Home Project-material CRITICALITY MULTI-MODELLING AND SIMULATION OF SPARE PARTS INVENTORY CONTROL

CRITICALITY MULTI-MODELLING AND SIMULATION OF SPARE PARTS INVENTORY CONTROL

Dept: MECHANICAL ENGINEERING File: Word(doc) Chapters: 1-5 Views: 3

Abstract

As the bar for service excellence keeps rising, especially in the request of shorter lead times, higher service levels, lower costs and better customer service support, the conventional models of spare parts inventory control are increasingly becoming inadequate. Therefore, to tackle this challenge, in this study, three novel models of spare parts inventory control have been formulated, developed and packaged into a multi-model and multi-purpose engineering computer software, called U-SPIC. Model 1 used mathematical analysis to integrate 7 spare parts inventory policies together. Model 2 integrated the same inventory policies of Model 1, using stochastic simulation while Model 3 expanded Model 2 by considering bulk demand and supply using stochastic simulation. Chi-square goodness of fit inference statistical technique was employed in the preliminary design to check the reasonableness of using Poisson distribution for the demands and it gave 86% success. Composite ste
INTRODUCTION

1.1 Spare Parts Inventory Control – Meaning

To establish a common understanding, ‘Spare parts’ refers to the

parts requirement for keeping both owned equipment/machine or

service needs of customers in healthy operating condition by

meeting repair and replacement needs imposed by breakdown and

preventive maintenance. The term spare parts in this study

therefore, is used to connote both spare parts and service parts

as applied to a firm handling both internal and

external spare and service needs. On the other hand, ‘Inventory

Control’ refers to the management of the supply, storage and

accessibility of items, in this case spare parts, in order to

ensure an adequate supply without excessive supply.

Spare parts inventory models differ substantially from regular

inventory models. The key reason for this difference is that

spare parts provisioning is not an end in itself, but a means to

guarantee up-time of equipment. With respect to spare parts

inventory, the customer’s sole interest is that his systems are

not down due to lack of spare parts because equipment downtime is

lost production capacity.

1.1.1 Large Revenue and Investment on Spare Parts Inventory

1

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In today’s technological environment, the importance of aftersales service which basically concerns the use of spare parts for

maintenance purposes, is high. Lost revenues due to disservice

are enormous. Not only is after-sales service valuable as a

competitive advantage for manufacturers and service providers,

direct revenues in this service are also remarkably high.

Companies that provide the after-sales service have to invest a

lot on spare parts inventory. In 2006, Koudalo1

investigated

revenues of spare parts in the service business over a period of

one year, and he reports combined revenues of more than $1.5

trillion. Flint2

stated that the world’s spare parts inventory in

the aviation industry in 1995 amounted to $45 billion at that

time. Any means to downsize this stock, without decreasing

customer service, would be more than welcomed by the aviation

industry. Also in other industries, large amounts of money are

invested in spare parts inventory and this has increased over the

years. Heather3

reported that the spare parts market of U.S.

represents $700 billion and 8 percent of the U.S. gross domestic

product. Many manufacturers find that profit margins for services

can top 40 percent, whereas margins for finished goods top out at

around 13 percent. Cohen et al4

and AberdeenGroup5

also report

that profitability in service is much higher than profitability

for initial products. Because of these large amounts of money

involved, savings of a few percent only constitute large cost

savings in absolute terms.

The above indicates that the control of spare parts for aftersales service deserves substantial corporate attention, which is

even more true, since customer requirements have tightened.

AberdeenGroup5

indicates that 70% of the respondents in its study

have seen service response times as required in service level

3

agreements shrinking to 48 hours or less, and Koudalo1

states

that customers keep raising the bar for service excellence by

requesting shorter lead times, higher service levels, lower

costs, and better customer service support.

1.1.2 Overview of the Case Study

The first insight on the importance of spare parts inventory

control by the researcher was made while carrying out another

study, Okonkwo6

, on stochastic queueing behaviour of vehicles in

a maintenance workshop which eventually resulted in the

development of a computer software: Ugoo Multi-Purpose Computer

Qeueuing Model Simulator (Ugoo MC-QMS).

