1. The philosophy of JIT can be traced back to Henry Ford, but formalized JIT originated in Japan as the Toyota Production System. W. Edwards Deming’s lesson of variability reduction was a huge influence. The focus of JIT is to improve the system of production by eliminating all forms of WASTE. Just-In-Time Philosophy JIT is a long-term approach to process improvement. It uses timeliness as a lever to lower costs, improve quality and improve responsiveness. However, JIT requires enormous commitment. It took Toyota more than 25 years to get right!

2. Just-in-Time Downstream processes take parts from upstream as they need. – Get what you want – when you want it – in the quantity you want.

3. 4. Just In Time-- What is It? Just-in-Time: produce the right parts, at the right time, in the right quantity – Requires repetitive, not big volume – Batch size of one – Short transit times, keep 0.1 days of supply

4. Characteristics of Just-in-Time  Pull method of materials flow  Consistently high quality  Small lot sizes  Uniform workstation loads  Standardized components and work methods  Close supplier ties  Flexible workforce  Line flows  Automated production  Preventive maintenance

5. 16-5 Push versus Pull Push system: material is pushed into downstream workstations regardless of whether resources are available Pull system: material is pulled to a workstation just as it is needed

6. From a a « push » to a « pull » System Work is pushed to the next station as it is completed SUPPLIERSSUPPLIERS CUSTOMERSCUSTOMERS

7. A workstation pulls output as needed SUPPLIERSSUPPLIERS CUSTOMERSCUSTOMERS From a a « push » to a « pull » System

8. JIT Demand-Pull Logic Customers Sub Fab Vendor Final Assembly Here the customer starts the process, pulling an inventory item from Final Assembly… Then sub-assembly work is pulled forward by that demand… The process continues throughout the entire production process and supply chain

9. Pull Versus Push Systems  A pull system uses signals to request production and delivery from upstream stations  Upstream stations only produce when signaled  System is used within the immediate production process and with suppliers

10. Pull Versus Push Systems  By pulling material in small lots, inventory cushions are removed, exposing problems and emphasizing continual improvement  Manufacturing cycle time is reduced  Push systems dump orders on the downstream stations regardless of the need

11. Waste in Operations 1.Waste from overproduction 2.Waste of waiting time 3.Transportation waste 4.Inventory waste 5.Processing waste 6.Waste of motion 7.Waste from product defects 8.Underutilization of people

12. Streamlined Production Flow with JIT Traditional Flow Customers Suppliers Customers Suppliers Production Process (stream of water) Inventory (stagnant ponds) Material (water in stream)

13. Lowering Inventory Reduces Waste WIP hides problems

14. Lowering Inventory Reduces Waste WIP hides problems

15. Lowering Inventory Reduces Waste Reducing WIP makes problem very visible STOP

16. Lowering Inventory Reduces Waste Reduce WIP again to find new problems

17. Reduce Variability Inventory level Process downtime Scrap Setup time Late deliveries Quality problems Figure 16.1

18. Inventory level Reduce Variability Scrap Setup time Late deliveries Quality problems Process downtime Figure 16.1

19. Causes of Variability 1.Employees, machines, and suppliers produce units that do not conform to standards, are late, or are not the proper quantity 2.Engineering drawings or specifications are inaccurate 3.Production personnel try to produce before drawings or specifications are complete 4.Customer demands are unknown

20. Variability Reduction  JIT systems require managers to reduce variability caused by both internal and external factors  Variability is any deviation from the optimum process  Inventory hides variability  Less variability results in less waste

21. Performance and WIP Level Less WIP means products go through system faster reducing the WIP makes you more sensitive to problems, helps you find problems faster Stream and Rocks analogy: – Inventory (WIP) is like water in a stream – It hides the rocks – Rocks force you to keep a lot of water (WIP) in the stream

22. Reduce Lot Sizes Figure 16.2 200 200 – 100 100 –Inventory Time Q 2 When average order size = 100 average inventory is 50 Q 1 When average order size = 200 average inventory is 100

23. Customer orders 10 Lot size = 5 Lot 1 Lot 2 Lot size = 2 Lot 1Lot 2Lot 3Lot 4Lot 5 Reducing Lot Sizes Increases the Number of Lots

24. Reduce Lot Sizes  Ideal situation is to have lot sizes of one pulled from one process to the next  Often not feasible  Can use EOQ analysis to calculate desired setup time  Two key changes  Improve material handling  Reduce setup time

25. Reduce Setup Times Use one-touch system to eliminate adjustments (save 10 minutes) Step 4 Step 5 Training operators and standardizing work procedures (save 2 minutes) Repeat cycle until subminute setup is achieved Initial Setup Time Step 2 Move material closer and improve material handling (save 20 minutes) Step 1 Separate setup into preparation and actual setup, doing as much as possible while the machine/process is operating (save 30 minutes) Step 3 Standardize and improve tooling (save 15 minutes) 90 min — 60 min — 45 min — 25 min — 15 min — 13 min — —

