Chapter

Chapter 44

Product, Process, and Service Design

1
 Overview


Designing and Developing Products and Services

Process Planning and Design

Major Factors Affecting Process Design Decisions

Types of Process Designs

Interrelationships Among Product Design, Process
Design, and Inventory Policy

Process Design in Services

Deciding Among Processing Alternatives

Wrap-Up: What World-Class Companies Do

2
 Product/Service Design

When a product/service is designed:


The detailed characteristics of the product/service are
established.

The characteristics of the product/service directly
affects how the product/service can be produced/
delivered.

How the product/service is produced/delivered
determines the design of the production/delivery
system.

3
 Product/Service Design

Product/service design directly affects:


Product/service quality

Production/delivery cost

Customer satisfaction

4
 Product/Service Design and Development


Sources of Product Innovation

Developing New Products/Services

Getting Them to Market Faster

Improving Current Products/Services

Designing for Ease of Production

Designing for Quality

Designing and Developing New Services

5
 Sources of Product/Service Innovation


Customers

Managers

Marketing

Operations

Engineering

Research and Development (R&D)

Basic research

Applied research

6
 Steps in Developing New Products

1. Technical and economic feasibility studies

2. Prototype design
3. Performance testing of prototype
4. Market sensing/evaluation and economic evaluation
of the prototype
5. Design of production model
6. Market/performance/process testing and economic
evaluation of production model
7. Continuous modification of production model

7
 Steps in Developing New Products

1. Technical and Economic Feasibility Studies


Determine the advisability of establishing a project
for developing the product

If initial feasibility studies are favorable, engineers
prepare an initial prototype design

8
 Steps in Developing New Products

2. Prototype Design

This design should exhibit the basic form, fit, and
function of the final product

It will not necessarily be identical to the
production model

9
 Steps in Developing New Products

3. Performance Testing of Prototype


Performance testing and redesign of the prototype
continues until this design-test-redesign process
produces a satisfactorily performing prototype

10
 Steps in Developing New Products

4. Market Sensing/Evaluation and Economic

Evaluation of the Prototype

Accomplished by demonstrations to potential
customers, market test, or market surveys

If the response to the prototype is favorable,
economic evaluation of the prototype is
performed to estimate production volume, costs,
and profits

If the economic evaluation is favorable, the
project enters the production design phase.

11
 Steps in Developing New Products

5. Design of Production Model


The initial design of the production model will not
be the final design; the model will evolve

12
 Steps in Developing New Products

6. Market/Performance/Process Testing and Economic

Evaluation of Production Model

The production model should exhibit:

low cost

reliable quality

superior performance

the ability to be produced in the desired
quantities on the intended equipment

13
 Steps in Developing New Products

7. Continuous Modification of Production Model


Production designs are continuously modified to:
Adapt to changing market conditions


Adapt to changing production technology



Allow for manufacturing improvements



14
 Managing Product Development Projects


About 5% of all new-product ideas survive to
production, and only about 10% of these are
successful.

It is best to cancel unpromising new-product/service
development projects early!

Employees often become emotionally caught up in
these projects and are overly optimistic

An impartial management review board is needed for
periodic reviews of the progress of these projects.

15
 Getting New Products to Market Faster


Speed creates competitive advantages

Speed saves money

Tools to improve speed:

Autonomous design and development teams

Computer-aided design/computer-aided
manufacturing (CAD/CAM)

Simultaneous (concurrent) engineering

16
 Tools to Improve Speed to Market


Autonomous Design and Development Teams

Teams are given decision-making responsibility
and more freedom to design and introduce new
products/services

Time-to-market has been slashed dramatically

Enormous sums of money have been saved

Teams do not have to deal with the bureaucratic
red tape ordinarily required to obtain approvals

17
 Tools to Improve Speed to Market


Computer-Aided Design/Computer-Aided
Manufacturing (CAD/CAM)

Engineers, using CAD/CAM, can generate many
views of parts, rotate images, magnify views, and
check for interference between parts

Part designs can be stored in a data base for use on
other products

When it is time for manufacturing, the product
design is retrieved, translated into a language that
production machinery understands, and then the
production system can be automatically set up.

