production & operation management
DESCRIPTION
PRODUCTION & OPERATION MANAGEMENT. PRODUCT DESIGN TOOLS By PRAMOD KUMAR BISWAL PRAFUL KUMAR YASHPAL SINGH RAHUL KUMAR. PRODUCTION & OPERATION MANAGEMENT. PRODUCT DESIGN TOOLS QUALITY FUNCTION DEPLOYMENT VALUE ANALYSIS THE TAGUCHI METHOD COMPUTER AIDED DESIGN - PowerPoint PPT PresentationTRANSCRIPT
PRODUCT DESIGN TOOLSBy
PRAMOD KUMAR BISWALPRAFUL KUMARYASHPAL SINGHRAHUL KUMAR
PRODUCT DESIGN TOOLS
QUALITY FUNCTION DEPLOYMENT VALUE ANALYSIS
THE TAGUCHI METHODCOMPUTER AIDED DESIGN
DESIGN FOR MANUFACTURABILITY AND DESIGN FOR ASSEMBLY
&PROTOTYPING
• THE MAIN OBJECTIVE OF A PRODUCT DESIGNER IS -
• TO REDUCE PRODUCTION COST.• TO DECREASE PRODUCT DEVELOPMENT
TIME.• TO IMPROVE QUALITY OF THE PRODUCT .• SEVERAL TOOLS AND METHODS HAVE BEEN
DEVELOPED TO HELP A PRODUCT DESIGNER TO IMPROVE PRODUCT QUALITY AT A LOWER COST.
• AN IMPORTANT ASPECTS OF PRODUCT DESIGN IS TO IDENTIFY CUSTOMERS PREFERENCE WITH RESPECT TO PRODUCT FEATURES AND CONVERT THEM INTO APPROPRIATE TECHNICAL AND DESIGN ATTRIBUTES.
• A STRUCTURED METHOD(QFD) FOR DOING THIS WAS FIRST DEVELOPED BY PROFESSOR YOJI AKAO IN JAPAN IN 1966.
QUALITY FUNCTION DEPLOYMENT (QFD) IS A “METHOD TO TRANSFORM USER DEMANDS INTO DESIGN QUALITY, TO DEPLOY THE FUNCTIONS FORMING QUALITY, AND TO DEPLOY METHODS FOR ACHIEVING THE DESIGN QUALITY INTO SUBSYSTEMS AND ITS COMPONENTS, AND ULTIMATELY TO SPECIFIC ELEMENTS OF THE MANUFACTURING PROCESS.” [
• FIRST CONCEPTUALIZED IN 1966 AS A METHOD OR CONCEPT FOR NEW PRODUCT DEVELOPMENT BY PROFESSOR YOJI AKAO.
• QUALITY FUNCTION DEPLOYMENT (QFD) IS USED TO TRANSLATE CUSTOMER REQUIREMENTS TO ENGINEERING SPECIFICATIONS
• IT FORMS A LINK BETWEEN CUSTOMERS - DESIGN ENGINEERS - COMPETITORS - MANUFACTURING.
• IT IS VERY MUCH POWERFUL AS IT INCORPORATES THE VOICE OF THE CUSTOMER IN THE DESIGNS - HENCE IT IS LIKELY THAT THE FINAL PRODUCT WILL BE BETTER DESIGNED TO SATISFY THE CUSTOMER'S NEEDS
• QFD IS APPLIED IN THE EARLY STAGES OF THE DESIGN PHASE SO THAT THE CUSTOMER WANTS ARE INCORPORATED INTO THE FINAL PRODUCT
QFD HELPS DESIGNER IN:-• UNDERSTANDING 'TRUE' CUSTOMER NEEDS
FROM THE CUSTOMER'S PERSPECTIVE .• UNDERSTANDING HOW CUSTOMERS OR
END USERS BECOME INTERESTED, CHOOSE, AND ARE SATISFIED.
• ANALYZING HOW DO WE KNOW THE NEEDS OF THE CUSTOMER
DECIDING WHAT FEATURES TO INCLUDE . DETERMINING WHAT LEVEL OF
PERFORMANCE TO DELIVER . HENCE IT LINKS THE NEEDS OF THE
CUSTOMER WITH DESIGN, DEVELOPMENT, ENGINEERING, MANUFACTURING, AND SERVICE FUNCTIONS .
