Manufacturing Systems II

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Manufacturing Systems II

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Title: Manufacturing Systems II


1
Manufacturing Systems II
  • Chris Hicks
  • Chris.Hicks_at_newcastle.ac.uk
  • http//www.staff.ncl.ac.uk/chris.hicks

2
Topics
  • Group Technology (Cellular Manufacture)
  • Inventory Management
  • Material Requirements Planning
  • Just-in-Time Manufacture

3
Cellular Manufacturing
4
References
  • Apple J.M. (1977) Plant Layout and Material
    Handling, Wiley, New York.
  • Askin G.G Standridge C.R. (1993) Modelling and
    Analysis of Manufacturing Systems, John Wiley
  • ISBN 0-471-57369-8
  • Black J.T. (1991) The Design of a Factory with a
    Future, McGraw-Hill, New York, ISBN
    0-07-005550-5

5
References (cont.)
  • Burbidge J.L. (1978)
  • Principles of Production Control
  • MacDonald and Evans, England
  • ISBN 0-7121-1676
  • Gallagher C.C. and Knight W.A. (1986)
  • Group Technology Production Methods in
    Manufacture
  • E. Horwood, England ISBN 0-471-08755-6
  • Hyde W.F. (1981)
  • Data Analysis for Database Design
  • Marcel Dekker Inc
  • ISBN 8247-1407-0

6
Manufacturing Layout
  • Process (functional) layout, like resources
    placed together.
  • Group (cellular) layout, resources to produce
    like products placed together.

7
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8
Scientific Management
  • F.W.Taylor 1907
  • Division of labour - functional specialism
  • Separation of doing and thinking
  • Workers should have exact instructions
  • Working methods should be standardised
  • Specialisation led to functional layouts

9
Process Layout
  • Like machines placed together
  • Labour demarcation / common skills
  • Robust wrt machine breakdown
  • Common jigs / fixtures etc.
  • Sometimes high utilisation
  • Components travel large distances
  • High work in progress
  • Long lead times
  • Poor throughput efficiency
  • Often hard to control

10
Group Technology (Cellular Manufacturing)
  • Group Technology is a manufacturing philosophy
    with far reaching implications.
  • The basic concept is to identify and bring
    together similar parts and processes to take
    advantage of all the similarities which exist
    during all stages of design and manufacture.
  • A cellular manufacturing system is a
    manufacturing system based upon groups of
    processes, people and machines to produce a
    specific family of products with similar
    manufacturing characteristics (Apple 1977).

11
Cellular Manufacturing
  • Can be viewed as an attempt to obtain the
    advantages of flow line systems in previously
    process based, job shop environments.
  • First developed in the Soviet Union in 1930s by
    Mitrofanov.
  • Early examples referred to as Group Technology.
  • Promoted by government in 1960s, but very little
    take up.
  • In 1978, Burbidge asked What happened to Group
    Technology?
  • Involves the standardisation of design and
    process plans.

12
Group (Cellular) Layout
  • Product focused layout.
  • Components travel small distances.
  • Prospect of low work in progress.
  • Prospect of shorter lead times.
  • Reduced set-up times.
  • Design - variety reduction, increased
    standardisation, easier drawing retrieval.
  • Control simplified and easier to delegate.
  • Local storage of tooling.

13
Group (Cellular) Layout
  • Flexible labour required.
  • Sometimes lower resource utilisation due to
    resource duplication.
  • Organisation should be focused upon the group
    e.g. planning, control, labour reporting,
    accounting, performance incentives etc.
  • Often implemented as a component of JIT with team
    working, SPC, Quality, TPM etc.
  • Worker empowerment is important - need people to
    be dedicated to team success. Cell members should
    assist decision making.

14
Characteristics of Successful Groups
Characteristic Description Team Specified team
of workers Products Specified set of products
no others Facilities Dedicated machines /
equipment Group layout Dedicated
space Target Common group goal for
period Independence Groups can reach goals
independently Size Typically 6-15 workers
15
Adapted from Black (1991)
16
Implementation of Cellular Manufacturing
  • Grouping - identifying which machines to put into
    each cell.
  • Cell / layout design - identifying where to put
    to place machines.
  • Justification
  • Human issues

17
Types of Problem
  • Brown field problem - existing layout, transport,
    building and infrastructure should be taken into
    account.
  • Green field problem - designers are free to
    select processes, machines, transport, layout,
    building and infrastructure.
  • Brown field problems are more constrained, whilst
    green field problems offer more design choice.

