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Title: Cellular Manufacturing


1
Cellular Manufacturing
Adapted from
2
Introduction to Cellular Manufacturing (CM)
  • Product layouts (assembly lines, mass production
    one a few products on the same line) is the most
    efficient of the basic layout options
  • Many products are not made in volumes that
    require a product layout
  • Cellular manufacturing (group technology) forms
    families of products that have common production
    requirements
  • Locate machines, people, jigs, fixtures,
    drawings, measuring equipment, material handling
    equipment together (focused factory)

3
Introduction to Cellular Manufacturing
  • The cellular approach is to organize the entire
    manufacturing process for particular or similar
    products into one group of team members and
    machines known as a "Cell".
  • These "cells" are arranged in a U-shaped layout
    to easily facilitate a variety of operations.
  • Parts or assemblies move one at a time (or in
    small batch sizes).
  • The parts are handed off from operation to
    operation without opportunity to build up between
    operations.

4
Introduction to Cellular Manufacturing
5
Introduction to Cellular Manufacturing
6
Introduction to Cellular Manufacturing
7
Empowered Employees in CM
  • Goals and tracking charts are maintained and
    posted.
  • Problems are solved through daily cell meetings
    and problem solving teams.
  • The inventory management system is a KANBAN
    Demand Pull instead of a work order/kit picking
    system.
  • Cells are responsible for planning, scheduling
    and expediting directly with vendors.
  • They establish and maintain a KANBAN system with
    the vendors.

8
Advanced CM
  • The cell operates like an independent business
    with total responsibility for quality,
    manufacturing and delivery of the product to the
    customer.
  • All cells have the resources within their
    organization to accomplish their mission.
  • The requirements are known and goals are
    established.
  • Cell members are flexible and work in teams to
    accomplish their goals including continuous
    improvement.

9
Benefits of CM
  • Common tooling required for many products (fewer
    setups)
  • Tooling can be justified since many products
    require it (more volume when products are
    grouped)
  • Minimized material handling
  • Simple production schedule
  • Short cycle time
  • Low WIP

10
Benefits of CM
  • Cross-training employees operate several
    machines
  • Minimized material handling costs since no
    paperwork is required and distance is small
  • Employees accept more responsibility of
    supervision (scheduling of parts within cell,
    scheduling of vacation, purchasing of material,
    managing a budget)
  • Simple flow pattern and reduced paperwork
  • Buffers are small if batch size is small

11
Disadvantages of CM
  • Lower equipment utilization
  • Increased set-up costs
  • Less flexibility than functional departments

12
Family Formation
  • Various levels macro and micro
  • Macro entire factories (focused factories) can
    specialize in a particular type of part
  • Micro families can be based on similarities in
    part geometry (group shafts, flat parts, gears,
    etc), process requirements (castings, forgings,
    sheet metal parts, heat-treated parts, printed
    circuit boards)
  • How are these groupings determined?
  • Coding

13
Finding Part Families
  • Visual Inspection of physical parts or
    photographs to identify similarities.
  • Coding and Classification of parts by examining
    design and/or manufacturing attributes.
  • OPITZ System
  • MICLASS System
  • Here a code is assigned to specific features of
    the part.
  • Is the part cylindrical or prismatic ?
  • Does it have threads?
  • Does it have through slots?
  • Does it require heat treatment?
  • This requires a large initial time investment in
    coding and classifying all parts.

14
Finding Part Families
  • Production Flow Analysis Since the parts in a
    part family have similar manufacturing processes,
    it is possible to identify similar parts by
    studying the route sheets.
  • Parts with similar routes can be grouped into
    families.

15
Group Analysis
  • To create part families and machine groups a
    part-machine matrix is created.
  • This is a 0-1 matrix in which a one signifies
    that a machine is required for a given part.
  • While creating this matrix the machine refers to
    a "type" of machine.
  • Thus, if there are 5 identical CNC lathes we will
    create one row in the matrix for these lathes.
  • Also, the number of times a part visits a machine
    is not considered at this stage

16
Group Analysis
  • Once a the part-machine matrix is created, it is
    customary to remove approximately 10 of the most
    heavily used machines.
  • Several copies of these machines are likely to be
    available and thus it is always possible to split
    these machines between different groups later.
  • The remaining matrix is then inspected for part
    families.

17
Group Analysis
  • To identify the part-families the rows and
    columns are interchanged such that a
    block-diagonal structure is obtained. There are
    several algorithms that can be used to do this. A
    simple algorithm for this problem can be
    described as follows
  • Pick any row and draw a horizontal line through
    it.
  • For each 1 in the row that has been crossed once
    draw a vertical line through the corresponding
    column.
  • Pick each new column identified in the previous
    step. For each 1 in the column that has been
    crossed once draw a horizontal line through the
    row.
  • Repeat this process until there are no
    singly-crossed 1s in the matrix.
  • Remove the rows and columns that have been
    crossed to form a part family-machine group.
  • Continue for the rest of the matrix

18
Group Analysis
19
Coding
  • GT coding and classification schemes attempt to
    capture design and manufacturing attributes such
    as the main shape, size, features of the product,
    production quantity, and material.
  • A large number of GT coding schemes have been
    developed for discrete machined parts including
    MICLASS, Opitz and DCLASS

