Post on 03-Jan-2016
Lecture 7
Production Planning System (Revisited)
Books• Introduction to Materials Management, Sixth Edition, J. R. Tony Arnold, P.E., CFPIM, CIRM, Fleming
College, Emeritus, Stephen N. Chapman, Ph.D., CFPIM, North Carolina State University, Lloyd M. Clive, P.E., CFPIM, Fleming College
• Operations Management for Competitive Advantage, 11th Edition, by Chase, Jacobs, and Aquilano, 2005, N.Y.: McGraw-Hill/Irwin.
Objectives
• Manufacturing Planning and Control System• Sales and operations planning (SOP)• Making production plan• Developing production plan• Market to stock production plan• Market to order production plan• Production planning hierarchy• Inventory cost• Type of inventory• Production settings
Manufacturing’s Objectives
• The goal of manufacturing is to produce
– The right goods
– Of the right quality
– In the right quantities
– At the right time
– At minimum cost
Four Basic Questions
What must we get?
What do wealreadyhave?
What doesit take tomake it?
What arewe goingto make?
Priority
The APICS Dictionary defines priority as “the relative importance of jobs, i.e., the sequence in which jobs should be worked on.” Priority refers to what is needed, how much is needed, and when it is needed.
Capacity
The APICS Dictionary defines capacity as “the capability of a worker, machine, work center, plant or organization to produce output per time period.”
Production Plan
Master ProductionSchedule (MPS)
Material RequirementsPlan (MRP)
Production ActivityControl (PAC)
ResourceRequirements
Plan (RRP)
Rough-CutCapacity
Plan (RCCP)
CapacityRequirements
Plan (CRP)
Input/Output Control
Operation Sequencing
Strategic BusinessPlan
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apacity Managem
ent Techniques
Manufacturing Planning and Control System
• Strategic Business PlanA statement of the major goals and objectives the company
expects to achieve over the next 2-10 years or more.– broad/general direction– low level of detail– long-range forecasts– responsibility of senior management– includes participation from Marketing, Finance, and
Production– usually reviewed every six months to a year
Manufacturing Planning and Control System
• Production Plan Concerns– Quantities of each product group required to be
produced– The desired inventory levels– The resources of equipment, labor, and material needed
in each period– The availability of resources needed
Manufacturing Planning and Control System
• Production Plan must– Satisfy market demand within resources available– Assist the implementation of the strategic business plan– Be based upon families of products– Be fairly low level of detail– Address a planning horizon of six to 18 months– Be reviewed each month or quarter
Manufacturing Planning and Control System
• Master Production ScheduleA plan for the production of individual end items (finished
goods). – breaks down production plan– list the quantity of each end item to be made– level of detail is higher than the production plan -
developed for individual end items– planning horizon extends three to 18 months– reviewed and changed weekly or monthly
Manufacturing Planning and Control System
• Material Requirements PlanA plan for the production and purchase of the components
used in making the items in the MPS– Production control and purchasing use MRP to decide
the purchase or manufacture of specific items– Level of detail is high– Determines when the components and parts are needed – Planning horizon is at least as long as the combined
purchase and manufacture lead times (3 to 18 months)– Usually reviewed daily or weekly
Manufacturing Planning and Control System
• Production Activity Control and Purchasing– Represents the implementation and control phase of the
production planning and control system– Purchasing is responsible for establishing and
controlling the flow of raw materials into the factory– PAC is responsible for planning and controlling the
flow of work through the factory– Planning horizon is very short, a day to a month– Level of detail is high– Reviewed and revised daily
Manufacturing Planning and Control System
– What are the priorities - how much of what is to be produced and when?
– What is the available capacity - what resources do we have? • Can we outsource?
– How can differences between priorities and capacity be resolved?
2 At each level in the MPCS, three questions must be answered:
Manufacturing Resource Planning (MRP II)
• Manufacturing resource planning (MRP II) is a method for the effective planning of all resources of a manufacturing company. Ideally, it addresses operational planning in units, financial planning in dollars, and has a simulation capability to answer “what if” questions. It is made up of a variety of functions, each linked together: business planning, sales and operations planning, production planning, master production scheduling, material requirements planning, capacity requirements planning, and the execution support systems for capacity and material. Output from these systems is integrated with financial reports such as the business plan, purchase commitment report, shipping budget, and inventory projections in dollars.
