Facility Decisions

1. Facility Decisions • Learning objectives: • To discuss facility location decisions • To discuss capacity planning • To discuss factory layout problems • Reading: Chapter 5 and its supplement

2. Location Problems • Where should a facility be located: • Given a range of qualitative and quantitative decision variables

3. Qualitative Location Factors • Local Infrastructure • Institutional (e.g., reliable electrical power grid) • Transportational (e.g., railway systems) • Worker Education and Skills • Education and skills of local workers. • Product Content Requirements • The minimum percentage of product that must be produced in a country in order for the product to be sold in that country. • Political/Economic Stability

4. Quantitative Location Factors • Labor Costs • Labor costs vary dramatically, depending on location. Cheap labor often lacks needed education and skills. • Distribution Costs • Distance and the time required to deliver products can offset lower location costs. • Facility Costs • Special economic zones (SEZ) • Duty-free areas established to attract foreign investment in the form of manufacturing facilities

5. Quantitative Location Factors • Exchange Rates • Variations in rates can have a significant effect on sales and profits. • Tax Rates • Taxes vary considerably between countries and within countries. • All forms of taxes should be considered (property, payroll, inventory, and investment taxes).

6. Geographic Information Systems (GIS) • Computer tool that assesses alternative locations for operations. • Provides a “bird’s eye view” of a particular region of interest.

7. Evaluating Potential Locations • Factor Rating System • Identify the specific criteria or factors to be considered. • Assign a weight to each factor. • Select a common scale for rating each factor. • Rate each potential location on each of the factors. • Multiply each factor’s score by its weight. • Sum the weighted scores and select the location with the highest score.

8. Factor-Rating System Example

9. Evaluating Potential Locations • Center of Gravity Method • Used to determine the optimal location of a facility based on minimizing the transportation costs between where the goods are produced and where they are sold or redistributed. • Locate each existing operation on an X and Y coordinate grid map. • Calculate X coordinate of center of gravity • Calculate Y coordinate of center of gravity

10. Center of Gravity Formulas Cx= X coordinate of the center of gravityCy = Y coordinate of the center of gravitydix = X coordinate of the ith locationdiy = Y coordinate of the ith locationVi= Volume of goods transported to the ith location

11. Y Q (790,900) D (250,580) A (100,200) (0,0) X Example Several automobile showrooms are located according to the following grid which represents coordinate locations for each showroom Question: What is the best location for a new Z-Mobile warehouse/temporary storage facility considering only distances and quantities sold per month?

12. Y New location of facility Z about (443,627) Q (790,900) Z D (250,580) A (100,200) (0,0) X Example You then compute the new coordinates using the formulas: You then take the coordinates and place them on the map:

13. Capacity Planning • Establishes the overall level of productive resources for a firm • Usually results in a capital investment decision – long term focus • These decisions are usually irreversible! • Given: • a sales forecast • a risk profile (aggressive, risk-averse, etc.)

14. Measuring Capacity • Objective is to measure a level of activity • Several possible measures, based either on staff or plant/equipment • An hospital would measure capacity according to its number of beds or overall capacity • different units for emergency room (staff) • A building contractor would measure a project in terms of staff • Precision machinist: Machine hours per month

15. Measuring Capacity • It is important to differentiate: • Planned capacity: • the theoretical capacity of a system given some allowances • Actual capacity: • the actual demand of the usage of resources, under- or over-capacity • Efficiency: • the degree to which production is as efficient as planned

16. Example • A precision machinist has a theoretical capacity of 15,000 hours. In a given month, 16,000 hours were sold. 3,000 hours were subcontracted. • This case: • is an example of under-capacity • is an example of 100% utilisation • the efficiency is 87% (13,000/15,000)

17. Capacity Planning: Decision objectives • Decisions objectives are: • Anticipate growth or wait? • Forecast the end of a growth period • Avoid overcapacity (unit cost consequence!) • What should be done in the case of over-capacity? Size of operations unit Timing of capacity