18
Grouping Methods
  • Eyeballing
  • Classification of parts
  • Product Flow Analysis
  • Cluster Analysis
  • Matrix methods (e.g. King 1980)
  • Similarity Coefficient methods
  • Layout generation without grouping
  • Beware
  • Different methods can give different answers
  • There may not be clear clusters
  • Cellular manufacturing not always appropriate

19
Classification of Parts
  • Based upon coding.
  • Many schemes available.
  • Basic idea is to classify according to geometry,
    similar shapes require similar processes.
  • Grouping codes together is synonymous with
    grouping together like parts.
  • Very prevalent in 1960s and 70s.
  • Many schemes aimed at particular sectors.

20
Coding issues
  • Part / component population
  • inclusive should cover all parts.
  • flexible should deal with future parts /
    modifications.
  • should discriminate between parts with different
    values for key attributes.
  • Code detail - too much and the code becomes
    cumbersome - too little and it becomes useless.
  • Code structure - hierarchical (monocode), chain
    (polycode) or hybrid.
  • Digital representation - numeric, alphabetical,
    combined.

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22
Product Flow Analysis
  • Developed by Jack Burbidge (1979).
  • Uses process routings.
  • Components with similar routings identified.
  • Three stages
  • Factory flow analysis.
  • Group analysis
  • Line analysis
  • (See Askin and Standridge p177-179)

23
Factory Flow Analysis
  • Link together processes (e.g. machining, welding,
    pressing) and subprocesses (turning, milling,
    boring) used by a significant number of parts.
  • Large departments are formed by combining all
    related processes.
  • These are essentially independent plants that
    manufacture dissimilar products.

24
Group Analysis
  • Breaks down departments into smaller units that
    are easier to administer and control.
  • The objective is to assign machines to groups so
    as to minimise the amount of material flow
    between the groups.
  • Small inexpensive machines are ignored, since
    they can be replicated if necessary.

25
Group Analysis
  • Construct a list of parts that require each
    machine. The machine with fewest part types is
    the key machine.
  • A subgroup is formed from all the parts that need
    this machine plus all the other machines required
    to make the parts.
  • A check is then made to see if the subgroup can
    be subdivided.
  • If any machine is used by just one part it can be
    termed exceptional and may be removed.

26
Group Analysis
  • Subgroups with the greatest number of common
    machine types may be combined to get groups of
    the desired size.
  • The combination rule reduces the number of extra
    machines required and makes it easier to balance
    machine loads.
  • Each group must be assigned sufficient machines
    and staff to produce its assigned parts.

27
Process Plan Example
28
Applying Grouping
  • Steps
  • 1. Identify a key machine. Either E or F.
  • Create a subgroup to D,E and F.
  • 2. Check for subgroup division. All parts visit F
    and so subgroup cannot be subdivided. Only part 7
    visits machine D so it is exceptional and is
    removed.
  • 1. Identify an new key machine for remaining 6
    parts. A is the new key machine with subgroup
    A,B,C producing parts 1,2 3.
  • 2. Subgroup division - C only used for part 3,
    therefore exceptional and can be removed.

29
Applying Grouping
  • 1. Identify next key machine. Only parts 4,5, 6
    remain as well as machines C and D.
  • 2. All parts use all machines - no subdivision
    possible.
  • 3. Cell designer can now recombine the three
    subgroups into a set of workable groups of
    desired size.
  • 4. The final solution must provide adequate
    machine resources in each group for the assigned
    parts. If exceptional parts exist, or if groups
    are not self contained, then plans must be made
    for transport.

30
Rank Order Clustering
1. Evaluate binary value of each row. 2. Swap
rows over to get them in rank order.
31
Rank Order Clustering
Next apply same method to the columns
32
Rank Order Clustering
Next swap over columns to get in rank order.
33
Rank Order Clustering
ROC has got a solution close to a block diagonal
structure. The process can be repeated
iteratively until a stable solution is found.
34
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35
Similarity Coefficients
  • Consider a pair of machines I,j,
  • ni number of parts visiting machine i
  • nj number of parts visiting machine j
  • nij number of parts visiting i and j.
  • Define similarity coefficient as
  • sij max(nij/ni,nij/nj)
  • Values near 1 denote high levels of interaction.
  • Values near 0 denote little or no interaction.