APICS Dictionary, 8th edition, 1995
Sales and operations planning (SOP)
• Medium time range• Benefits:
– Provides a means of updating the strategic business plan
– Provides a means of managing change– Permits better management of production, inventory
and backlog
Making the Production Plan
• Purpose
Production planning is
. . . setting the overall level of manufacturing output . . . and other activities to best satisfy the current planned levels of sales . . . while meeting general business objectives of profitability, productivity . . . etc., as expressed in the overall business plan.
APICS Dictionary, 8th edition, 1995
Making the Production Plan
• Production planning is concerned with– The quantities of each product group in each period. – The desired inventory levels.– The resources of equipment, labor, and material needed in
each period.– The availability of needed resources.
• Why are plans made for product groups?• What should the product groups be based on?
Making the Production Plan
• Production planning characteristics– The time horizon may be more or less than 12
months, depending on the manufacturing cycle.– Demand is seasonal for many products, but not for
all. Seasonal demand is the worst-case scenario.– A plan is made for families or groups.– Management will have a variety of objectives.
• What might be some management objectives?
Developing the Production Plan
• Three Basic Strategies – Chase (Demand Matching) Strategy: Produce the
amounts that are demanded at any one time– Production Leveling Strategy: Continuously
produce an amount equal to the average demand– Subcontracting: Meeting additional demand
through subcontracting.
• Hybrid Strategy: Combination of any of the above strategies
Developing the Production Plan
Chase (demand matching) StrategyThe goal is to produce the amounts demanded at any
given time. Inventory levels remain stable while production varies to meet demand
Uni
ts
1 2 3 4 5 6 7 8 9 10 11 12Periods
Developing the Production Plan
• Chase Strategy Disadvantages– As production increases, workers must be hired and
trained. Extra shifts may be needed, and overtime may be necessary. These requirements all increase cost.
– As production decreases, people are laid off and morale suffers,
– When production starts to increase again, the best workers may have other jobs and their skills will not be available.
Developing the Production Plan
• Chase Strategy Disadvantages (continued)– Manufacturing must have enough plant capacity to
produce at the highest capacity needed.
• What industries use a chase strategy?
Developing the Production Plan
• Production Leveling Strategy
The goal of this strategy is to continuously produce an amount equal to the average demand.
1 2 3 4 5 6 7 8 9 10 11 12
Uni
ts
Periods
Developing the Production Plan
• Production Leveling Strategy– This strategy avoids the disadvantages of demand
matching. However, inventory builds up.
• What are some examples of industries that could use this strategy?
Developing the Production Plan
• Subcontracting Strategy– Subcontracting means always producing at the level
of minimum demand and meeting any additional demand through subcontracting
• Major Advantage– Costs associated with excess capacity are avoided– Since production is leveled, there are no costs
associated with changing production levels
Developing the Production Plan
• Subcontracting Strategy - Disadvantage– The cost of purchasing may be greater than if the
item were made in the plant– Certain core skills or technologies may be lost
Developing the Production Plan
• Hybrid Strategy– Combination of any of the three previous strategies– Production management is responsible for finding the
combination of strategies that minimizes the sum of all costs involved, providing the level of service required, and meeting the objectives of the financial and marketing plans
Developing a Make-to-Stock Production Plan
• Under a make-to-stock production plan, goods are put into inventory and sold from inventory. It is used when– Demand is fairly constant and predictable– Only a few product options exists– Required delivery times are shorter than the time
needed to make the product– Product has a long shelf life
• Information needed for a make-to-stock production plan includes– A forecast by time period for the planning horizon– Opening inventory– Desired ending inventory
• The objective in developing a production plan is to minimize the costs of carrying inventory, changing production levels, and stocking out (not supplying the customer what is wanted when it is wanted).
Developing a Make-to-Stock Production Plan
Making a Level Production Plan
• Procedure for Level Production– Total the forecast demand for the planning horizon– Determine the opening inventory and the desired
ending inventory– Calculate the total production– Calculate the production required each period by
dividing the total production by the number of periods
– Calculate the ending inventory for each period
Making a Level Production Plan
Period 1 2 3 4 5 Total Forecast Demand 110 120 130 120 120 Production Ending Inventory
Example Problem: (Pg. 29/33)
Opening inventory (OI) = 100 unitsDesired ending inventory (EI) = 80 units
Total production needed = total forecast demand + EI - OI = _____ + _____ - _____ = _______ units
Production each period = 5
units
Making a Level Production Plan
Ending Inventory for Period 1 = OI + production - forecast demand= ______ + ______ - ______ = ______ units
Making a Level Production Plan
• How much should be produced each period?• What is the ending inventory for each period?• If the cost of carrying inventory is $5 per case per period
based on ending inventory, what is the total cost of carrying inventory?