20
Coding
  • Code should contain information about
  • Part or assembly itself
  • Manufacturing process (manufacturing engineering,
    industrial engineering, tool engineering,
    scheduling, line supervision, quality assurance,
    etc)

21
Coding Requirements
  • Precise nonambiguous meaning, no double or triple
    definitions for the same phrase
  • Tightly structured and concise
  • Easy to use

22
Coding Options
  • Codes can be chain or hierarchical
  • Chain each digits specific location is fixed
    for a particular meaning
  • Chain Example
  • First digit is reserved for the product type
  • Second digit for material
  • Digits 3-6 for part geometry

23
Coding Options
  • Chain Advantage easy to learn
  • Chain Disadvantage requires more digits making
    it difficult to handle manually and with low
    power computers (not as big a problem today as
    the price of computers has dropped)

24
Coding Options
  • Hierarchical code each code character depends
    on the preceding one a tree type structure
  • Advantages code can be sort since many branches
    can be eliminated
  • Disadvantages difficult to learn

25
Code Generation
  • CM codes are typically generated manually or
    interactively by answering a series of questions
    and applying appropriate coding rules.
  • However, this is a slow and inconsistent
    procedure which inhibited the widespread use of
    CM.

26
Opitz Coding Scheme
  • Shah and Bhatnagar developed an automated CM
    coding system based on the Opitz coding scheme
    for machined parts.
  • The system assigns pre-defined taxonomy codes for
    each feature of its feature-based CAD system.
  • The generic information captured by the taxonomy
    codes is used to determine individual feature
    characteristics and the relationships between
    features and the entire parts.
  • The CM code generator uses the resulting feature
    information and Opitz coding rules to generate
    the CM codes.

27
Using Codes
  • Comparing the CM codes of two products is a quick
    and efficient method for estimating product
    similarity in selected attributes.
  • CM codes can be used to search a database of
    products and retrieve the designs and process
    plans of those products which are similar to a
    given design
  • To generate new process plans automatically using
    a knowledge-based system
  • To assess manufacturability of a product design

28
Cell Layout
  • Usually U, L or circular shaped
  • Minimizes transportation distance for operators
    (human or robotic)
  • Encourages multiple machines per operator
  • Most machines are automatic or semiautomatic,
    resulting in considerable idle time
  • In a job shop (functional layout) there is one
    operator for each machine

29
Supply Push
  • Input availability triggers production or work
  • Emphasis on keeping busy to maximize resource
    utilization as long as there is work to be done
  • Will synchronize supply with demand at each stage
    if
  • If all information (about product recipe,
    processing lead times, and part inventories) is
    accurate
  • If forecasts of finished goods are correct
  • If there is no variability in processing

30
Demand Pull
  • Output need triggers production
  • Each station produces only on demand from its
    customer station
  • Each station signals demand by picking up a part
    from its input buffer
  • The supplier station produces a new unit as a
    replacement in the buffer
  • Toyota formalized demand pull with cards called
    kanbans

31
Kanbans
  • Kanbans are attached to output flow units in the
    buffer between customer and supplier processes
  • Each card lists the following information
  • Customer process
  • Supplier process
  • Parts description
  • Production quantity

32
Kanbans
  • As the customer withdraws output flow units from
    the buffer, the attached kanban goes back to the
    supplier
  • It signals an authorization for the supplier to
    produce the listed quantity to be replaced in the
    buffer
  • Upon producing the required quantity, the
    supplier returns the output with an attached
    kanban to the buffer
  • Kanbans control buffer inventory and provide
    information and discipline to the supplier as to
    when and how much to produce
  • In the case of a process that handles multiple
    products, each supplier station must also know
    what to produce

33
Problem 2 - Test 2 Summer 2001
A B C D E F
1 1 0 0 1 0 1
2 1 1 0 0 1 0
3 1 0 1 0 0 1
4 0 1 0 0 1 0
5 0 0 1 1 0 0
6 0 0 0 0 0 0
34
Problem 2 - Test 2 Summer 2001
A B C D E F
1 1 0 0 1 0 1
2 1 1 0 0 1 0
3 1 0 1 0 0 1
4 0 1 0 0 1 0
5 0 0 1 1 0 0
6 0 0 0 0 0 0
35
Problem 2 - Test 2 Summer 2001
A B C D E F
1 1 0 0 1 0 1
2 1 1 0 0 1 0
3 1 0 1 0 0 1
4 0 1 0 0 1 0
5 0 0 1 1 0 0
6 0 0 0 0 0 0
36
Problem 2 - Test 2 Summer 2001
A B C D E F
1 1 0 0 1 0 1
2 1 1 0 0 1 0
3 1 0 1 0 0 1
4 0 1 0 0 1 0
5 0 0 1 1 0 0
6 0 0 0 0 0 0
37
Problem 2 - Test 2 Summer 2001
A B C D E F
1 1 0 0 1 0 1
2 1 1 0 0 1 0
3 1 0 1 0 0 1
4 0 1 0 0 1 0
5 0 0 1 1 0 0
6 0 0 0 0 0 0
Thus all parts require all machines and only cell
is formed
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