36
Similarity Coefficients
37
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38
Clustering
  • We start with 6 clusters, one for each machine.
  • With a threshold of T 1 machines A and B can be
    grouped. Likewise E and F.
  • There are several methods for updating similarity
    coefficients between newly formed clusters and
    existing clusters.
  • The single linkage approach uses the maximum Sij
    for any machine i in the first cluster and any
    machine j in the second cluster. Therefore any
    single pair of machines can cause groups to be
    combined

39
Updating Similarity Coefficients (Using Single
Linkage)
Next consider the highest value of T possible.
This gives the cluster CD at T 0.75. The
coefficients then need to be updated again.
40
Dendogram
41
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42
Variety Reduction
  • Basic principle always use common designs and
    components wherever possible.
  • Modular design.
  • Standardisation.
  • Redundant features.
  • Can base upon geometric series.
  • Imperial / metric series.
  • Reduced estimated work planning.
  • Simplified stock control.
  • Less problems with spares.

43
Variety Reduction
  • May use slightly more expensive parts than
    necessary.
  • Increases the volume of production of items.
  • Reduced planning / jigs and fixtures etc.
  • Reduced lead times.

44
Product Family Analysis
  • There are a number of different ways of
    identifying part families. The following factors
    should always be considered
  • How wide is the range of components?
  • How static is workload?
  • What changes are anticipated?
  • Is Group Technology aimed purely at manufacturing
    or is standardisation and modularisation of
    design a major issue?

45
Manufacturing Layout
  • Concerned with the relative location of major
    physical manufacturing resources.
  • A resource may be a machine, department, assembly
    line etc.
  • A block plan can be produced that shows the
    relative positioning of resources.
  • Evaluation criteria are required such as
    minimising transport costs, distance travelled
    etc.

46
Approaches
  • Many methods are based upon a static
    deterministic modelling approach.
  • Dynamic effects may be guessed by trying out a
    variety of scenarios.
  • Dynamic and stochastic effects may be evaluated
    by simulation.
  • A premium may be placed upon favourable
    attributes
  • Flexibility dealing with changes in design,
    demand etc.
  • Modularity the ability to change the system by
    adding or removing component parts to meet major
    changes in demand.
  • Reliability
  • Maintainability

47
Line Layout
48
Spine Layout
  • Spine is central core for traffic.
  • Secondary aisles for traffic into departments
  • Each department has input /output storage areas
    along the spine.
  • Point of use storage reduces material flow.

49
Loop Structure
Circular Structure
50
Layout Configurations
  • Eli Goldratt I, V, U, W
  • I layouts have linear flow with no direction
    changes, empty pallets may go in reverse
    direction.
  • V and U lines have more direction changes but may
    help with empty pallets.
  • Rectilinear layouts may restrict operators from
    working multiple machines.
  • Circular layouts may enable operators to work
    multiple machines.

51
Analysing Flow
  • Sting diagrams provide a very quick way to
    identify the pattern of flow.
  • Look at performance measures
  • Distance travelled per component
  • Material handling costs
  • Material handling time
  • Load / unload times
  • Number of direction changes
  • Number of moves per day
  • Many, many more.
  • Looking at performance measures enables
    alternative layouts to be evaluated.

52
Measures of Performance
  • Resource Measures
  • Resource utilisation
  • Productivity.
  • Inventory
  • work in progress
  • queues.
  • Product
  • lead times
  • delivery performance
  • Quality.
  • Financial, overhead recovery v.s. ABC costing.

53
Creating Layouts
  • If there is a dominant flow, such as all parts
    going from department 1-gt 2 -gt 3 then the layout
    should reflect this.
  • At the other extreme, if the flow between
    departments is uniformly distributed, then any
    arrangement may be equally good.
  • However, most problems will lie between the
    extremes of dominant and equal flow.

54
Systematic Layout Planning
  • 1. Data collection.
  • 2. Flow analysis.
  • 3 Qualitative considerations.
  • 4. Relationship diagram.
  • 5. Space requirements.
  • 6. Space availability.
  • 7. Space relationship diagram.
  • 8. Modifying considerations and limitations.
  • 9. Evaluation.

(Muther 1973)
55
1. Data Collection
  • Products to be produced volumes.
  • Routing, Bill of Materials, parts lists.
  • Resources for production, layout geometrical
    information.
  • Timing information - set-up, processing
    transfer durations.
  • Data determines loads resource utilisation.
  • Quantity variety determine appropriate layout
    type.
  • A Product-Quantity chart, which is a Pareto
    analysis of product importance can be used to
    determine items that justify their own lines or
    families of parts that justify a cell.