However, the primary motivation that finally triggered off this

research is an experience with the spare parts complex of a

leading motor assembling/manufacturing company in Nigeria. The

Anambra Motor Manufacturing Company (ANAMMCO) Enugu, Nigeria –

This company is a product of a joint venture of the Federal

Government of Nigeria and Daimler-Chrysler of Germany, and was

commissioned in 1980. The spare parts complex of ANAMMCO provides

considerable after-sales service which is impacted significantly

by the spare parts control. The company has a very large spare

parts complex that stores and manages spares various models of

Mercedes Benz heavy duty vehicles. Specifically, besides the

selling of vehicles, the spare parts of various models of heavy

duty vehicles listed below are stored and managed by the company.

Trucks: MB-711, MB-1418, MB-1520, MB-1518, MB-1720, MB-1620,

MB-1718, MB-1634, MB-2423

Actros: MB-2031, MB-2035, MB-3340, MB-4031

4

Freightliner: MB-M21126X4, MB-M21124X2

Axor: MB-1823

Buses: MB-712, MB-812, MB-1721, MB-O400, MB-O500

The management of these models which is complex was further

complicated by the vast number of parts required in each model.

In fact, more than 30,000 active parts needed to be controlled.

The management of these parts can only be done with the aid of a

computer, hence the spare parts complex has a computerized spare

parts inventory database. Each of the parts that is supplied or

replenished is continuously keyed into the computer and the

inventory stock parameters are updated automatically.

The company uses two software for its inventory control. The

first is the Electronic Parts Catalogue (EPC) which is used to

identify the part number of the spare parts. Once the engine and

chassis number is inputted, it invokes a dialogue box from where

spare parts section is selected and from the pull down menu, the

particular spare part is chosen. The software will search and pop

up the part number of the spare part, a 3-D AutoCAD drawing of

the required part, a CAD drawing guide on how it can be fixed

into the vehicle and in some cases an alternative part to be used

in case the said part is out of stock. From the part number, the

location of the spare parts in the stock room is identified. The

second software is Integrated Dealer Importer System (IDIS). It

is a software that determines the stock level for each part in

the stock complex. It has a database showing the orders and

replenishments that have been made. It also indicates when to

replenish and the quantity. It uses continuous review (r,Q)

inventory policy. It should also be noted that the complex

5

observes the well known A-B-C classification in its spare parts

inventory.

The company faces two major demands of spare parts from the

complex, the first is demand from the maintenance section of the

company. The second is from the external customers that directly

buy spare parts from the complex for their personal use. Demand

from the maintenance section is as a result of spare parts

demands for maintaining their vehicles, for maintaining aftersales service of vehicles whose owners had service level

agreement with the company as well as those that just take their

vehicles to their maintenance workshop for either regular

servicing or for repairs when they have broken down completely.

Notwithstanding the fact that the company’s inventory system is

computerized, yet the computerized system does not observe

service differentiation through rationing and demand lead time.

However, in some exceptional cases, the company observes demand

lead time manually though, But, more than ever before, this

method can no longer withstand the challenges of modern standards

of spare parts inventory control. These standards have risen to

such levels that it is difficult, if not impossible to attain it

by manual form of optimization.

Therefore, this study provides improved models which when

implemented, find solution to the company’s spare parts network

challenge. These models will not only provide immediate and

significant benefit to the company under study, but can be

adapted to very many other systems.

1.1.3 Introduction to Service Differentiation

6

In spare parts inventory, just as different customers may require

different product specifications, they may also require different

service levels. For instance, for a single product, different

customers may have different stockout costs and/or different

minimum service level requirements or different customers may

simply be of different importance to the supplier by similar

measures. Therefore, it can be imperative to distinguish between

classes of customers thereby offering them different services. In

this setting, different product demands from different customers

can no longer be handled in a uniform way. This, in turn, gives

rise to multiple demand classes and customer differentiation.

In this system of multiple demand classes the easiest policy

would be to use different stockpiles for each demand class. This

way, it would be very easy to assign a different service level to

each class. Also the practical implementation of this policy

would be relatively easy and will require less mathematical

analysis. But the drawback of this policy is that there is no

advantage from the so-called portfolio effect. In other words,

the advantage of pooling demand from different demand sources

together would no longer be utilized. Therefore, as a result of

the increasing variability of demand, more safety stock would be

needed to ensure a minimum required service level which in turn

means more inventory.