• A COMPREHENSIVE QFD INVOLVE FOUR PHASES:
• PRODUCT PLANNINGTRANSLATE CUSTOMER REQUIREMENT INTO PRODUCT TECHNICAL REQUIREMENTS TO MEET THEM.
• PRODUCT DESIGN TRANSLATE TECHNICAL REQUIREMENTS TO KEY PART CHARACTERISTICS OR SYSTEMS
• PROCESS PLANNING IDENTIFY KEY PROCESS OPERATIONS NECESSARY TO ACHIEVE KEY PART CHARACTERISTICS.
• PRODUCTION PLANNING (PROCESS CONTROL): ESTABLISH PROCESS CONTROL PLANS, MAINTENANCE PLANS, TRAINING PLANS TO CONTROL OPERATIONS.
CUSTOMER REQUIREMEN
T
IMPORTANCE
TECHNICAL ATTRIBUTES
CASE MATERIAL
BATTERY TYPE/SIZE
SCREEN TYPE/SIZE
RAM CAPACITY
HARD DISC TYPE/SIZE
KEY BOARD TYPE/SIZE
LIGHT WEIGHT 4.5 • ° • • • •
SMALL SIZE 3.0 ° • • °
LONG OPERATION BETWEEN CHARGING
3.5 °
LARGE KEYS ON KEYBOARD
2.0 °
SHORT TIME TO RECHARGE
1.5 °
READABLE SCREEN
3.0 °
DURABLE 2.0 ° • • •
FAST PROCESSING/
4.0 ° °
ATTRIBUTES IMPORTANCE 31.5 118.5 49.5 52.5 64.5 64.5
a
• HISTORY:-
• THE CONCEPT OF VALUE ANALYSIS WAS CONCEIVED DURING WORLD WAR II AT GENERAL ELECTRIC COMPANY BY LAWRENCE MILES TO FIND AN ACCEPTABLE SUBSTITUTE FOR SHORTAGE OF SKILL LABOURS AND RAW MATERIALS.
• THERE IT WAS NOTICED THAT THESE SUBSTITUTION OFTEN REDUCED COST,IMPROVED PRODUCT AND BOTH.
• SO WHAT STARTED OUT AS AN ACCIDENT OF NECESSITY WAS TURNED INTO A SYSTEMATIC PROCESS WHICH IS NOW REFERRED AS VALUE ANALYSIS.
THE VALUE OF PRODUCT WILL BE INTERPRETED IN DIFFERENT WAY BY DIFFERENT CUSTOMER .
IN GENERAL VALUE CAN BE EXPRESSED AS MAXIMISING THE FUNCTION OF A PRODUCT IN RALATION TO ITS COST.SO ,
VALUE=(PERFORMANCE+CAPABILITY)/COST= FUNCTION/COST
VALUE ANALYSIS PRIMARILY FOCUSSED ON THE FUNCTION OF A PRODUCT RATHER THAN ITS STRUCTURE OR FORM. FURTHER IT TRIES TO MAXIMIZE THE ECONOMIC VALUE OF A PRODUCT/COMPONENT WITH RESPECT TO ITS COST.
THE USE OF MULTIDISCIPLINARY TEAM(OP,MKT,SALE,CUSTOMER,SUPPLIER)
SYSTEMATIC PROCEDURE FOR EVALUATING PRODUCT FUNCTIONALITY AND VALUE.
FOCUS ON PRODUCT SIMPLIFICATION
PROCESS BEGINS WITH ANALYSING THE PRODUCT AS A WHOLE AND THEN EACH SUB ASSEMBLY IF NECESSARY.A SERIES OF QUESTIONS ARE USED TO GUIDE PROCESS AT EACH STEPS.
• THE FIRST STEP IS TO SPECIFY THE FUNCTION OF PRODUCT. THE TYPICAL QUESTIONS HERE MIGHT BE :-
• WHAT IS THE PRODUCT OR COMPONENT ?• WHAT IS ITS FUNCTION ?• WHAT CHARACTERISTICS ARE OF VALUE TO
THE CUSTOMER ?• HOW WILL THE CUSTOMER USE THE
PRODUCT? • THE ANSWER OF THE ABOVE QUESTION
WILL REVEAL CORE OF A PRODUCT.
• IN SECOND STEP ANALYSIS IS DONE TO DETERMINE HOW EACH PRODUCT CHARACTERISTICS OR COMPONENT CONTRIBUTES TO ITS VALUE(FUNCTIONALITY) AND ALSO TO DETERMINE WHAT EACH COMPONENT COSTS.