18
 Tools to Improve Speed to Market

Simultaneous Product/
(Concurrent) Service Ideas
Engineering Continuous
Interaction
Economic and Technical
Feasibility Studies

Product/Service Design Production Process Design

Produce and Market

New Product/Service
19
 Improving the Design
of Existing Products/Services

Focus is improving performance, quality, and cost

Objective is maintaining or improving market share
of maturing products/services

Little changes can be significant

Small, steady (continuous) improvements can add up
to huge long-term improvements

Value analysis is practiced, meaning design features
are examined in terms of their cost/benefit (value).

20
 Designing for Ease of Production


Ease of Production (Manufacturability)

Specifications - Precise information about the
characteristics of the product

Tolerances - Minimum & maximum limits on a
dimension that allows the item to function as
designed

Standardization - Reduce variety among a group of
products or parts

Simplification - Reduce or eliminate the complexity
of a part or product
21
 Designing for Quality


Crucial element of product design is its impact on
quality

Quality is determined by the customer’s perception of
the degree of excellence of the product/service’s
characteristics

Chapter 7 covers the principles of designing
products/services for quality

22
 Designing and Developing New Services

Three general dimensions of service design are:


Degree of Standardization of the Service

Custom-fashioned for particular customers or
basically the same for all customers?

Degree of Customer Contact in Delivering the Service

High level of contact (dress boutique) or low level
(fast-food restaurant)?

Mix of Physical Goods and Intangible Services

Mix dominated by physical goods (tailor’s shop) or
by intangible services (university)?

23
 Designing and Developing New Services


Differences Between New Service and New Product
Development

Unless services are dominated by physical goods,
their development usually does not require
engineering, testing, and prototype building.

Because many service businesses involve
intangible services, market sensing tends to be
more by surveys rather than by market tests and
demonstrations.

24
 Process
Planning and Design

25
 Process Planning and Design System

Inputs:
• Product/Service Information
• Production System
Information
• Operations Strategy
Process Planning & Design:
• Process-Type Selection
• Vertical Integration Studies Outputs:
• Process
• Process/Product Studies
• Equipment Studies Technology
• Facilities
• Production Procedures Studies
• Personnel
• Facilities Studies
Estimates
26
 Major Factors Affecting Process Designs


Nature of product/service demand

Degree of vertical integration

Production flexibility

Degree of automation

Product/Service quality

27
 Nature of Product/Service Demand

Production processes must have adequate capacity to
produce the volume of the products/services that
customers need.

Provisions must be made for expanding or
contracting capacity to keep pace with demand
patterns.

Some types of processes are more easily expanded
and contracted than others.

Product/service price affects demand, so pricing
decisions and the choice of processes must be
synchronized.

28
 Degree of Vertical Integration

Vertical integration is the amount of the production
and distribution chain that is brought under the
ownership of a company.

This determines how many production processes need
to be planned and designed.

Decision of integration is based on cost, availability
of capital, quality, technological capability, and more.

Strategic outsourcing (lower degree of integration) is
the outsourcing of processes in order to react quicker
to changes in customer needs, competitor actions, and
technology.

29
 Production Flexibility


Product flexibility -- ability of the production (or
delivery) system to quickly change from producing
(delivering) one product (or service) to another.

Volume flexibility -- ability to quickly increase or
reduce the volume of product( or service) produced
(or delivered).

30
 Degree of Automation


Advantages of automation

Improves product quality

Improves product flexibility

Reduces labor and related costs

Disadvantages of automation

Equipment can be very expensive

Integration into existing operations can be difficult

31
 Product/Service Quality


Old viewpoint – high-quality products must be made
in small quantities by expert craftsmen

New viewpoint – high-quality products can be mass-
produced using automated machinery

Automated machinery can produce products of
incredible uniformity

The choice of design of production processes is
affected by the need for superior quality.

