Capacity Planning For Products and Services Facility Planning Facility planning answers: What kind of capacity is needed? How much capacity is needed? When more capacity is needed? Where facilities should be located (location) How facilities should be arranged (layout) Capacity (Definition of) The number of units a facility can hold, receive, store or produce in a period of time It is the upper limit or ceiling on the load that an operating unit can handle. It includes equipment, space, employee skills Capacity Planning Establishes overall level of productive resources Affects lead time responsiveness, cost & competitiveness Determines when and how much to increase capacity Types of Planning Over a Time Horizon Long Range Planning Intermediate Range Planning Add Facilities Add long lead time equipment Sub-Contract Add Equipment Add Shifts *Limited options exist Add Personnel Build or Use Inventory * Short Range Planning Modify Capacity * Schedule Jobs Schedule Personnel Allocate Machinery Use Capacity Importance of Capacity Decisions 1. 2. 3. 4. 5. 6. 7. 8. Impacts ability to meet future demands Affects operating costs Major determinant of initial costs Involves long-term commitment Affects competitiveness Affects ease of management Globalization adds complexity Impacts long range planning Capacity Measures Design capacity Maximum output rate or service capacity an operation, process, or facility is designed for Effective capacity Capacity a firm can expect to attain given its product mix, methods of scheduling, maintenance and standards of quality. Design capacity minus allowances such as personal time, maintenance and scrap Capacity Related Concepts Actual output Rate of output actually achieved—cannot exceed effective capacity Utilization Actual output as a percent of design capacity Efficiency Actual output as a percent of effective capacity Actual or Expected Output Actual (or Expected) Output = (Effective Capacity)(Efficiency) Efficiency Measure of how well a facility or machine is performing when used Efficiency = Actual output Effective Capacity (expressed as a percentage) Utilization Measure of planned or actual capacity usage of a facility, work center, or machine Utilization = Actual Output Design Capacity (expressed as a percentage) Efficiency/Utilization Example Design capacity = 50 trucks/day Effective capacity = 40 trucks/day Actual output = 36 units/day Actual output = 36 units/day Efficiency = = 90% Effective capacity Utilization = Actual output Design capacity 40 units/ day = 36 units/day 50 units/day = 72% Determinants of Effective Capacity Facilities Product and Service Factors Process Factors Human Factors Policy Factors Operational Factors Supply Chain Factors External Factors Key Decisions in Capacity Planning 1. Amount of capacity needed 2. Timing of changes (frequency of capacity additions) 3. Need to maintain balance 4. Extent of flexibility of facilities 5. External sources of capacity Steps for Capacity Planning 1. 2. 3. 4. 5. 6. 7. 8. Estimate future capacity requirements Evaluate existing capacity Identify alternatives Conduct financial analysis Assess key qualitative issues Select the best alternative Implement the alternative chosen Monitor results Calculating Processing Requirements: Example 1 (1 of 2) Standard processing time per unit (hr.) Product Annual Demand Processing time needed (hr.) #1 400 5.0 2,000 #2 300 8.0 2,400 #3 700 2.0 1,400 5,800 Calculating Capacity Requirements Example 1 (2 of 2) If the department works one eight hour shift, 250 days a year, calculate the number of machines that would be needed to handle the required volume. Solution: 5800/(250)(8) = 2.9 3 machines are needed Special Requirements for Making Good Capacity Decisions Forecasting the demand accurately Understanding the technology and capacity increments Finding the optimal operating level (volume) Build for change Make or Buy 1. 2. 3. 4. 5. 6. Available capacity Expertise Quality considerations Nature of demand Cost Risk Economies of Scale Economies of scale If the output rate is less than the optimal level, increasing output rate results in decreasing average unit costs Diseconomies of scale If the output rate is more than the optimal level, increasing the output rate results in increasing average unit costs Average cost per room Best Operating Levels Best operating level Economies of scale 250 Diseconomies of scale 500 # Rooms 1000 Economies of Scale Average cost per unit Minimum cost & optimal operating rate are functions of size of production unit. 0 Small plant Medium plant Large plant Volume Economies & Diseconomies of Scale Economies of Scale and the Experience Curve working Average unit cost of output 100-unit plant 200-unit plant 300-unit plant 400-unit plant Diseconomies of Scale start working Volume The Experience Curve As plants produce more products, they gain experience in the best production methods and reduce their costs per unit Yesterday Cost or price per unit Today Tomorrow Total accumulated production of units Strategies for Matching