• What will be the total cost of the plan?
Making a Level Production Plan
Answer:a. Total production required = 600 + 80 - 100 = 580 cases
b. Ending inventory = OI + production - demand
Ending inventory after the first period = 100 + 116 - 110
= 106 cases
Ending inv. for period 1 becomes the opening inv. for period 2
Ending inventory (period 2) = 106 + 116 - 120 = 102 cases
Production each period = 5805
= 116 cases
Making a Level Production Plan
Answer: (continued)
c. The total cost of carrying inventory would be:
(106 + 102 + 88 + 84 + 80)($5) = $2300
d. There were no stockouts and no changes in the level of production, $2300 is the total cost of the plan:
Period 1 2 3 4 5 Total Forecast (cases) 110 120 130 120 120 600 Production 116 116 116 116 116 580 Ending Inventory / 100 106 102 88 84 80
Developing a Make-to-Order (Chase Strategy) Production Plan
Using preceding example, suppose that changing the production level by one case costs $20.
A change from 50 to 60 would cost
(60 - 50)($20) = $200
Opening inventory is 100 cases, and the company wishes to bring this down to 80 cases in the first period
110 - (100 - 80) = 90 cases
Developing a Make-to-Order (Chase Strategy) Production Plan
Cost of changing production level = (60)($20) = $1200
Cost of carrying inventory = (80 cases)(5 periods)($5) = $2000
Total cost of the plan = $1200 + $2000 = $3200
Period 0 1 2 3 4 5 Total Demand (cases) 110 120 130 120 120 600 Production 100 90 120 130 120 120 580 Change in Production 10 30 10 10 0 60 Ending Inventory 100 80 80 80 80 80
Assemble to Order
• Assemble-to-order is a subset of make-to-order– several product options exists– customer is not willing to wait until the product is made– manufacturers assemble the component parts from
inventory according to the order– Examples: automobiles and computers
Developing a Make-to-OrderProduction Plan
• Information needed for make-to-order products– Forecast by period for the planning horizon– Opening backlog of customer orders– Desired ending backlog
• BacklogUnfilled customer orders that will be delivered in the future.
Resource Requirements Planning
• The preliminary production plan must be compared with the existing resources of the company. Two questions must be answered:– Are the required resources available?– If not, how will the differences be reconciled?
• Helpful tool is the resource bill or bill of resources
Resource Requirements Planning
• Resource bill or Bill of Resources– shows the quantity of critical resources (materials,
labor, and “bottleneck” operations) needed to make one average unit of the product group
Product Wood(board feet)
Labor(standard hours)
Tables 20 1.31Chairs 10 0.85Stools 5 0.55
Bill of Resources
Production Planning Hierarchy
Master Production Scheduling
Production Planning and Control Systems
Pond DrainingSystems
Aggregate Planning
PushSystems
PullSystems
Focusing onBottlenecks
Long-Range Capacity Planning
Production Planning Horizons
Master Production Scheduling
Production Planning and Control Systems
Pond DrainingSystems
Aggregate Planning
PushSystems
PullSystems
Focusing onBottlenecks
Long-Range Capacity PlanningLong-Range
(years)
Medium-Range(6-18 months)
Short-Range(weeks)
Very-Short-Range(hours - days)
Production Planning: Units of Measure
Master Production Scheduling
Production Planning and Control Systems
Pond DrainingSystems
Aggregate Planning
PushSystems
PullSystems
Focusing onBottlenecks
Long-Range Capacity PlanningEntire
Product Line
ProductFamily
SpecificProduct Model
Labor, Materials,Machines
Aggregate Planning
Why Aggregate Planning Is Necessary
• Fully load facilities and minimize overloading and underloading
• Make sure enough capacity available to satisfy expected demand
• Plan for the orderly and systematic change of production capacity to meet the peaks and valleys of expected customer demand
• Get the most output for the amount of resources available
Inputs
• A forecast of aggregate demand covering the selected planning horizon (6-18 months)
• The alternative means available to adjust short- to medium-term capacity, to what extent each alternative could impact capacity and the related costs
• The current status of the system in terms of workforce level, inventory level and production rate
Outputs
• A production plan: aggregate decisions for each period in the planning horizon about– workforce level– inventory level– production rate
• Projected costs if the production plan was implemented
Medium-Term Capacity Adjustments
• Workforce level– Hire or layoff full-time workers– Hire or layoff part-time workers– Hire or layoff contract workers
• Utilization of the work force– Overtime– Idle time (undertime) – Reduce hours worked
• . . . more
Medium-Term Capacity Adjustments
• Inventory level– Finished goods inventory– Backorders/lost sales
• Subcontract
Approaches
• Informal or Trial-and-Error Approach• Mathematically Optimal Approaches
– Linear Programming– Linear Decision Rules
• Computer Search• Heuristics
Pure Strategies for the Informal Approach
• Matching Demand• Level Capacity
– Buffering with inventory– Buffering with backlog– Buffering with overtime or subcontracting
Matching Demand Strategy
• Capacity (Production) in each time period is varied to exactly match the forecasted aggregate demand in that time period
• Capacity is varied by changing the workforce level• Finished-goods inventories are minimal• Labor and materials costs tend to be high due to the
frequent changes
