InventoryManagement.pptx

OPERATIONS

MANAGEMENT

PUAF U6217

Inventory Management

Importance of Inventory

Average Firm Carries 10,000 – 50,000 Items of inventory

Typical Value of Inventory: 10% – 60% of Production Cost

National Inventory Value: 20% – 30% of US GNP

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Inventory Examples

Boeing Aircraft – $10.5 billion Inventory with $25.5 billions in Sales

Saks Fifth Avenue – $543.1 millions Inventory with $2.2 billions in Sales

Barnes & Noble – $852 millions Inventory with $2.8 billions in Sales

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Definition

Stock, Materials, Paperwork or Other Resources Used in an Organization to Produce a Final, Useable Product

The Final Product Before Use or Sale

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Types of inventory

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Types of Inventory

Raw Materials

Finished Products

Component Parts

Supplies

Work In Progress

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Why Would We Want Inventory?

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Why Would We WantInventory?

To Maintain Independence of Operations

To Meet Variation In Product Demand

To Allow Flexibility in Production Scheduling

To Provide a Safeguard for Variation in Raw Material Delivery Time

To Take Advantage of Economic Purchase Order Size

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Inventory Measures

Number of Units

Dollar Value

Weeks of Supply

Inventory Turnover

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Inventory Systems

2 BIN

ABC

EOQ

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Costs of InventoryBroad Categories

Holding or Carrying Costs

Acquisition Costs

Ordering Costs

Shortage Costs

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Holding Costs

Storage (Rent & Maintenance), Energy (Heat, Light, Refrigeration), and Handling

Cost of Capital

Insurance

Spoilage, Pilferage & Damage

Obsolescence

Property Taxes

Information processing

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Set Up Costs

Machine & Tool Adjustment

Cleaning

Material Handling

Scrap

Start Up

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Ordering Costs

Administrative and Clerical

Transportation

Insurance

Handling and Inspection

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Shortage Costs

Lost Sales (Present)

Lost Sales (Future)

Backordering

Extra Shipping

Loss of Goodwill

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Types of Inventory Systems

Designed to Account for Variable, Independent Demand

Designed to Recognize Planned, Dependent Demand

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Dependent Demand

Material Requirement Planning (MRP)

Demand is Known or Predicted

Aggregate Plan/Customer Orders/Forecasts

Master Schedule

Eliminate Variability/ Establish Priorities

Getting the Right Materials to the Right Place at the Right Time

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MRP

How Many Items Do We Want to Make and When? – Master Schedule

Final Demand “Exploded” Into Parts Needed – Bill of Materials

Plan Backwards From When You Need Final Parts Given the Assembly Procedure

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Independent Demand

Fixed Order Quantity- Order Same Amount Each Time, Order When Inventory Position Drops Below the Reorder Point (Inventory Position Equals Inventory On Hand Plus On Order Minus Backorders or Shortages)

Fixed Order Period -Review Inventory Position At Same Intervals and Order Amount To Return Your Position To The Calculated Base Stock Level

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Continuous review Models

Inventory is continuously monitored.

Order placed whenever inventory goes below a re-stocking level.

The amount ordered is a constant

Useful when a computerized system is used to manage inventory.

Examples: ordering stationary in an office; Just-In-Time production system in automobile manufacturing.

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EOQ Model Assumptions

Single product or item

Demand rate known and constant

Item produced in lots, or purchased in orders

Each lot or order received in single delivery

Lead time known and constant

Ordering, or setup costs are constant

No backorders are allowed

No quantity discounts are allowed

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General Inventory Representation

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Reorder Point (ROP)

Time

Inventory Level

AverageInventory (Q*/2)

Lead Time

Optimal Order Quantity(Q*)

Economic Order Quantity (EOQ)

Find Optimal Order Size to Minimize Holding Costs Plus Ordering Costs

Larger Order Size Higher Holding Costs Lower Ordering Costs (Fewer Orders)

Smaller Order Less Holding Cost Higher Ordering Costs (More Frequent Orders)

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Definitions

D = Average Annual Demand

S = Ordering Cost ($ per Order)

H = Unit Holding Cost Per Year ($/Unit/Yr)

Alternate: H = I x C, where

I = Inventory Carrying Charge per $ Value of Inventory Per Year

C = $ Value Per Unit

Q = Order Quantity

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Annual Inventory Cost

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Total Cost:

Total Annual = Cost

Annual Ordering + Cost

Annual Cost Of Items +

Ordered

Annual Holding Cost

EOQ Model Equations

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Re-ordering point:

Optimal Order Quantity:

Expected Number of Orders:

Expected Time Between Orders:

Days:

Total Cost:

EOQ Model Application

An EOQ model is applicable when

Demand does not change significantly from one ordering period to another

Example: long lifecycle stable products such as groceries, automobile components, chemicals, heavy industrial equipment, etc.