56
Product-Quantity Chart
57
2. Flow Analysis
  • Operation process charts determine movement
    showing major operations, inspections, moves and
    storage.
  • Process charts, similar to operation process
    charts, but more detail.
  • Flow diagrams.
  • Flow data can be summarised in From-To charts
    (like mileage charts in maps)
  • Volumes
  • Distance travelled
  • Costs
  • String diagrams.

58
Operation Process Chart
59
Process Chart Symbols
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61
Flow Diagram
Material flow
Process chart symbols
Facility layout
62
3. Qualitative Considerations
REL Chart
63
4. Relationship Diagram
  • Combines quantitative and qualitative
    relationship data.
  • Provides a mechanism for visualising
    relationships.

64
5. Space Requirements
  • Departmental space requirements need to be
    estimated.
  • May have standards that define space requirement
    for each machine type.
  • Can work from current space needs.
  • Can determine space requirement by considering
    tasks performed, tooling, access, flow of
    materials etc.

65
6. Space Availability
  • Need to accommodate machines, material handling
    equipment, people, energy transmission, drainage,
    air lines, communications etc.
  • If an existing facility is to be used, the
    available space and constraints need to be
    accurately defined.
  • In the case of new facilities there are financial
    and often planning constraints.Need to consider
    possibility of future changes in demand or use.

66
7. Space Relationship Diagram
  • Represents departments with templates that are
    proportional in size to space requirements.
  • Templates can be rearranged to find improved
    solutions.

67
(a)
(b)
a) Relationship Diagram b) Space Relationship
Diagram
68
8. Modifying Considerations and Limitations
  • Steps 1-7 have not taken into account
    implementation details.
  • Site specific or operations specific conditions
    may require adjustments to the layout.
  • Need to consider
  • Utilities, power, heating, light, drainage
    compressed air etc.
  • Structural limitations, load-bearing capacity of
    floors, ceiling heights, columns.
  • Location of external connections e.g. roads.

69
9. Evaluation
  • Several alternatives should be considered.
  • Drawings, flow diagrams etc form the basis of
    assessment of advantages and disadvantages of
    each.
  • Costs / benefits can be attributed to each
    alternative.
  • Quality of flow can be evaluated.
  • Flexibility, maintainability, expandability
    safety and ease of operations should be reviewed.

70
Computerised Layout Planning
  • Improvement algorithms are based upon an initial
    layout. They generate improvements by
    rearrangement. Suitable for brown field sites.
    Examples CRAFT (Armour Buffa 1963)
  • Construction algorithms start with a blank shop
    floor and add machines to it. Suitable for green
    field sites. Example ALDEP (Seehof Evans
    1967), CORELP (Parsaei et al 1987), SHAPE (Hassan
    et al 1986).
  • Hybrid algorithms include both construction and
    improvement algorithms.

71
Computerised Relative Allocation of Facilities
(CRAFT)
  • Creates layouts by exchanging machine pairs and
    then evaluating the layout.
  • When all pairs of exchanges have been completed,
    the exchange with the best evaluation is chosen
    and a new layout in generated.
  • This process is repeated until no improvement can
    be made through exchanges.

72
Automated Layout Design Program (ALDEP)
  • A machine is randomly selected and added to the
    layout.
  • The closeness of all the remaining machines to it
    is calculated. The closest machine is added.
    This is repeated until all machines have been
    placed.
  • Once a machine has been placed, it is fixed. This
    makes it difficult to find good solutions.
  • Often use an improvement algorithm to improve
    layout produced.

73
Construction Algorithm Differences
  • Method for election of next machine and its
    placement.
  • Evaluation of the relationship between machines
    already located and the selected machine (e.g. by
    using different definitions of similarity
    coefficient).
  • How the layout is represented.

74
Synthetic Machine Concept
  • A group of machines form a synthetic machine.
  • Resource hierarchy flattened.
  • Framework to assist delegated responsibility.
  • Local planning, control and work organisation.
  • Concerned only with cell inputs and outputs.

75
Types of Cell
  • Highly automated - conveyers, robot handling,
    Flexible Manufacturing Systems (FMS).
  • Semi-automated - some automated material
    handling.
  • Simple cells without automated material handling.
  • Work grouped on a single machine using a
    multi-functional machine tool.
  • NOTE Need to find an appropriate mix for given
    production volumes. Increasing automation
    normally increases overheads and reduces
    flexibility.

76
Supporting Techniques
  • Statistical process control.
  • Quality Circles.
  • Team working.
  • Empowerment.
  • Visible performance measures.
  • Total preventative maintenance.
  • Single minute exchange of dies.
  • Simple machine concept.