Developing and Evaluating the Matching Production Plan
• Production rate is dictated by the forecasted aggregate demand
• Convert the forecasted aggregate demand into the required workforce level using production time information
• The primary costs of this strategy are the costs of changing workforce levels from period to period, i.e., hirings and layoffs
Level Capacity Strategy
• Capacity (production rate) is held level (constant) over the planning horizon
• The difference between the constant production rate and the demand rate is made up (buffered) by inventory, backlog, overtime, part-time labor and/or subcontracting
Developing and Evaluating the Level Production Plan
• Assume that the amount produced each period is constant, no hirings or layoffs
• The gap between the amount planned to be produced and the forecasted demand is filled with either inventory or backorders, i.e., no overtime, no idle time, no subcontracting
• . . . more
Developing and Evaluating the Level Production Plan
• The primary costs of this strategy are inventory carrying and backlogging costs
• Period-ending inventories or backlogs are determined using the inventory balance equation:
EIt = EIt-1 + (Pt - Dt )
Aggregate Plans for Services
• For standardized services, aggregate planning may be simpler than in systems that produce products
• For customized services,– there may be difficulty in specifying the nature and
extent of services to be performed for each customer
– customer may be an integral part of the production system
• Absence of finished-goods inventories as a buffer between system capacity and customer demand
Preemptive Tactics
• There may be ways to manage the extremes of demand:– Discount prices during the valleys.... have a sale– Peak-load pricing during the highs .... electric
utilities, Nucor
Time Horizon in Production PlanningStatic Vs. Dynamic Environments
• Models used for production planning are either static or dynamic• Static
– Constant through time– Assume same plan acceptable in each period for the
foreseeable future• Dynamic
– Explicitly consider changes in demand and resource availability to determine what should be done through time over a planning horizon
– Require stochastic data – Require great effort to build and solve
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The Role of Inventory
• Inventory consists of physical items moving through the production system
• Originates with shipment of raw material and parts from the supplier
• Ends with delivery of the finished products to the customer• Costs of storing inventory accounts for a substantial
proportion of manufacturing cost– Often 20% or more
• Optimal level of inventory– Allows production operations to continue smoothly
• A common control measure is Inventory Turnover62
Inventory Turnover
• The ratio of annual cost of goods sold to average inventory investment.
• It indicates how many times a year the inventory is sold.
• Higher the ratio, the better, because it implies more efficient use of resources.
• Higher the profit margin and longer the manufacturing lead time, the lower the inventory turns.
• Example: Supermarkets (low profit margins) have a fairly high turnover rate
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Inventory Definitions and Decisions
• Batch or order size, Q– Batch size is the number of units released to the shop floor
to be produced• Reorder point, r
– Specifies the timing for placing a new order• Inventory Position
Inventory Position = Inventory On Hand + On Order – Backorders
• Units on order – Have been ordered but not yet arrived
• Backorders – Items promised to customers but not yet shipped – New units are shipped out to cancel backorders64
Types of Inventory
• Raw Materials– Essential to the production process– Often kept in large quantities on site
• Finished Goods– Completed products awaiting shipment to customers
• Work-in-Process (WIP)– Batches of semi finished products currently in production– Batches of parts from time of release until finished goods
status• Pipeline
– Goods in transit between facilities– Raw materials being delivered to the plant– Finished goods being shipped to warehouse or customer65
Types of Inventory
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Justification of Inventory
67
Inventory will always exist Competitive pressure to supply common products
quicker than they can be produced imply finished goods inventory must be kept near the customer
Price breaks are common when large quantities of material and parts are purchased
We may store inventory in periods of low demand and consume them in periods of large demand to smooth production rate (seasonal demand)
Speculation
Inventory Costs and Tradeoffs
• Holding inventory is costly• In constructing economic models for choosing the
optimal levels of inventory, trade of the costs caused by:
1. Ordering or set up of machines
2. Investing and storing the goods
3. Shortages (not having inventory available when needed)
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Ordering Costs
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A fixed ordering cost can be associated with each replenishment when parts are ordered from suppliers• Identifying the need to order• Execute the order• Prepare the paperwork• Place the order• Delivery cost fixed component• Receiving inspection• Transportation to place of use• Storage
Setup Costs