18. Best Operating Levels With Economies & Diseconomies Of Scale

19. Timing of capacity Units Capacity lag strategy Units Capacity Demand Capacity lead strategy Capacity Demand Time Time Units Capacity One-step expansion Average capacity strategy Incremental expansion Demand Demand Time

20. Layout Decisions • How should machines, workers, departments, etc. be arranged? • Several generic options

21. Types of Layout

22. Process or Functional Layout • Job and batch systems are based on functional layouts • machines, processes and equipment of the same type are grouped together in the same department or area

23. Product Layout • High volume production systems use product layouts • machines, equipment and workplaces are arranged according to the order in which operations need to be carried out to produce a complete component, product or sub‑assembly (lines, flow systems)

24. Flexible Line Layouts

25. Design Methods – Process Layouts

26. Design Methods – Process Layouts

27. Design Methods – Process Layouts Total cost: $2,223 ($1 for adjacent departments - $1 for each travel-through)

28. Improvement: 3-5 Permutation *Only interdepartmental flow with effect on cost is depicted. Total cost: $1,878 (= $2,223 – 230 + 50 - 165)

29. Labour resources and physical facilities Finished products Material inputs Assembly Line Balancing • Means the design of the layout of an efficient assembly line • Product Layout • Also called flowlines, as product flows through workstations • Is also a pre-schedule of operations

30. Tasks to be allocated to work stations Work stations Flow of material Objective: To find the best allocation of tasks which will produce the desired output while maximising efficiency and achieving good 'balance' Problem Statement

31. Idle time Cycle time Station work content Line Balancing • The main objective of line design will be to maximise line efficiency (or minimise total work station idle time) • At the same time any idle time should be spread as evenly as possible among the work stations, ie the line should be 'balanced'

32. Procedure • Summarise precedence data in a table • Draw a precedence diagram • Compute the desired cycle time • Compute the theoretical number of workstations • Assign tasks to workstation (heuristics) • Draw layout and compute efficiency

33. Example • Cold Sheffield Ltd needs 5 tasks to assemble its product. It has 1200 minutes of assembly workforce time available per day and it needs to produce 100 units per day. Precedence relationships between the task are: • Tasks Time Predecessors • A 4 (mn) None • B 5 A • C 2 B • D 10 A • E 3 C,D • Design a balanced assembly line.

34. Draw a Precedence Diagram 5 2 B C 4 A 10 3 D E

35. Cycle Time Computation • Target output: 100 units/day • Target cycle time: • The number of minutes to complete work at one workstation • A measure of the frequency with which products roll off the assembly line • Available work time: 1200 minutes per day production time available desired output C = 1200 100 C = = 12 minutes / units

36. Theoretical Number of Workstations Theoretical number of workstations Sum of elementary tasks time Cycle Time = = 24 / 12 = 2

37. Task Assignment Workstation 1 (11 minutes) 5 4 2 B A C 10 3 D E

38. Task Assignment Workstation 1 (11 minutes) 5 4 2 B A C 10 3 D E Workstation 2 (10 minutes) Workstation 3 (3 minutes) (Alternative AB and CD)

39. Summary of Solution Linear layout Workstation 1 (ABC)- 11 mn Workstation 2 (D)- 10 mn Workstation 3 (E)-3 mn Efficiency of line = 24 / 3 * 12 = 24/36 = 66.7% (sum of tasks time divided by number of workstations times cycle time)

40. Low Efficiency • Although with 2 workstations, there would be enough time to complete all tasks (24 mn), the tasks cannot be combined in a linear layout in 2 workstations! • Try alternative forms of layouts • U-shaped layouts • Gives the option to combine non sequential tasks

41. U-Shape Layout Solution Workstation 1 Workstation 2 A,B C,D E 12 mn 12 mn Line is perfectly balanced – 100% efficiency

42. Class Exercise Problem 5-1, p. 190 Problem 5-11, p. 192

43. Suggested Homework • Solved Problems p. 188 • Problem 5-2 p. 191 • Problem 5-12 p. 192 • Problems S5-1, S5-2, p. 210