Capacity to Demand 1. Making staffing changes (increasing or decreasing the number of employees) 2. Adjusting equipment and processes – which might include purchasing additional machinery or selling or leasing out existing equipment 3. Improving methods to increase throughput; and/or 4. Redesigning the product to facilitate more throughput Capacity Expansion Volume and certainty of anticipated demand Strategic objectives for growth Costs of expansion and operation Incremental or one-step expansion Frequency of capacity additions Capacity Expansion Strategies Expected Demand Expected Demand New Capacity Demand Demand New Capacity Time in Years Capacity leads demand with an incremental expansion Time in Years Capacity leads demand with a one-step expansion Expected Demand New Capacity New Capacity Time in Years Capacity lags demand with an incremental expansion Demand Demand Expected Demand Time in Years Attempts to have an average capacity, with an incremental expansion Issues in Capacity Management 1. Design flexibility into systems 2. Take stage of life cycle into account 3. Take a “big picture” approach to capacity changes 4. Prepare to deal with capacity “chunks” 5. Attempt to smooth out capacity requirements 6. Identify the optimal operating level Capacity Planning: Balance Unbalanced stages of production Units per month Stage 1 Stage 2 6,000 7,000 Stage 3 5,000 Maintaining System Balance: Output of one stage is the exact input requirements for the next stage Balanced stages of production Units per month Stage 1 Stage 2 6,000 6,000 Stage 3 6,000 Bottleneck Operation Machine #1 Machine #2 Bottleneck operation: An operation in a sequence of operations whose capacity is lower than that of the other operations 10/hr 10/hr Machine #3 Bottleneck Operation 10/hr Machine #4 10/hr 30/hr Bottleneck Operation Bottleneck Operation 1 20/hr. Operation 2 10/hr. Operation 3 15/hr. Maximum output rate limited by bottleneck 10/hr. Capacity Flexibility Flexible plants Flexible processes Flexible workers Evaluating Alternatives Cost-volume analysis Break-even point Financial analysis Cash flow Present value Decision theory Waiting-line analysis Amount ($) Cost-Volume Relationships (1 of 3) Fixed cost (FC) 0 Q (volume in units) Amount ($) Cost-Volume Relationships (2 of 3) 0 Q (volume in units) Amount ($) Cost-Volume Relationships in Making Capacity Decisions (3 of 3) 0 BEP units Q (volume in units) Break-Even Problem with Step Fixed Costs (1 of 2) 3 machines 2 machines 1 machine Quantity Step fixed costs and variable costs. Break-Even Problem with Step Fixed Costs (2 of 2) $ BEP 3 TC BEP2 TC 3 TC 2 1 Quantity Multiple break-even points Assumptions of Cost-Volume Analysis 1. One product is involved 2. Everything produced can be sold 3. Variable cost per unit is the same regardless of volume 4. Fixed costs do not change with volume 5. Revenue per unit constant with volume 6. Revenue per unit exceeds variable cost per unit Decision Theory Helpful tool for financial comparison of alternatives under conditions of risk or uncertainty Suited to capacity decisions Waiting-Line Analysis Useful for designing or modifying service systems Waiting-lines occur across a wide variety of service systems Waiting-lines are caused by bottlenecks in the process Helps managers plan capacity level that will be cost-effective by balancing the cost of having customers wait in line with the cost of additional capacity Strategy Driven Investment Select investments as part of a coordinated strategic plan Choose investments yielding competitive advantage Consider product life cycles Include a variety of operating factors in the financial return analysis Test investments in light of several revenue projections Financial Analysis Cash Flow - the difference between cash received from sales and other sources, and cash outflow for labor, material, overhead, and taxes. Present Value - the sum, in current value, of all future cash flows of an investment proposal. Net Present Value F = future value P = present value F P N I = interest rate (i 1) N = number of years Planning Service Capacity Inability to store services: Capacity must be available to provide a service when it is needed (capacity must be matched with the timing of demand) Need to be near customers: Capacity and location are closely tied. Service goods must be at the customer demand point and capacity must be located near the customer Volatility of Demand: Much greater than in manufacturing Capacity Utilization & Service Quality Best operating point is near 70% of capacity From 70% to 100% of service capacity, what do you think happens to service quality? Extras Managing Existing Capacity Demand Management Capacity Management Vary prices Vary promotion Change lead times (e.g., backorders) Offer complementary products Vary staffing Change equipment & processes Change methods Redesign the product for faster processing Complementary Products Sales (Units) 5,000 4,000 3,000 2,000 1,000 0 Total Snowmobiles Jet Skis J M M J S N J M M J S N J Time (Months)
