Manufacturing System Flow Analysis Ronald G. Askin Systems & Industrial Engineering The University of Arizona Tucson, AZ 85721 [email protected] October 12, 2005
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Manufacturing System Flow Analysis
Ronald G. AskinSystems & Industrial Engineering
The University of ArizonaTucson, AZ 85721
October 12, 2005
How Many IEs Does It Take to Change a Light Bulb?
n?
• One to Work Sample to Detect Burned out Bulbs• One to Flowchart the Process • One to Schedule the Maintenance• One to Supervise the Maintenance Task• One to Implement a Process Improvement Plan/Kaizen
Event• One to Determine Optimal Lumens for Replacement Bulb• One to do an Economic Analysis of Buying Longer Life
Bulbs• …
Overview of Session
• The Modern (Lean) Factory• WIP vs. Flowtime & Throughput (Little’s Law)• Transfer Batches vs. Process Batches (Lot-streaming)• Cross-Training (Balancing and Buckets)• Performance Evaluation – Open & Closed Cells
1. Factory Flow Thru Cell System
Gears Chassis
Shafts Cards Frame
Assembly
Flow in a Cell
J. T. Black, Design of the Factory with a Future, 1991
Cell Independence (Burbidge)
• Dedicated Team of (Compatible) Workers• Dedicated Set of Machines• Specified Set of Parts/Products• Dedicated Space for Operations• Common Goal and Evaluation• Independence of Success• Ideally 7-10 Members
2. Little’s Law: Defining Rule for Flow
L = λW (N = XT)
WIP = Prod. Rate x Flow Time
Theoretical Profile!
Capacity Deterministic
Production
Probabilistic (Exponential)
WIP
N = X T
Empirical ProfileLittle's Law and Chaos
0
2
4
6
8
10
12
0 10 20 30 40 50 60 70 80 90
WIP
Thr
ou
ghp
ut
Deterministic
Exponential
Empirical
10 stages, µ = 1
RememberN = XT
Questions?
• What happens when we release jobs to a busy shop floor?
• What happens when we reduce variability?
Typical Scenario: High Utilization, So Jobs are Late, Therefore Release More Jobs Early
L=λW (or N=XT)1. λ high implies ∆λ small;2. Since L increases, W increases;3. As W (lead time) increases, tempted to release
jobs even earlier4. Congestion and interference reduce throughput
Reducing Variability
General Arrivals (λ) and Service (S)
( ) ( )[ ]
2 2 2 2 2
2 2
( ) ( ) ( )
1( )
2 (1 )1
q
s a s
q
s
E ThroughputTime E W E S
C C CE W
C
ρ ρλ ρρ
= +
+ +≈ ⋅
−� �+� �
( )E Sρ λ= ⋅(ρ = X ÷÷÷÷ Capacity)
Question: How Far Is the Blue (Random) Line from the Purple (Deterministic) Line?
• ρ = 0.8, • Exponential Arrivals vs. Fixed Interarrivals• Random Service vs. Standardized Service
What happens if we release jobs at fixed intervals?What happens with reliable processes & standard tasks?
3. Transfer vs. Process Batches
• Lot-Streaming – Dividing the process batch into multiple transfer batches for concurrent processing at successive stages
Simple Illustration
• Three stages• Batch size = 20• Unit proc. times = 1, 3, 2• No setup
a. One Transfer Batch
b. Two Transfer Batches
. . .
0 1 4 20 61 63
c. Single Unit Transfer Batches
Machine
1
2
3
Time 120 80 20
Machine
1
2
3
Time 10 40 70 90
Machine
1
2
3
Time
MH vs Thruput Time TradeoffMH Loads vs. Cycle Time
0
5
10
15
20
25
0 20 40 60 80 100 120 140
Cycle Time
MH Loads
Basic Rules (L Sublots, Q units)
1. Consistent, equal sublots good (not optimal)
(p2 qi = p1 qi+1 is optimal for adjacent WSs)
2. Decreasing marginal benefit:
2 sublots � 50% of max gain
3. Protect bottleneck (avoid sublot setup loss)
b ii b
QT Q p p
L ≠
= ⋅ + ⋅�
4. Cross-Training
• Ensure Redundancy• Consider Job Enrichment as Motivator• Task Frequency Sufficient for Proficiency• Lead Experts for Each Task• Cover all Responsibilities• Pay per Skill Breadth and Depth• Worker Flexibility vs. WIP Safety Stock
a. Dynamic Rebalancing
1
4 min 3 min
6 min
8 min 3 min
a. Two Workers
1
4 min 3 min
6 min
8 min 3 min
b. Three Workers
Part Flow
Worker Flow (Orbit)
Workstation
Total Time = 24
b. Bucket Brigades (TSS) & Variants
• BBAssumes Task ContinuityOrdered WorkersSlowest to FastestEffective in PickingBuffers can be added
•Champion Strategy
(For low machine ρ)
•Leapfrog Strategy
(Less worker movement)
5. Performance Evaluation
• Find X & T given N & Capacity• Find T and needed N for desired X given Capacity• Find T, X Tradeoff
N = X T
Open System (Receive and Release)
Random
Basic Poisson Process Estimate
2. Evaluate Each Workstation
(M/M/1)
P(0) = 1-ρρρρ
L = ρρρρ/(1-ρρρρ)
W = L/λλλλ
1. Compute Effective Arrival Rates at Workstations
' '
1
m
j j k kjk
pλ λ λ=
= + ⋅�
5/day
(A)
6/day (B)
2
6
4
4
5
5
System & Product Measures
3. Aggregate Across Workstations
1
m
j jj
W v W=
= ⋅�
WB= W + .67W + W
Closed System (CONWIP)External Demand
Basic Performance Evaluation - ClosedConsider a Closed System with N Jobs:
1
M
jj
C c=
=� Total Servers or Max Active Jobs
1
M
jj
P t=
=� Total Job Processing time
min( , ) so
C NT P N XT X
P≥ = → ≤
X = Production rate, T = Throughput time
Performance Evaluation Extension
• Assume WIP Evenly Spread Out
As Always, N=XT
11 , Exponential Processing Time
, Constant, Synchronous Processing with
NP
MT
NP N M
M
� −� �+ ⋅ �� ��= ��
� �� ⋅ ≥ � � �
Very Optimistic Model! No Starvation when N ≥ M
References and Extensions
1. Askin, R. & J. Goldberg, Design and Analysis of Lean Production Systems, Wiley& Sons, 2002
2. Askin, R. & C. Standridge, Modeling and Analysis of Manufacturing Systems, Wiley & Sons, 1993
3. Black, J. T., Design of the Factory with a Future, McGraw Hill, 1991
4. Harmon, R & L. Peterson, Reinventing the Factory, Free Press, 1989
5. Hopp, W. and M. Spearman, Factory Physics, McGraw Hill, 2000.
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