1. Fundamentals of Production Planning and Control Chapter 5 Inventory Management

2. Basic Inventory Concepts  Inventory is stored capacity  Inventory is a symptom not a problem

3. Categories of Inventory  Sources of demand  Position of the inventory in the process  Function or use of the inventory

4. Sources of Demand  Independent Demand (Forecasting/EOQ)  Dependent Demand (MRP or Kanban)

5. Position of the Inventory  Raw Materials  Work in Process (WIP)  Finished Goods  Maintenance, Repair, and Operations (MRO)

6. Function of the Inventory  Transit or Transportation Inventory  Cycle or Lot-Size Inventory  Buffer or Fluctuation Inventory  Anticipation Inventory  Decoupling Inventory  Hedge Inventory

7. Cost of Inventory  Not Having Inventory  Having Inventory

8. Costs of Not Having Inventory  Stockouts/Customer Goodwill  Excessive Setups (split lots)  Expediting  Backorders  Extra Shipping Expenses  Production rate problems  Poor facility utilization

9. Costs of Having Inventory  Setup Costs/Order Costs  Holding Costs

10. Setup Costs/Order Costs  Manufacturing – cost of changeover  Lost production  Cost of scrap incurred  Purchasing - cost of placing an order  Paperwork for making purchase  Cost of receiving

11. Holding Costs  Rent, lease, mortgage  Utilities  Maintenance  Tracking and monitoring of inventory  Damage/spoilage  Pilferage/shrinkage  Obsolescence  Taxes and Insurance  Interest (cost of capital)

12. Calculation of Holding Cost  H – cost of holding a unit in inventory  H = rP  P – unit production/procurement cost  r – percentage based on cost of capital

13. EOQ Model TC – Total Cost D – Annual Demand C – Cost per item Q – order quantity per order H – holding cost per year (Ci) S – order or setup cost

14. EOQ Model

15. Economic Order Quantity (EOQ)

16. EOQ Example A company decides to establish an EOQ for an item. The annual demand is 400,000 units, each costing $8.00, ordering costs are $32 per order, and inventory carrying costs are 20%. Calculate the EOQ

17. EOQ Example

19. How many orders will they place per year?

20. EOQ Example

21. What are the costs of ordering the cost of carrying and the total cost?

22. EOQ Example

23. Economic Order Quantity (EOQ)  Demand is constant, continuous, and known  Demand is independent  Set cost is fixed  Holding cost is known and constant  Total holding cost is a linear function of lot size  Instantaneous replenishment  Unit purchase cost is fixed (no quantity discounts or production economies)  Stockouts do not occur

24. Problems with EOQ-based Methods  Assumptions limit applicability  Demand is rarely constant and known  Costs are difficult to identify  Replenishment is not instantaneous

25. EOQ Model is Robust

26. Inventory Pattern over Time Time Inventory Level 0 EOQ

27. Relax Instantaneous Replenishment Assumption  Replenishment Lead Time - The time it takes from order until arrival  Must reorder before zero point is reached

28. Determination of Reorder Point Time Inventory Level 0 EOQ Lead Time Reorder Point

29. Reorder Point Calculation

30. Reorder Point Example Lead time for the previous product is 2 weeks. What is the Reorder Point (assume 50 weeks in a year)?

31. Reorder Point Example

32. Relax Additional Assumptions  Things can disrupt the conditions established  Supplier late  Demand exceeds expectations  Maintain safety stock

33. Safety Stock Calculation

34. Z-scores  90% customer service level, z = 1.29  95% customer service level, z = 1.65  99% customer service level, z = 2.33

35. Reorder Point with Safety Stock

36. Safety Stock Example Assume the standard deviation of demand is 1000 units. If the company wants to maintain a 95% customer service level, what should safety stock be and the new reorder point?

