By
Timothy G. Clapp, Ph.D., P.E.
Professor
College of Textiles
North Carolina State University
Raleigh, NC 27695
(919) 515-6566
tclapp@tx.ncsu.edu

Michael S. Slocum, Ph.D.*
Principal and Chief Scientist, The Inventioneering Company
2820 Drake Avenue
Costa Mesa, CA 92626
(714) 641-0677
slocum1946@aol.com
(* Adjunct Assistant Professor
North Carolina State University
Raleigh, NC 27695)

The tasks of the educator are of supreme importance as the next generation of engineers relies on the training and skills imparted to equip them for the challenges in the ever-changing competitive industrial environment. It is with this in mind that the integration of the Theory of Inventive Problem Solving (TRIZ) into existing engineering curriculums was considered. TRIZ problem solving methods are especially suited for rapidly, identifying innovative solutions that are more robust and more economical than conventional problem solving methods [1][2][3[4].

Since the introduction of TRIZ methods in the United States in 1991, only limited efforts have been undertaken to introduce TRIZ into the engineering academic curriculums [5][6]. The authors sought to develop a system for incorporating TRIZ into the Textile Engineering curriculum at NC State University in the Fall of 1998 [7].

This paper addresses the first phase of the systematic integration of TRIZ into the Textile Engineering curriculum in a senior-level engineering design capstone course. An existing senior design class was selected by the authors to eliminate potential problems of adding a separate course, which would add additional credit hours to an already crowded curriculum. Most importantly, the integration enables the student to understand the proper perspective of this methodology in respect to other traditional engineering methods. TRIZ and the perception of it as a panacea is avoided and the coordination of the methodology with value engineering, robust design, Pugh concept selection, failure mode effects analysis, etc.,…, is clearly defined. Problems from industry assigned to teams of students provided scenarios for the application of the methodology as it was taught. The theory’s place in the concept generation phase as well as the problem resolution phase is obviated. Exercises that require the integration of the theory into existing design practices reduce the theory to practice and reinforce the power of the methodology. We have found these interrelations to be critical to the success of the introduction of the theory. The integration is indicated by the curriculum outlined in Table 1.0.

1	Syllabus, Pre-evaluation
	Introduction to Engineering Design
	Information Gathering (Library, Internet)
2	Industrial Problems Presented
	Structure of the Design Process
	Team Fundamentals
3	Understanding the Problem: QFD
	Understanding the Problem: Process Flow Chart
	Forming the Entrepreneurial Company
4	Defining the Technical Problem
	Team Training Exercises
5	History of Innovation, Introduction to TRIZ
	TRIZ Continued
	Team TRIZ exercises
6	TRIZ Software: Problem Analysis Module
	Ideal Solution Generation (Principle of Ideality)
	Team Idea Generation (Brainstorming)
7	TRIZ Software: Generating Solutions
	Evaluating Alternatives (Pugh Analysis)
	Team Performance Checks
8	Proposal Preparation
	Oral/Written Communication in Industry
	Proposal Preparation
9	Team Presentation Preparation
	Formal Presentation
10	Design Lecture-Detailed Designs
	Presentation feedback
	Anticipatory Failure Determination (AFD)
	Application of AFD to Team Projects
	Industrial Feedback
12	Business Ethics
	Team Progress Review
	Sensor Technologies
13	Team Progress Review
	Relay Ladder Logic, PLC’s,
	Special Individual Project (SIP)
14	SIP Lab Activity
	SIP DUE, Team Activity Report Due
15	Design report/presentation Preparation
	Design report/presentation Preparation
16	Design report/presentation Preparation
17	Exam Week-Presentation

The curriculum in Table 1.0 reflects the material that will be covered during the first half of the design engineering course. The lectures given and their respective durations are listed in Table 2.0.

Lecture	Sub-lecture(s)	Duration	Applicability
Introduction and Overview	History of Innovation Psychological Inertia Ideality 40 Principles	2 hours	used these principles in senior project
Contradiction Matrix Theory	Physical contradiction (PC) Technical contradiction (TC) TC-to-PC conversion Separation principles (SP) 40 Principles and reversibility 39 Parameters Contradiction matrix	2 hours	used this theory to formulate problems associated with senior design project
Function Analysis	Function analysis Su-Field introduction	2 hours	performed function analysis using TOPE 3.0 of senior design project
Introduction to Directed Evolution	S-curve Trends of Evolution Maturity mapping	2 hours
Review of previous 4 lectures		2 hours
Anticipatory Failure Determination	Failure Analysis Failure Prediction	2 hours	performed AFD on existing designs of senior project to eliminate and mitigate failure modes

The lectures were supplemented by assigning tasks designed to reinforce material presented in a format that was directly related to the engineering projects assigned the class. This series of lectures will be augmented by several additional series to complete the presentation of the basic body of TRIZ knowledge. The use of the theory will also be expanded from the concept development stage (the primary goal of the first half of the course) to the reduction to practice stage. Many insights are expected during this transition from theoretical application to experimental activity.

The reactions of the class were positive in the following senses: 1) questions were asked to elucidate portions of the theory that needed further elaboration, 2) many technical contradictions and physical contradictions were presented that were applicable to assigned design projects and discussions concerning proper framing were very active (real-world concerns were addressed), 3) the function analysis lecture was followed by the creation of a function model as a team (the synergy of the team coupled with the complications associated with function diagram creation were ideal for a thorough understanding of the processes involved), and 4) many side-bars were experienced after lecture completion for students who evidenced advanced curiosity. We consider these activities to be indicators of successful delivery. Table 3.0 indicates the performance increases in solution generation realized post lecture delivery. Table 4.0 indicates team performance on their senior projects in the areas of component reduction, cost reduction, number of solutions generated, and potential patents.

	Component reduction	Cost reduction	Solutions generated	potential patents
Group I, 6 students	35%	40%	37	1
Group II, 6 students	35%	44%	13	2
Group III, 7 students	40%	11%	21	1

Average	37%	32%	24	1.33

In conclusion, Tables 3.0 and 4.0 reflect several important issues: student acceptance, student application (increase in number of innovative solutions, project component reduction, project cost reduction, and potential patents), and realization of relevancy. A number of the students have expressed interest in taking a course dedicated to TRIZ. Phase II of this project is comprised of detailed design of their respective (Groups I-III) projects. The usage of Anticipatory Failure Determination (failure prediction) will be presented in the next report. The detailed design activity will reveal additional problems that will be addressed using the material presented to date. These secondary problems will be reported on as well.

question	percent
solution increase using TRIZ	30
solutions more innovative	>70
TRIZ will be used in other fields by student	>85
TRIZ relevant to project	>85
used Ideal Final Result to improve design	>60

Theory of Inventive Problem Solving Pedagogy in Engineering Education, Part I

Theory of Inventive Problem Solving Pedagogy in Engineering Education,
Part I