Demand can be forecasted accurately. In other words, it has less randomness

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Practice Problem

For the following set of numbers, calculate and plot on one graph the ordering cost, the holding cost, and the total cost. Also calculate the reorder point. Calculate EOQ.

Annual Demand = 1,000 units (365 days)

Cost to Place an Order = $10, Holding Cost per unit per year = $2.50, Unit Cost = $15

Lead Time = 7 days

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EOQ With Variablity

Probabilistic Model

Variability in Demand and Supply Lead Times

Lead Time Demand: Demand during leadtime

Leadtime demand follows normal distribution (forecasting)

Other EOQ assumptions apply

Result: You Need Safety Stock

Trade Off of Lost Use or Sales vs. Overstocking

How much & when to order

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Safety Stock Computation

Leadtime demand is a normal distribution

Decide on the target performance (service level) α (i.e 99%)

Find the corresponding level of inventory ROP

Likelihood that leadtime demand is smaller than ROP is α

ROP = μld + Safety Stock = μld + sld * z*

z* is such that F(z) = α

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red area = a

zs

m

ld = N(m,s)

F(z) = area = a

z

0

N(0,1)

Safety Stock

Consider service level & safety stock

Service level = 1 – Probability of stockout

Higher service level means more safety stock

More safety stock means higher ROP

ROP = mean of leadtime demand + safety stock

Safety stock = standard deviation of leadtime demand × z,*

z* is determined by the desired service level

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Probabilistic Models: When to Order?

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Safety Stock (SS)

Time

Inventory Level

X

SS

ROP

Service Level

P(Stockout)

Frequency

ROP

Lead Time

Place order

Receive order

Mean demand during leadtime

ROP = re-order point

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Standard Normal Distribution

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F(z)

z

0

F(z) = Prob( N(0,1) < z)

 = 98.7% implies z* = 2.23

Transform back, knowing z*

ROP = m + z*s

Probabilistic Models Examples

1. Demand during leadtime for one brand of TV is normally distributed with a mean of 36 TVs and a standard deviation of 15 TVs. What safety stock should be carried for a 90% service level? What is the appropriate reorder point?

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Probabilistic Models Examples

2. Based on available information, the daily demand for iPhones averages 10 units (normally distributed), with a standard deviation of 1 drive. The leadtime is exactly 5 days. Management wants a 97% service level. What safety stock should be carried? What is the appropriate reorder point?

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Other Inventory Control Systems

Continuous review systems: each time a withdrawal is made from inventory, the remaining quantity is reviewed to determine whether an order should be placed.

Periodic review systems: the inventory of an item is reviewed at fixed time intervals, and an order is placed for the appropriate amount.

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Fixed Period Models (fixed review)

Orders placed at fixed intervals, e.g., once a week or once a month

Inventory is brought up to target amount

The amount ordered is not constant but varies because of randomness of demand

No continuous inventory count

Since inventory is counted once a period, there is a possibility of stockout between intervals

Useful when vendors visit routinely

Example: P&G representative calls every 2 weeks

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Fixed Period Models (fixed review)

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Time

Inventory Level

Target maximum

1 Period

1 Period

1 Period

Demand

How much to Order ?

Continuous review Models

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Time

Inventory Level

Reorder point

Demand

Order quantity

Time between orders is not fixed

When to Order?

Continuous vs. periodic review

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Continuous Review

System Advantages

Lower Safety Stock

Fixed lot size may make it easier to obtain quantity discounts

Individual review of items is used and this may be very desirable for expensive items

Periodic Review

System Advantages

Less time consuming and expensive to maintain

Allows combining orders to the same supplier

Inventory record keeping costs can be reduced