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For parts produced in-house, we must:• Check status of raw material• Possibly place an order• Create route sheets with instructions for each stage of
the production process• Store routing data in a database• Check routing data for compatibility with shop status
and engineering changes• Make routing instructions with raw material• Deliver to production workers• Machine set up
Inventory Carrying Costs
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Carrying inventory incurs a variety of costs• Space heated and cooled• Move inventory occasionally because it blocks access
to other goods• Construct and maintain information system to track
location• Pay taxes based on value• Insurance costs• Some will be lost, damaged, or perished• Cost of capital invested in inventory
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Shortage Costs
When customer demands an out of stock item• May decide to wait for delivery - backorders• May cancel the order – lost sales• May look elsewhere next time – lost customer• May pay expedite charges
Within the plant, if material is unavailable to start production• Work center may lack work• Schedule may have to be modified• Completion of products may be delayed• Result in late deliveries or lost sales
Information Flow for Various Production Systems
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I I
Order Entry
RawMaterial
I
a. Materials Requirements Planning (MRP)
RawMaterial
b. Just-In-Time (KANBAN)
IProcessorInformation Flow
Material FlowFinite Capacity Inventory Buffer
Infinite Capacity Inventory Buffer
KANBAN control
• Kanban control uses the levels of buffer inventories in the system to regulate production. When a buffer reaches its preset maximum level, the upstream machine is told to stop producing that part type. This is often implemented by circulating cards, the kanbans, between a machine and the downstream buffer.
• The machine must have a card before it can start an operation. It can then pick raw materials out of its upstream (or input) buffer, perform the operation, attach the card to the finished part, and put it in the downstream (or output) buffer.
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KANBAN control
• Kanban control ensures that parts are not made except in response to a demand.
• The analogy is to a supermarket: Only the goods that have been sold are restocked on the shelves.
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Information Flow for Various Production Systems
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I
Limit onTotal
Inventory
RawMaterial
I
c. Constant Work-In-Process (CONWIP)
RawMaterial
d. Hybrid CONWIP-KANBAN
IProcessorInformation Flow
Material FlowFinite Capacity Inventory Buffer
Infinite Capacity Inventory Buffer
CONWIP Control
• CONWIP stands for Constant Work-In-Process.• a control strategy that limits the total number of
parts allowed into the system at the same time. • Once the parts are released, they are processed as
quickly as possible until they fill up the last buffer as finished goods.
• Once the consumer removes a part from the finished goods inventory, the first machine in the chain is authorized to load another part.
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CONWIP Control
• Like KANBAN, the CONWIP system only responds to actual demands, so it is still a ``pull'' type system.
• But unlike kanban, the buffers for all downstream machines are empty, except finished goods, which is full.
• This occurs because any part released to the system will move to finished goods. New parts will not be released if the finished goods buffer is full.
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Inventory is Needed to Support Production
• Recent years claim a goal of zero inventory– But some is necessary to meet needs – Economically practical to maintain some WIP to facilitate
production scheduling– Variability in processing time and job arrival rates
• Inventory should not be used to cover problems– Wasteful practice all too common– Prevents the system from improving– Defects not detected until later
• Lean companies– Operate with reliable processes, quick changeovers, low
inventories, small space, low scrap and rework, closer communication
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Large Inventories Imply Long Throughput Times
• Throughout time (manufacturing Lead Time)– The span of time from when the part enters a system
until it leaves• Little’s Law I = X · T
– Relates average throughput time (T) to the level of average inventory (I) and the production rate (X) for any stationary process
• Stationary process– Probability of being in a particular state is
independent of time
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To reduce throughput time
Eliminate unnecessary, non-value added operations:– Reduce waiting time– Reduce transfer time– Reduce quality inspection time– Increase process rates– Reduce batch size
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Capacity Balancing
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1 2 3 4 5Flow In Flow Out
Desire to have same number of units produced in each work center
Capacity is measured by number of units that can be made per time period
Total production is limited by the workstation with the smallest capacity (bottleneck station)
Excess capacity reduces cycle time
Theory of Constraints (TOC)
A management philosophy developed by Dr. Eliyahu Goldratt.
The goal of a firm is to make money.
End of Lecture 7