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12. |
Inventory Management |
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Inventory is the stock of items
kept by an organisation to meet internal or external customer demand (Russell
and Taylor, 2009). The type of inventory management system employed is
determined by the nature of the demand for the goods and services on the
organisation. Demand can be classified into two categories; dependent and
independent.
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12.1. |
Dependent
Demand |
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A dependent demand item has a
demand which is relatively predictable because it is dependent on other
factors. Thus a dependent demand item can be classified has having a demand
that can be calculated as the quantity of the item needed to produce a
scheduled quantity of an assembly that uses that item.
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12.2. |
Independent
Demand |
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Independent demand is when demand
is not directly related to the demand for any other inventory item. Usually
this demand comes from customers outside the company and so is not as
predictable as dependent demand. Because of the unknown future requirements
of customers, forecasting is used to predict the level of demand. A safety
stock if then calculated to cover expected forecast error. Independent demand
items can be finished goods or spare parts used for after sales service.
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12.3. |
Types
of Inventory Generally inventory is classified
as either raw materials, work-in-progress (WIP) or finished goods. The
proportion between these inventory types will vary but it is estimated that
generally 30% are raw materials, 40% are work in progress and 30% finished
goods. The location of inventory can be used to define the inventory type and
its characteristics. There are various definitions of inventory types
including the following :
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Buffer/Safety This is used to compensate for the
uncertainties inherent in the timing or rate of supply and demand between two
operational stages. |
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Cycle If it is required to produce
multiple products from one operation in batches, there is a need to produce enough
to keep a supply while the other batches are being produced. |
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Anticipation This includes producing to stock
to anticipate a increase in demand due to seasonal factors. Also speculative policies
such as buying in bulk to take advantage of price discounts may also increase
inventory levels. |
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Pipeline/Movement This is the inventory needed to
compensate for the lack of stock while material is being transported between stages.
e.g. the time taken in distribution from the warehouse to a retail outlet.
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12.4. |
Inventory
Decisions The main concern of inventory
management is the trade-off between the cost of not having an item in stock
against the cost of holding and ordering the inventory. A stock-out can
either be to an internal customer in which case a loss of production output
may occur, or to an external customer when a drop in customer service level
will result. In order to achieve a balance between inventory availability and
cost the following inventory management aspects must be addressed of volume -
how much to order and timing - when to order.
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12.5. |
The
Economic Order Quantity (EOQ) Model The Economic Order Quantity (EOQ)
calculates the inventory order volume which minimises the sum of the annual
costs of holding inventory and the annual costs of ordering inventory. The
model makes a number of assumptions including
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Stable or Constant Demand |
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Fixed and identifiable ordering
cost |
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The cost of holding inventory
varies in a linear fashion to the number of items held |
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The item cost does not vary with
the order size |
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Delivery lead time does not vary |
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No quantity discounts are
available |
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Annual demand exists |
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These assumptions have led to criticisms of the use of EOQ in practice. The assumption of one delivery per order, and then the use of that stock over time increases inventory levels and goes against a JIT approach. Also annual demand will not exist for products with a life-cycle of less than a year. However the EOQ approach still has a role in inventory management in the right circumstances and if its limitations are recognised Using the EOQ each order is assumed to be of Q units and is withdrawn at a constant rate over time until the quantity in stock is just sufficient to satisfy the demand during the order lead time (the time between placing an order and receiving the delivery). At this time an order for Q units is placed with the supplier. Assuming that the usage rate and lead time are constant the order will arrive when the stock level is at zero, thus eliminating excess stock or stock-outs. The order quantity must be set at a level which is not too small, leading to many orders and thus high order costs and not too large leading to high average levels of inventory and thus high holding costs. The annual holding cost is the
average number of items in stock multiplied by the cost to hold an item for a
year. If the amount in stock decreases at a constant rate from Q to 0 then
the average in stock is Q/2.
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12.6. |
The
Re-Order Point (ROP) Model The EOQ model tells us how much to order, but not when to order. The Reorder point model identifies the time to order when the stock level drops to a predetermined amount. This amount will usually include a quantity of stock to cover for the delay between order and delivery (the delivery lead time) and an element of stock to reduce the risk of running out of stock when levels are low (the safety stock). The previous economic order
quantity model provides a batch size that is then depleted and replenished in
a continuous cycle within the organisation. Thus the EOQ in effect provides a
batch size which the organisation can work to. However this assumes that demand rates and
delivery times are fixed so that the stock can be replenished at the exact
time stocks are exhausted. Realistically though both the demand rate for the
product and the delivery lead-time will vary and thus the risk of a stock-out
is high. The cost of not having a item in stock when the customer requests it
can obviously be costly both in terms of the potential loss of sales and the
loss of customer goodwill leading to further loss of business.
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12.6.1. |
Safety Stock and Service Level Safety stock is used in order to prevent a stock-out occurring. It provides an extra level of inventory above that needed to meet predicted demand, to cope with variations in demand over a time period. The level of safety stock used, if any, will vary for each inventory cycle, but an average stock level above that needed to meet demand will be calculated. To calculate the safety stock
level a number of factors should be taken into account including : -
cost due to stock-out -
cost of holding safety stock -
variability in rate of demand - variability in delivery lead time It is important to note that there is no stock-out risk between the maximum inventory level and the reorder level. The risk occurs due to variability in the rate of demand and due to variability in the delivery lead time between the reorder point and zero stock level. The reorder level can of course be estimated by a rule of thumb, such as when stocks are at twice the expected level of demand during the delivery lead time. However to consider the probability of stock-out, cost of inventory and cost of stock-out the idea of a service level is used. The service level is a measure of
the level of service, or how sure, the organisation is that it can supply
inventory from stock. This can be expressed as the probability that the
inventory on hand during the lead time is sufficient to meet expected demand
(e.g. a service level of 90% means that there is a 0.90 probability that
demand will be met during the lead time period, and the probability that a
stock-out will occur is 10%. The service level set is dependent on a number
of factors such as stockholding costs for the extra safety stock and the loss
of sales if demand cannot be met.
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12.7. |
The ABC Inventory Classification System Normally a mix of fixed-order-interval and fixed order quantity inventory systems are used within an organisation. When there are many inventory items involved this raises the issue of deciding which particular inventory system should be used for a particular item. The ABC classification system sorts inventory items into groups depending on the amount of annual expenditure they incur. This will depend on both the estimated number of items used annually multiplied by the unit cost. To instigate a ABC system a table is produced listing the items in expenditure order (with largest expenditure at the top), and showing the percentage of total expenditure and cumulative percentage of the total expenditure for each item. By reading the cumulative percentage figure it is usually found, following Pareto’s Law, that 10-20% of the items account for 60-80% of annual expenditure. These items are called A items and need to be controlled closely to reduce overall expenditure. This often implies a fixed quantity system with perpetual inventory checks or a fixed-interval system employing a small time interval between review periods. It may also require a more strategic approach to management of these items which may translate into closer buyer-supplier relationships. The B items account for the next 20-30% of items and usually account for a similar percentage of total expenditure. These items require fewer inventory level reviews than A items. A fixed order interval system with a minimum order level may be appropriate here. Finally C items represent the remaining 50-70% of items but only account for less than 25% of total expenditure. Here much less rigorous inventory control methods can be used, as the cost of inventory tracking will outweigh the cost of holding additional stock. It is important to recognise that
overall expenditure may not be the only appropriate basis on which to
classify items. Other factors include the importance of a component part on
the overall product, the variability in delivery time, the loss of value
through deterioration and the disruption caused to the production process if
a stock-out occurs. |
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