Ordering Cost
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Transcript Ordering Cost
BUAD306
Chapter 13 - Inventory Management
Everyday Inventory
Food
Gasoline
Clean clothes…
What else?
Inventory
Stock or quantity of items kept to meet
demand
Takes on different forms
Final goods
Raw materials
Purchased/component parts
Labor
In-process materials
Working capital
Inventory
Static – only one opportunity to buy
and sell units
Dynamic – ongoing need for units;
reordering must take place
Demand
Dependent Demand
Items are used internally to produce a
final product
Independent Demand
Items are final products demanded by
external customers
Reasons To Hold Inventory
To meet anticipated demand
To smooth production requirements
To decouple components of the productiondistribution system
To protect against stock-outs
To take advantage of order cycles
To hedge against price increases or to take
advantage of quantity discounts
To permit operations
Inventory Costs
Carrying Costs
Ordering Costs
Costs of holding an item in inventory
Costs of replenishing inventory
Shortage (stockout) Costs
Temporary or permanent loss of sales
when demand cannot be met
Inventory Management
How much and when to order inventory?
Objective: To keep enough inventory
to meet customer demand and also
be cost-effective
Purpose: To determine the amount of
inventory to keep in stock - how much
to order and when to order
Inventory Management
Requirements
A system to keep track of the inventory
on hand and on order
A reliable forecast of demand
Knowledge of lead times
Reasonable estimates of inventory
costs
A classification system for inventory
items (ABC)
Inventory Control Systems
Control the level of inventory by
determining how much to order and
when
Continuous (Perpetual) Inventory
System - a continual record of the
inventory level for every item is
maintained
Periodic Inventory System - inventory
on hand is counted at specific time
intervals
Other Control Systems/Tools
Two-Bin System - two containers of
inventory; reorder when the first is
empty
Universal Product Code (UPC) - Bar
code printed on a label that has
information about the item to which it
is attached
0
RFID Tags
214800
232087768
Considerations
Lead Time
Cycle Counting
Time interval between ordering and
receiving the order
Physical count of items in inventory
Usage Rate
Rate at which amount of inventory is
depleted
Inventory Cycle
Profile of Inventory Level Over Time
Q
Usage
rate
Quantity
on hand
Reorder
point
Receive
order
Place Receive
order order
Lead time
Place
order
Receive
order
Time
Economic Order Quantity
The EOQ Model determines the
optimal order size that minimizes total
inventory costs
Inventory Costs
Carrying Costs – cost associated with
keeping an item in stock
Includes: storage, warehousing,
insurance, security, taxes, opportunity
cost, depreciation, etc.
Ordering Costs – cost associated with
ordering and receiving inventory
Determining quantities needed,
preparing documentation, shipping,
inspection of goods, etc.
Optimal Order Quantity
Q
o
=
2DS = 2 (Annual Demand) (Order Cost)
H
Annual Holding Cost per unit
Length of order cycle =
Qo
D
# Orders / Year =
D
Qo
Basic EOQ Model
Annual
Annual
Total cost = carrying + ordering
cost
cost
TC =
Where:
Qo
H
2
+
DS
Qo
Qo = Economic order quantity in units
H = Holding (carrying) cost per unit
D = Demand, usually in units per year
S = Ordering cost
Cost Minimization Goal
Annual Cost
The Total-Cost Curve is U-Shaped
TC
Qo
D
H
S
2
Qo
Carrying Costs
Ordering Costs
QO (optimal order quantity)
Order Quantity
(Q)
EOQ Example 1
A local office supply store expects to sell
2400 printers next year. Annual carrying
cost is $50 per printer, and ordering cost is
$30. The company operates 300 days a
year.
A) What is the EOQ?
B) How many times per year does the store reorder?
C) What is the length of an order cycle?
D) What is the total annual cost if the EOQ quantity is
ordered?
EOQ Example 2
A local electronics store expects to sell 500
flat-screen TVs each month during next
year. Annual carrying cost is $60 per TV,
and ordering cost is $50. The company
operates 364 days a year.
A) What is the EOQ?
B) How many times per year does the store reorder?
C) What is the length of an order cycle?
D) What is the total annual cost if the EOQ quantity is
ordered?
Quantity Discounts
A
price discount on an item if
predetermined numbers of units
are ordered
TC =
Carrying cost + Ordering cost + Purchasing cost =
(Q / 2) H + (D / Q) S + PD
where P = Unit Price
Quantity Discount Example
Campus Computers 2Go Inc. wants to reduce a large
stock of laptops it is discontinuing. It has offered the
University Bookstore a quantity discount pricing
schedule as shown below. Given the discount
schedule and its known costs, the bookstore wants to
determine if it should take advantage of this discount
or order the basic EOQ order size.
Quantity
Price
Carrying Cost:
$200
1 – 49
$1,500
Ordering Cost
$1,000
50 – 89
$1,000
Annual Demand
400 units
90 +
$800
HW #13
A mail-order house
uses 18,000 boxes
a year. Carrying
costs are $.60 per
box per year and
ordering costs are
$96. The following
price schedule is
offered. Determine
the EOQ and the #
of orders per year.
# Boxes
Unit Price
1000-1999
$1.25
2000-4999
$1.20
5000-9999
$1.15
10000+
$1.10
EOQ with Incremental
Replenishment (EPQ)
Used when company makes its own
product
Considers a variety of costs/terms:
Carrying Cost
Setup Cost (analogous to ordering costs)
Maximum and Average Inventory Levels
Economic Run Quantity
Cycle Time
Run Time
EOQ with Incremental
Replenishment (EPQ)
Definitions
S = Setup Cost
H = Holding Cost
Imax = Maximum Inventory
Iavg = Average Inventory
D = Demand/Year
p = Production or Delivery Rate
u = Usage Rate
EOQ with Incremental
Replenishment
Total Cost = Carrying
Cost + Setup Cost
Economic run quantity
(Imax/2) H + (D/Qo) S
Qo = 2DS/H * p/(p-u)
Cycle time (time between Qo /u
runs)
Run time (production
Qo /p
phase)
Maximum Inventory Level Imax = (Qo /p)(p-u)
Average Inventory Level
Iaverage = Imax /2
Assumptions
Only one item is involved
Annual demand is known
Usage rate is constant
Usage occurs continually, production
periodically
Production rate is constant
Lead time doesn’t vary
No quantity discounts
EOQ Replenishment Example
A toy manufacturer uses 48,000 rubber wheels per
year for its product. The firm makes its own
wheels, which it can produce at a rate of 800 per
day. The toy trucks are assembled uniformly over
the entire year. Carrying cost is $1 per wheel a
year. Setup cost for a production run of wheels is
$45. The firm operates 240 days per year.
Determine the:
Optimal
run size
Minimum total annual cost for carrying and setup
Cycle time for the optimal run size
Run time
1
2
3
4
5
6
7
600
1200
1800
1600
1400
1200
1000
8
800
9
600
10
400
11
200
12
0
13
14
START ALL OVER
15
Other Considerations
Safety Stock
Reorder Point
Seasonality