77
Case Study 1
  • World class automotive components supplier.
  • Adopted lean manufacturing practices yet
    productivity still 50 of Japanese sister plant.
  • WHY?

78
Findings
  • Layout - rectilinear v.s clusters.
  • Supervision of resources.
  • Smallest machine concept.
  • Flexible resource variable.
  • Cost of capital and accounting philosophies.

79
Case Study 2
  • SME supplier of orthotics (surgical appliances).
  • Very long delivery.
  • High work in progress.
  • How can situation be improved?

80
Solution
  • Business process analysis
  • Non physical processes
  • Physical processes .
  • Target queuing by streamlining processes or
    increasing capacity.
  • Result
  • Lead time 14 weeks to 4
  • Cash flow improved by 300k on 2M turnover.

81
Other Key Issues
  • Batch sizes
  • Set-up
  • Machining
  • Transfer
  • Effect on other measures of performance.

82
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85
Hints
  • Look at the material flow
  • Try to simplify
  • Think about removing in-process inventory
  • Think about the operators
  • Consider other layout constraints

86
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89
Inventory Management
90
Inventory
  • Money invested in materials
  • 3 Types of inventory
  • Raw materials
  • Work in progress
  • Finished goods

91
Advantages of Inventory
  • Raw materials offset lead time
  • Work in progress offsets disturbances in the
    production system and may help keep resource
    utilisation high
  • Finished goods stocks enable fast delivery
  • Economic order quantity methods claim to claim
  • People feel busy
  • Process decoupling

92
Inventory Disadvantages
  • Expensive to keep
  • Interest on capital
  • Storage costs
  • Adverse effect on cash flow and liquidity
  • Risk of obsolescence
  • Lack of flexibility
  • Masks problems with manufacturing system
  • Difficult to control

93
Types of Demand
  • Independent
  • Demand for an item is independent of the demand
    for another item
  • Dependant
  • Demand for an item is linked to the demand for
    another item
  • Product structure defines dependencies

94
Inventory Control
  • The activities and techniques of maintaining
    stock items at desired levels, whether they are
    raw materials, work in progress or finished
    products

95
Inventory Control Decisions
  • How many?
  • (lot size or order quantity
  • When
  • timing or order point

96
Independent Demand
  • Fixed order quantity (FOQ) systems order a
    predetermined quantity of items when stock levels
    drop below a predetermined level e.g. 2 bin
    system
  • Economic order quantity systems aim to minimise
    the combination of ordering and carrying costs.
    They make a number of assumptions
  • annual demand can be estimated
  • demand is uniform
  • no quantity discounts
  • Ignores the costs associated with stock outs

97
Dependent Demand
  • Demand for one item linked to the demand for
    another
  • Producing an assembly causes dependent demand for
    all the components that go into the assembly
  • Assembling a car requires one windscreen, 5
    wheels, one engine etc.
  • One engine requires one crankshaft, one cylinder
    head etc.
  • One cylinder head requires .

98
Product Structure
99
Product Structure
A
B
D
c
E
F
G
H
100
Material Requirements Planning
  • Method for planning dependent demand
  • Requirement for subassemblies and components
    based upon requirements for end items and product
    structure
  • Takes into account current stocks of each item to
    calculate net requirements

101
Material Requirements Planning
End Item Requirements
MRP
Stocks
Product Structure
Net Requirements
102
ABC Classification
  • Break items into 3 groups
  • A - the items that represent 75 of value and 20
    volume
  • B - the items that represent 20 value and 30
    volume
  • C - the items that represent 5 value and 50
    volume
  • This approach is based upon
  • Parieto analysis

103
Just-in-Time
104
Just-in-Time
  • Approach to achieve excellence in manufacturing
  • Minimise waste anything that adds cost but not
    value
  • Just the correct quantity
  • at just the right quality
  • at just the right time
  • in the right place

105
Push Scheduling
Manufacturing Systems
Inventory
PUSH
106
Kanban
  • Japanese word for card
  • One card
  • Two card

107
One Card Kanban
Item Kanban
Stock Area
MC1
MC2
Machine 1 operates at a constant rate
Kanban
108
Two Card Kanban
Item Kanban
Item
Stock Area
MC1
MC2
P Kanban
C Kanban
P Production Kanban C Conveyance Kanban
109
Pull scheduling
5
2
1
3
4
Manufacturing System
PULL
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