design (Layout & systems production) production management (MRP, Material Requirements Planning) and process design.

The faculty at Purdue University has been working together to reform existing PLM-related courses. The new curriculum provides three courses at junior years to build a student’s basic PLM knowledge and skill sets and two senior level electives course based on project-based learning environment to help the students synthesize what they have learned during the past academic years [3].

The importance of include trends of industry 4.0 in the engineering training, is reflected in different courses in several European universities: the polytechnic university of Torino [2] developing courses around the framework Small Factory Project. The courses focus on training the students in ERP and PLM tools.

The HSR (university of applied science of Rapperswil) [13] covers trends of industry 4.0 & digitalization based on a scenario around the product using very common technologies (Lego, Arduino, etc.) and IT tools (PLM, CAD, ERP, etc.)

Finally, it is note that in the literature review a training destined to customize PLM system based on customer requirements was not found.

This gap is taken advantage for design and implement a new subject with a first approach to cover these requirements.

3 Design and Development of a PLM Subject

The incipient demand on PLM & Industries 4.0 has seduced students and therefore engineering schools to include PLM training in their curricula. All this is encouraged because the A400M program will further strengthen the importance of Andalusia (in the south of Spain) as one of the country’s main aerospace-production regions. The all-new A400M military aircraft made its first flight from Andalusia’s Seville San Pablo Airport after its assembly at the EADS CASA factory, the third largest Airbus production plant in the world.

The Andalusian aerospace cluster is composed of 117 companies (engineering and consulting 18.8%), generating 14.463 direct jobs. Where 26% are highly qualified employees (Engineers).

This environment has led to develop an optional subject in the aeronautical engineering master degree at the University of Sevilla. In order to provide students of cross-cutting skills to plan, design, manage & certification procedures, infrastructures and systems that support the aerospace industry with activities related to industry 4.0. As well as specific skills related to use and customization of PLM tools focus on development of business in professional field.

As a prerequisite, the student must be graduated in an engineering field and is highly recommended possess knowledges of data modeling and production management.

With a total of 125 h distributed as face-to-face classes and cooperative homework, the subject is divided into two blocks:

  • Theoretical classes: teaching class 25 h (face to face) and 50 h analysis and study (non-presential)

  • Computing practices: teaching class 15 h (Face to face) and 35 h (non presential)

The structure of the subject is divided in four large modules. Each module in turn, is structured into theoretical and applied sub-modules. The first one, is composed by an introductory part and general concepts associated with the relevant module and the second one by a practical part. In such a way that the student progressively acquires the skills necessary for each of them.

Module 1: Product Lifecycle Management in Aerospace Industry.

Theoretical part:

Introduction and basic concepts about product lifecycle. Differences between sequential engineering and concurrent engineering and first approach concept of collaborative engineering across PLM systems. Definition of PLM system and their relationship with the Industy 4.0.

Practical part:

Analyze and develop with a project management tool a collaborative framework collecting the following aspects:

  • Project management

  • Teamwork management

  • System virtualization concept, software and PLM architecture

Module 2: PLM System in Aerospace Industry

Theoretical part:

Introduction and concepts about PLM Systems in aerospace industry. Programs and projects management in aerospace industry. Main activities:

  • Planning, managing and controlling

  • Organizational structure OBS and Work Breakdown Structure Work.

  • Requeriments management & product specification.

Practical part:

Design and modeling an aerospace program with several projects associated with a PLM tool where it is collected the following aspects:

  • Analysis of requirements associated with the project

  • OBS (Organizational Breakdown Structure) the structure of the project

  • Analysis and modeling users permissions in the tool

  • Creation of identities

  • Modify permissions and users

  • Update items and relationships

  • Allocation and configuration of roles in the teamwork

Module 3: Product Data Management

Theoretical part:

Introduction and concepts of industrial digital mock-up (iDMU, [9]): 3D virtual prototypes and information contain. Product data management: concept of BOM, EBOM, MBOM. Configuration management, versions and variants & Product lifecycle management.

Practical part:

Design and modeling a product lifecycle with a PLM tool where it is collected the following aspects:

  • Set the product lifecycle & models

  • Products and models creation

  • Definition states and permission associated with states

  • Creation of bill of material BOM

  • Creation new attributes

Module 4: Process Data Management in PLM Environment

Theoretical part:

Introduction and concepts about virtual product and collaborative design. Definition of a process management data and process plan. The concept of PPR (Product, Process, Resource) structure and data explode in the manufacturing area (Work instructions and Maintain Resource Operation).

Practical part:

Design, modeling and adapt a process plan in a PLM tool where it is collected the following aspects:

  • Setting up the environment to include the concept of PPR in a tool

  • Design data model and implementation of a classical PPR structure and relationships between Product, Process and Resource)

4 Case Study. Configuration & Customization a PLM Tool

4.1 Architecture Software

For the implementation and development of practices, it is necessary to set up an infrastructure allowing the student to interact with the different tools in a collaborative framework through two main systems: a production system that allows students to work in a collaborative environment for the implementation project and a development system, through a virtual machine in each student machine for developing and testing solutions. Previous implementation in the productive system (Fig. 2).

Fig. 2.
figure 2

Architecture software

4.2 Software and Material Support

The Information systems, material and complementary information used in practice are described below:

  • ARAS INNOVATOR is a software, which offers integration services for PLM and PDM solutions on a single platform.