32
 Types of Process Designs


Product-Focused

Process-Focused

Group Technology/Cellular Manufacturing

33
 Product-Focused


Processes (conversions) are arranged based on the
sequence of operations required to produce a product
or provide a service

Also called “Production Line” or “Assembly Line”

Two general forms

Discrete unit – automobiles, dishwashers

Process (Continuous) – petrochemicals, paper

34
 Product-Focused

Raw Material Components

22 4 Su
Co ba
m ss
po em
n. .
Assemblies Fin. Goods
1 3 5 7
Raw Material Components Subassem.

s
lie
mb
Purchased

se
Product/Material
1 Flow

As
6
Production Operation Components,
Subassemblies

35
 Product-Focused


Advantages

Lower labor-skill requirements

Reduced worker training

Reduced supervision

Ease of planning and controlling production

Disadvantages

Higher initial investment level

Relatively low product flexibility

36
 Process-Focused


Processes (conversions) are arranged based on the
type of process, i.e., similar processes are grouped
together

Products/services (jobs) move from department
(process group) to department based on that particular
job’s processing requirements

Also called “Job Shop” or “Intermittent Production”

Examples

Auto body repair

Custom woodworking shop
37
 Process-Focused

Custom Woodworking Shop

Cutting Planing Shaping Assembly Sanding Finishing
11 22 55 66 77

Job A 22 33

Job B 33 44

11 44 55 66

Drilling Turning

38
 Process-Focused


Advantages

High product flexibility

Lower initial investment level

Disadvantages

Higher labor-skill requirements

More worker training

More supervision

More complex production planning and controlling

39
 Group Technology/Cellular Manufacturing


Group Technology

Each part produced receives a multi-digit code that
describes the physical characteristics of the part.

Parts with similar characteristics are grouped into
part families

Parts in a part family are typically made on the
same machines with similar tooling

40
 Group Technology/Cellular Manufacturing


Cellular Manufacturing

Some part families (those requiring significant
batch sizes) can be assigned to manufacturing
cells.

The organization of the shop floor into cells is
referred to as cellular manufacturing.

Flow of parts within cells tend to be more like
product-focused systems

41
 Group Technology/Cellular Manufacturing


Advantages (relative to a job shop)

Process changeovers simplified

Variability of tasks reduced (less training needed)

More direct routes through the system

Quality control is improved

Production planning and control simpler

Automation simpler

42
 Group Technology/Cellular Manufacturing


Disadvantages

Duplication of equipment

Under-utilization of facilities

Processing of items that do not fit into a family
may be inefficient

43
 Group Technology/Cellular Manufacturing


Candidates for GT/CM are job shops having:

A degree of parts standardization

Moderate batch sizes

44
 Product/Process Design & Inventory Policy


Standard Products and Produce to Stock

Sales forecasts drive production schedule

Maintain pre-determined finished-goods levels

MRP forecast drives material ordering

Custom Products and Produce to Order

Orders set production schedule and drive material
deliveries

Design time (preproduction planning) may be
required before production can be scheduled

45
 Process Design in Services


Some of the factors important in process design for
products are also important in services:

Nature (level and pattern) of customer demand

Degree of vertical integration

Production flexibility

Degree of automation

Service quality

46
 Process Design in Services


Three schemes for producing and delivering services

Quasi-Manufacturing

Customer-as-Participant

Customer-as-Product

47
 Process Design in Services


Quasi-Manufacturing

Physical goods are dominant over intangible
service

Production of goods takes place along a production
line

Operations can be highly automated

Almost no customer interaction

Little regard for customer relations

Example – bank’s checking encoding operation

48
 Process Design in Services


Customer-as-Participant

Physical goods may be a significant part of the
service

Services may be either standardized or custom

High degree of customer involvement in the
process

Examples: ATM, self-service gas station

49
 Process Design in Services


Customer-as-Product

Service is provided through personal attention to
the customer

Customized service on the customer

High degree of customer contact

There is a perception of high quality

Customer becomes the central focus of the process
design

Examples: medical clinic, hair salon

50
 Process Reengineering


The concept of drastically changing an existing
process design

Not merely making marginal improvements to athe
process

A correctly reengineered process should be more
efficient

A smaller labor force is often the result

51
 Deciding Among Processing Alternatives


Batch Size and Product/Service Variety

Capital Requirements

Economic Analysis

Cost Functions of Alternative Processes

Break-Even Analysis

Financial Analysis

52
 Process Design Depends
on Product Diversity and Batch Size
Product
Large

Focused,
Dedicated
Systems
Batch Size

Product
Focused,
Batch
System
Cellular
Manufacturing Process-Focused,
Small

Job Shop

Few Number of Product Designs Many

53
 Capital Requirements


The amount of capital required tends to differ for
each type of production process

Generally, the capital required is greatest for product-
focused, dedicated systems

Generally, the capital required is lowest for process-
focused, job shops

The amount of capital available and the cost of capital
are important considerations

54
 Economic Analysis


Cost Functions of Processing Alternatives

Fixed Costs

Annual cost when production volume is zero

Initial cost of buildings, equipment, and other
fixed assets

Variable Costs

Costs that vary with production volumes

Labor, material, and variable overhead

55
 Cost Functions of Processing Alternatives

Annual Cost of Production ($000)

o p f.
Sh Ma n u
Job lula
r
Ce l

e m bly L ine
tom . A s s
2,000 Au
Automated
1,500 Assembly Line
Preferred
Cellular
1,000
Manufacturing
Job
Preferred Units
500 Shop
Preferred Produced
Per Year
100,000 250,000
56
 Cost Functions of Processing Alternatives


Example
Three production processes (A, B, and C) have
the following cost structure:
Fixed Cost Variable Cost
Process Per Year Per Year
A $120,000 $3.00
B 90,000 4.00
C 80,000 4.50
What is the most economical process for a volume of
8,000 units per year?

57
 Cost Functions of Processing Alternatives


Example
TC = FC + v(Q)
A: TC = 120,000 + 3.00(8,000) = $144,000 per year
B: TC = 90,000 + 4.00(8,000) = $122,000 per year
C: TC = 80,000 + 4.50(8,000) = $116,000 per year
The most economical process at 8,000 units is
Process C, with the lowest annual cost.

58
 Economic Analysis


Break-Even Analysis

Widely used to analyze and compare decision
alternatives

Can be displayed either algebraically or
graphically

Disadvantages:

Cannot incorporate uncertainty

Costs assumed over entire range of values

Does not take into account time value of money

59
 Break-Even Analysis


Example
Break-Even Points of Processes A, B, and C,
assuming a $6.95 selling price per unit
Q = FC / (p-v)
A: Q = 120,000 / (6.95 - 3.00) = 30,380 units
B: Q = 90,000 / (6.95 - 4.00) = 30,509 units
C: Q = 80,000 / (6.95 - 4.50) = 32,654 units
Process A has the lowest break-even point.

60
 Economic Analysis


Financial Analysis

A great amount of money is invested in production
processes and these assets are expected to last a
long time

The time value of money is an important
consideration

Payback period

net present value

internal rate of return

Profitability index

61
 Deciding Among Processing Alternatives


Assembly Charts (Gozinto Charts)

Macro-view of how materials are united

Starting point to understand factory layout needs,
equipment needs, training needs

Process Charts

Details of how to build product at each process

Includes materials needed, types of processes
product flows through, time it takes to process
product through each step of flow

62
 Wrap-Up: World Class Practice


Fast new product introduction

Design products for ease of production

Refine forecasting

Focus on core competencies ... less vertical
integration

Lean production

Flexible automation

Job shops move toward cellular manufacturing

Manage information flow ..... automate and simplify!

63
End
End of
of Chapter
Chapter 44

64