26. 6. Kanban When 3 finishes a part, – Finished parts move over one spot – He has to have a red tag available to put on, – He gets a part from 2’s outbound pile, – And gives the blue back to 2 3’s production will be taken by 4, offstage right. – Tag goes back into 3’s bin Flow of work 3 2

27. 6. Kanban Red finishes his part next. But 4 hasn’t freed up any of the red kanbans, so there is nothing for 3 to work on now. 3 could maintain his machine, or see if 4 needs help 3 2 3 2

28. The Number of Cards or Containers  Need to know the lead time needed to produce a container of parts  Need to know the amount of safety stock needed Number of kanbans = Demand during Safety lead time+stock Size of container

29. Number of Kanbans Example Daily demand=500 cakes Production lead time=2 days (wait time + material handling time + processing time) Safety stock=1/2 day Container size=250 cakes Demand during lead time = 2 days x 500 cakes = 1,000 Number of kanbans = = 5 1,000 + 250 250

30. Example A switch is assembled in batches of 4 units at an “upstream” work area. delivered in a bin to a “downstream” control-panel assembly area that requires 5 switch assemblies/hour. The switch assembly area can produce a bin of switch assemblies in 2 hours. Safety stock = 10% of needed inventory. 2.75 or 3 4 5(2)(1.1)  C dL (1  S) k size of container Expected demand during lead time + safety stock 

31. Scheduling Small Lots ABCAAABBBBBC JIT Level Material-Use Approach ACAAABBBBBCCBBBBAA Large-Lot Approach Time

32. 32 Minimizing Waste: Uniform Plant Loading Not uniformJan. UnitsFeb. UnitsMar. UnitsTotal 1,2003,5004,3009,000 UniformJan. UnitsFeb. UnitsMar. UnitsTotal 3,0003,0003,0009,000 Suppose we operate a production plant that produces a single product. The schedule of production for this product could be accomplished using either of the two plant loading schedules below. How does the uniform loading help save labor costs? or

33. 33 Mixed Batch Example Company produces three products with a mixed model assembly line. – Operates 16 hours per day for 250 days/yr. – Determine the mixed model MPS for a daily batch. – Determine minimum batch MPS and the mix schedule for a day. ProductsForecasts (year) 120,000 210,000 35,000

34. 34 Calculations #1#2#3 Year Forecast 20000100005000 Daily Batchdivide by 250804020 Hourly Batchdivide by 1652.51.25 Minimum Batch MPS 421 For every unit of #3 (minimum batch), we need twice as many #2 and 4 times As many #1 so for minimum batch: Produce during each day produce #1,1,1,1,2,2,3 - repeated 20 times

35. Characteristics of JIT Partnershps Few, nearby suppliers Supplier just like in-house upstream process Long-term contract agreements Steady supply rate Frequent deliveries in small lots Buyer helps suppliers meet quality Suppliers use process control charts Buyer schedules inbound freight

36. Promote flow with little WIP Facilitate workers staffing multiple machines U-shaped cells Maximum visibility Minimum walking Flexible in number of workers Facilitates monitoring of work entering and leaving cell Workers can conveniently cooperate to smooth flow and address problems Cellular Layout Inbound StockOutbound Stock

37. Group Technology An engineering and manufacturing philosophy that identifies physical similarities of parts and establishes their effective production. Assignment of individual products to product families

38. Cellular Manufacturing Assignment of product families to manufacturing cells

39. Layout Traditional – job shop approach of using widely spread-out equipment with space for stockrooms, tool cribs, and work-in-process inventories between the equipment – To handle and move all this inventory, automated or semi automated materials handling equipment (conveyors, forklifts) is required, which takes even more space. JIT – Equipment is moved as close together as possible so that parts can be actually handed from one worker or machine to the next. – Use of cells, and flow lines dictates small lots of parts with minimal work-in-process and material-moving equipment. – manual transfer

40. Group Technology (Part 1) Using Departmental Specialization for plant layout can cause a lot of unnecessary material movement Saw LathePress Grinder Lathe Saw Press Heat Treat Grinder Note how the flow lines are going back and forth

41. Group Technology (Part 2) Revising by using Group Technology Cells can reduce movement and improve product flow Press Lathe Grinder A 2 B Saw Heat Treat LatheSaw Lathe Press Lathe 1

42. Group Technology (con’d) A set of machines dedicated to processing one or more family Arrange machines in a narrow U Workers rotate among several machines

43. Group Technology (con’d)  Advantages  Reduce cycle time Move time Queue time Set up time  Adjust the output rate by increasing or decreasing the number of workers in a cell  Facilitate job training  Promote job satisfaction

44. Typical Benefits of JIT Cost savings: inventory reductions, reduced scrap, fewer defects, fewer changes due to both customers and engineering, less space, decreased labor hours, les rework. Revenue increases: better service and quality to the customer. Investment savings: less space, reduced inventory, increased the volume of work produced in the same facility. Workforce improvements: more satisfied, better trained employees. Uncovering problems: greater visibility to problems that JIT allows, if management is willing to capitalize on the opportunity to fix these problems.