The structure is divided in 3 mains modules:

  • PLM to manage processes throughout the life cycle

  • PDM to manage CAD data: product, part and documentation

  • PLATFORM to adapt, extend and build applications

  • Redmine is a free and open source, web-based project management and issue tracking tool. It allows users to manage multiple projects and associated subprojects. It features per project wikis and forums, time tracking, and flexible, role-based access control. It includes a calendar and Gantt charts to aid visual representation of projects and their deadlines. Redmine integrates with various version control systems and includes a repository browser and diff viewer [5].

  • A Lego helicopter model 6745-H, composed by 247 pieces, to define the assembly process (6745 Model Propeller, [1]). The implementation must be defined in the Aras Innovator tool under the Schema control of the production model defined as well as Lego designer software tool (Lego Designer, [8]), a free software available for mac and windows to design through the pc any Lego assembly.

4.3 Rubric Evaluation

A rubric is typically an evaluation tool or set of guidelines used to promote the consistent application of learning expectations, learning objectives, or learning standards in the classroom, or to measure their attainment against a consistent set of criteria. In instructional settings, rubrics clearly define academic expectations for students and help to ensure consistency in the evaluation of academic work from student to student, assignment to assignment, or course to course.

The rubric applied has 9 points. From 1 to 6 evaluate the PLM skills achieve in the subject. The 7th and 8th point is an optional section to increase marks and the last point evaluates project management skills.

The practical part is developed in groups. The groups consist of a minimum of 3 students and a maximum of 4. Each group defines a project manager who manages and monitors tasks for a satisfactory conclusion.

1st point collected the sections related to the OBS structure and will be assessed the following aspects

  • User definition: the student must define different roles.

  • Teamwork definition: the student must define different groups that share common functions.

  • Permission definition: The student must define permissions according to the role, lifecycle and data type associated.

2nd point collected the sections related to the program & project management and will be assessed the following aspects

  • Program definition. The student must define at least one program and define lifecycle (state, transition) and the users and permissions involved.

  • Project definition. The student must define a project based on a template that should be extended with tasks and activities. The project must be associated with a model as well as a life cycle and access permissions.

3rd point includes paragraphs related to the customization of a PLM tool

  • Parts and Products definition: the student must define new attributes to the structure of a Part, identify the types of parts and design forms & new attributes.

  • Definition of the life cycle: the student must design a cycle of life for each item type as well as the permissions and allocation of transitions.

4th point includes the concept of EBOM (As Design concept)

  • Definition of the EBOM where the student must design the product structure with a LEGO model and implementation into PLM System.

  • Definition the Vault File concept applying import and export data associated to parts.

5th point. It is used to define the Manufacturing model (as planned and as prepare structure), design of the manufacturing structure (MBOM)

  • Definition and design manufacturing parts, implementing the idmu data model into PLM system.

  • Definition of the MBOM structure for 6745 Lego propeller model. The student must incorporate new structures in the PLM tool (processes and resources) as well as define their lifecycle, forms and relationships between elements (structure PPR).

6th point. Documentation of the technical evaluation report: the student must upload documentation associated with the project that reflects the following aspects:

  • Introduction and objectives

  • Scope

  • Analysis and requirements capture

  • Design

  • Implementation

  • Tests

  • Conclusions

  • Extensions

7th point an alternative option for students. It evaluates the automatic software programming included into PLM System. For example, develop import and export data in batch modes.

  • Definition data model. Description of the level of implementation of the description of the procedures.

8th point: included aspect related to extensions where the student puts to the test the skills acquired going a step and beyond.

  • Design and implementation Work Instruction.

  • Engineering change order. Definition business process to change management.

  • Effectivities

9th point collected aspects of project management. To know the activities done by students in the subject.

  • Work distribution. Hours to develop task.

  • Task type distribution. Balanced work distribution by rubric point.

  • Analysis learning curves. Evaluation of group members.

4.4 Results

In the literature review, the experience is focusing on describing content and skills acquired by the students.

This experience starts in 16/17 academic year. The following table describes the level of achievement in percentage (by work team) of competencies acquired by students (Fig. 3).

Fig. 3.
figure 3

Comparative table (expressed as a percentage)

The results reflect that all Works teams have acquired 75% of competences defined. Likewise, these competencies have been achieved completing over 80% of activities.

On the other hand, software development skills that involves using customization PLM Tools and not included in theoretical lessons and practices, have not been achieved. One of the possible causes is the dedication time at developing competences and skills. The average dedicated by the Works teams was 156 h; 45 h theoretical-practical and 116 for developing out of classes.

A disaggregate analysis, student by student, shows that the workload is balanced. The difference between the hardworker is around 11% while the deviation respect from the average stands is about 8%. The work division has been balanced (deviation less than 15%).

5 Conclusions

This paper has described the development and results of the implementation of a subject oriented towards the acquisition of skills in the customization of PLM systems. A very demanded area nowadays by companies and not included in the current aeronautical engineering curricula.

During the design and the planning stages of the subject, several doubts emerged about the reception from the students as an optional subject with unknown content.

However, the result reflected in the information systems of the University of Sevilla through satisfactions surveys, shows that not only the subject has well accepted by the students but also the number of students has doubled respect from the last course and assessed positively in the study plans.

Finally, another important factor to consider and perhaps the most important from the point of view as educator have been the result reflected in the workload required to the student outside school hours. It can be observed the similarity between the estimated and actual hours in the study plan and how the most of students have achieved the aims and competences successfully.