• TYPICAL QUESTION HERE COULD BE HOW DOES THIS COMPONENT CONTRIBUTE TO FUNCTIONALITY ?
• HOW DOES IT INCREASE THE PRODUCT VALUE ?• WHAT DOES IT COST ?
• THIRD AND FINAL STEP IS THE CREATIVE PHASE OF VALUE ANALYSIS.
• HERE WE REDESIGN PRODUCT OR COMPONENT TO REDUCE ITS COST OR IMPROVE ITS VALUE.
• HERE FOCUS IS MAINLY ON SIMPLIFYING THE DESIGN AND EVALUATING APPROPRIATENESS OF PRODUCT SPECIFICATION USING THESE QUESTIONS.
• CAN THIS BE DONE ANOTHER WAY ?• CAN THIS BE DONE MORE CHEAPLY ?• CAN A DIFFERENT MATERIAL BE USED ?• CAN THIS PRODUCT BE MADE EASIER TO
ASSEMBLE ?• CAN THE ITEM FUNCTION BE COMBINED WITH
THAT OF ANOTHER COMPONENT ?• HERE THE ANSWER REPRESENTS DESIGN
ALTERNATIVES THAT CAN BE COMPARED AND EVALUATED IN TERMS OF THEIR VALUE AND COST.
HONDA’S ACCORD DESIGN OF YEAR 1994 IS ONE OF THE FINEST APPLICATION OF VALUE ANALYSIS.
The Taguchi method is one of the most popular tools used in robust design. Taguchi’s approach is based on three principles:
1. when the value of a product attribute, such as shape or length, deviates from its target value, the cost of society (in term of consumer and producers) in terms of lower quality increase more than linearity (increase at an increasing rate.
socialcost Target value Product attributes
2. The design feature of the product and production process together determine the amount of variation in the product attributes.
3.Using experimentation, those product and process characteristics that affect product attributes can be determined and by manipulating these characteristic, product can be designed to reduce the attribute variations that result from normal production variations.
To illustrate Taguchi’s approach, consider the production of metal sheets that require a very smooth , uniform 0.005 inch coating of plastic.
PROCESS: the production process involves passing the metal sheets through a bath of liquid plastic and then through an oven to dry. The type of metal and plastic used(product design feature) and the temperature of the plastic, time of bathing and drying temperature and time (process design feature) will affect the thickness, uniformity, and smoothness of the coating .
.
With this tool we experiment with different product and process design characteristic to determine the best combination that produces the least variation in product quality under normal production conditions.
We consider the effect of two product design feature type of plastic used
P1=low viscosity plastic P2=high viscosity plastic Surface quality of metal M1 ,
M2
Normal variationIn plastic viscosity
ResultingVariation in SUR S
UR
Plastic type viscosity
Sur and viscosity
At fixed metal surface quality
P1 P2
SUR
M1 M2
Metal surface quality
Sur and metal quality
At fixed plastic viscosity
Suppose target level of coating smoothness and uniformity can be obtained by using the plastic/metal combination
P2M1 orP1M2 here P2M1 produces less variationBecause (1) SUR is very sensitive to P1 but insensitive to P2 (2) the sensitivity of SUR to
metal surface is relatively constant for M1 & M2
P2M1
P1M2
target SUR
frequency
The difficulty with this method is that if there are several product and process features, no of alternative will be more no. of expriment will be large.
The Taguchi analysis can be extended to studying the relationship between process characteristics such as belt speed (drying time) ,temperature and SUR e.g.
low-temp , low-speed drying may produce less variation in coating smoothness and uniformity than high-temp, high-speed drying.
Taguchi divided the factors affecting any system into two categories - control factors and noise factors. Control factors are factors affecting a system that are easily set by the experimenter. For example, if in a chemical process the reaction time is found to be a factor affecting the yield, then this factor is a control factor since it can be easily manipulated and set by the experimenter. The experimenter will choose the setting of the reaction time that maximizes the yield. Noise factors are factors affecting a system that are difficult or impossible to control. For example, ambient temperature may also have an effect on the yield of a chemical process, but ambient temperature could be a noise factor if it is beyond the control of the experimenter. Thus, change in ambient temperature will lead to variations in the yield but such variations are undesirable
Taguchi studied the interaction between the control and noise factors using two experiment designs - the inner array and the outer array. The inner array is essentially any experimental design that is used to study the effect of the control factors on the response. Taguchi then used an outer array for the noise factors so that each run of the inner array was repeated for every treatment of the outer array. The resulting experiment design, that uses both inner and outer arrays, is referred to as a cross array.