37. Safety Stock Example

38. Inventory Control Having the right stuff in the right place at the right time

39. Location Approaches  Fixed or Home Locations  Floating or Random Locations  Combinations  Zoned Random  Home with Reserve Stock

40. ABC inventory control  Uses Pareto’s law  About 20% of the items account for 80% of the dollar usage  About 30% of the items account for 15% of the dollar usage  About 50% of the items account for 5% of the dollar usage

41. Steps in making an ABC analysis 1. Determine the annual usage for each item 2. Multiply the annual usage of each item by its item cost to get is total annual dollar usage 3. List the items according to their annual dollar usage

42. Steps (continued) 4. Calculate the cumulative annual dollar usage and the cumulative percentage of items 5. Exam the annual usage distribution and group the items into A,B, and C groups based on the percentage of annual usage.

43. ABC Example (Steps 1 and 2) Part NumberUnit UsageUnit Cost $Annual $ Usage 11,1002$2,200 26004024,000 31004400 41,3001 5100606,000 61025250 71002200 81,50023,000 92002400 105001 TOTAL5,510 38,250

44. ABC Example (Steps 3 and 4) Part NumberAnnual $ UsageCumulative $ Usage Cumulative % $ usage 2$24,00024,00062.75 56,00030,00078.43 83,00033,00086.27 12,20035,20092.03 41,30036,50095.42 1050037,00096.73 940037,40097.78 340037,80098.82 625038,05099.48 720038,250100

45. ABC Example (Step 5) Part NumberCumulative % $ usage Cumulate % of items Class 262.7510A 578.4320A 886.2730B 192.0340B 495.4250B 1096.7360C 997.7870C 398.8280C 699.4890C 7100 C

46. Control Based on ABC Classification  Have plenty of low-value items  Use the money and control effort saved to reduce the inventory of high-value items

47. A Items – tight control  Complete accurate inventory records  Regular and frequent review by management  Frequent review of demand forecasts  Close follow-up and expediting to reduce lead time

48. B Items – Normal Controls  Good records  Regular attention  Normal processing

49. C items – Simple or No Records  2–bin system or periodic review system  Order large quantities  Carry safety stock

50. Importance of inventory accuracy  Allows firms to maintain customer service  Operate efficiently and effectively

51. Inaccurate records cause  Lost sales  Shortages and disrupted schedules  Excess inventory  Low productivity  Poor delivery performance  Excessive expediting

52. Causes of inventory record errors  Unauthorized withdrawal of material  Unsecured stockroom  Poorly trained personnel  Inaccurate transaction recording  Poor transaction recording systems  Lack of audit capability to catch mistakes

53. Inaccurate Transaction Recording  Inaccurate piece counts  Unrecorded transactions,  Delay in recording transactions  Inaccurate material location  Incorrectly identified parts

54. Measuring inventory record accuracy  Record accuracy = Number of records within tolerance/total number of records  Tolerance – amount of variation permitted due to  Inaccuracies of count  Expense of perfect accuracy

55. Inventory Accuracy Example Part Number Inventory Record Shelf CountToleranceCount OK? 11001055%X 2100 0%X 3100983%X 4100972% 51001022%X 61001032% 7100993%X 8100 0%X 9100975%X 10100995%X

56. Auditing accuracy  Physical Inventory  Cycle Counting

57. Physical Inventory Process  Housekeeping  Identification  Training  Take inventory

58. Taking the inventory Count items and record the count on a ticket left on the item  Verify this count by recounting or by sampling  When the verification is finished collect the tickets and list the items in each department  Reconcile the inventory records for differences between the physical count and inventory records

59. Disadvantages  Lost production time  Not accurate  Have people counting that don’t really understand  Often more errors are introduced  Expensive  Not timely

60. Cycle Counting  Advantages  Timely detection and correction of problems  Partial reduction of lost production  Use of personnel trained and dedicated to cycle counting

61. When to count  When an order is placed  When an order is received  When inventory reaches zero  When a specified number of transactions have occurred  When an error occurs  Randomly generated using ABC

62. ABC method Count parts on a rotating cycle based an ABC classification  A – 12 times per year  B - 4 times per year  C –1 time per year

63. Additional Cycle Counting Techniques  Location Audit System  Zone Method

64. Location audit system  If using ABC counts and floating locations  System only counts what it thinks is there  Count every location a specified number of times

65. Zone method Items are grouped by zones to make counting more efficient

66. Homework  Problems 3 (assume slow season lasts 6 months), 6 and 7