Customer specificationHeight: 11-13inWidth : 8-10 in
Thickness: 2.5-3.5 inTotal volume: >= 324 q inBurst strength: >= 100 lbsPuncture rating: >= 6Printing: 2 rotogravure Quality: rotogravure or
lithograph
Height: 11.5inWidth : 9.5 in
Thickness: 3.0 inTotal volume: 327.75 q inBurst strength: >= 105lbsPuncture rating: >= 6.2Printing: 2 rotogravure Paper board stock: grade C 80% recycled
fiber
Height: 11.0 inWidth : 9.5 in
Thickness: 3.25 inTotal volume: >= 330.69 q inBurst strength: >= 115 lbsPuncture rating: >= 6.7Printing: 2 rotogravure Paper board stock: grade B 80% recycled
fiber
The material cost gone up Labor cost and machine time dropped So overall cost was lower After testing the carton new product found
to be of superior quality as : faster filling, less spilling, larger
volume and stronger pack.
Computer aided design involves any type of design activity which makes use of computer to develop , analyze , or modify an engineering design .modern CAD system are based on interactive computer graphics (ICG). Interactive computer graphics denotes a user oriented system in which computer is employed to create ,transform and display data in the form of symbol .
The user in the computer graphics design system is designer , who communicates data and commands to the computer through input device . The computer communicates with the user via a cathode ray tube (CRT) the designer create an image on CRT screen by entering commands to call the desired software subroutines stored in the computer .
1. To increase the productivity of the designer.
2 To improve the quality of design. 3 To improve the communication. 4 To create a database for manufacturing.
The design process consist of six identifiable steps or process.
1 .Recognition of need. 2. Definition of problem 3. Synthesis. 4.Analysis and optimization. 5.Evaluation. 6.presentation.
The various design related task which are performed by a modern CAD system can be grouped into four functional areas:
1. Geometric modeling 2. Engineering analysis 3. Design review and application 4. Automated drafting
In CAD geometric modeling is concerned with computer compatible mathematical description of the geometry of an object. The
mathematical description allow the image of the object to be displayed and manipulated on a graphic terminal through signals from the CPU and CAD system.
There are several methods of representing the object in geometric modeling . The basic form uses wire frames to represent the object. In this form the object is displayed by interconnecting lines.
Wireframe geometric modeling is classified into three types .the three types are:
1.2D Two dimensional representation is used for flat object.
2 . 2 ½ D This goes somewhat beyond 2d capability by permitting a three –dimensional object to be represented as long as it has no side –wall details.
3. 3D. This allows for full three –dimensional modeling of a more complex geometry.
The engineering analysis may involve stress-strain calculation , heat transfer computation, or the use of differential equations to describe the dynamic behavior if the system being designed.
One of the most interesting evaluation features available on some CAD system is kinematics. The available kinematics packages provide the capability to animate the motion of simple design mechanism such as hinged component and linkages. This capability enhances the designers visualization of the operation of the mechanism and help to ensure against interference with other components.
Automated drafting involves the creation of hard copy engineering drawing directly from CAD data base. This is the principal justification for investing in CAD system. It can increase productivity in the drafting function by roughly five times over manual drafting.
In addition to the four CAD functions described above , another feature of CAD data base is that it can be used to develop a part classification and coding system. Parts classification and coding involves the grouping of part designs into classes ,and relating the similarities by means of coding scheme . Designers can use the classification and coding system to retrieve existing part design rather than always redesigning new parts.
1. Improved engineering productivity 2. Shorter lead time 3. reduced engineering personnel requirement 4.Customer modification are easier to make 5. Avoidance of subcontracting to meet
schedule 6. Minimized transcription errors 7. Improved accuracy of design 8. In analysis, easier recognition of component
interaction
9. Provides better functional analysis to reduce prototype testing
10. Assistance in preparation of documents 11. Designs have more standardization 12. better designs provided 13. Improved productivity in tool design 14. Better knowledge of cost provided 15. Fewer error in NC part programming 16. Makes the management of design
personnel on project more effective
THANK YOU