On the other side, one could simply use the same pool of

inventory to satisfy demand from various customer classes without

differentiating them. In this case, the highest required service

level would determine the total inventory needed and thus the

inventory cost. The drawback of this policy is that higher

service level will be offered to the rest of the demand classes,

7

a deficiency that would lead to increased inventory costs.

Critical level policy essentially lies between these two

extremes. It requires complex mathematical analysis, but the

gains outweigh the task involved.

In the existing practice, the company studied failed to exploit

service differentiation (demand classes) of the various

customers. The company targets to achieve the maximum of the

service level requirements while considering the aggregated

demand. Moreover, the company does not recognize the possible

demand lead times (the difference between requested date and

shipment date of the request) for lead time orders. This study

develops spare parts inventory models that recognize the demand

lead times, multiple demand classes, allow for providing

differentiated service levels through rationing, as well as

optimizes the generated policy parameters, notwithstanding the

complex analysis that it entails.

1.2 Statement of the Problem

The complexities and the growing criticality of spare parts

inventory control in manufacturing and service operations are on

the increase. Factors like demand unpredictability, parts

indigenization, high service levels, large investments on and

revenues from parts, the imperative to accurately forecast spare

parts requirements and to optimize existing inventory policies

require significant decision support. This decision support can

only be achieved from the results generated from more efficient

novel decision models.

8

Unfortunately, many researchers from the third world shy away

from developing this type of models. Those who delve into it

limit themselves to the development of spare parts inventory

control database, using conventional models. These conventional

models are increasingly becoming ineffective in tackling spare

parts inventory control problems. On the other hand, the

advanced countries that have done a lot of work with regards to

developing novel spare parts inventory control models have not

been able to integrate either the 7 spare parts inventory

policies as was done in Models 1 and 2 of this study, or 9 spare

parts inventory policy as was done in Model 3 of this study, in

any of their developed models. The spare parts inventory policies

are listed in the objective of the study in section 1.3.

9

1.3 Objective of the Study

The objective of the study embraces the following:

? Development of a novel analytical model (Model 1)

This integrates 7 spare parts inventory policies together.

The policies are continuous review, one to one lot, service

differentiation and rationing, backordering, demand lead

time, priority clearing mechanism and bounded enumerative

optimization.

? Development of novel stochastic simulation models (Models 2 and 3)

Model 2 integrates the same 7 spare parts inventory policies

of model 1 using stochastic simulation while model 3 expands

model 2 by considering in addition to the to the policies of

modal 2, bulk demand and bulk replenishment of spare parts

using stochastic simulation.

? Showcasing new insight in the behaviour of backorders of spare parts

inventory This is with regards to its maximum queue length,

mean response time and average number in the system.

? Establishment of the magnitude of cost savings

This is done by the application of service differentiation

through rationing and demand lead time.

? Formulation of composite graphical representations of the models

This is for pedagogical purposes.

? Proposal of the models to the Management of ANAMMCO

This is for possible interfacing with their already existing

computer spare parts inventory model.

? Uploading the active software to the internet

This is for easy subscription, access and run, from any part

of the world.

10

1.4 Significance of the Study

The envisaged significance of this study is laid on its applied

nature mainly. That is, the output results from these models have

foreseeable potentialities for immediate practical applications

to the on-going challenge of achieving above 99% service level at

minimum stock.

Specifically, the models can easily be applied in spare parts

inventory control Industries/Companies and even Institutions, for

the following purposes:

1. The models can be applied to the management of the spare

parts inventory system, requiring both preventive and

breakdown demands of spare parts.

2. Industries that have contractual agreements for servicing

machines/vehicles/airplanes with some of its customers can

also find the models very useful for the management of its

inventory. An example is an airline industry that has

contractual agreement with its major and minor airlines of

differentiated service levels.

3. Spare parts inventory systems that do not recognize both

service differentiation and positive demand lead time can

equally make use of these models. What is required is just

to remove the service differentiation and demand lead time

by setting critical service level and demand lead time to

zero value, accomplished through pressing few clicks on the

graphical user interface of the multi-model software

package.

4. Managing inventories for spare parts of equipments of

different criticality can make use of the models. In this

11

case the equipment criticality will determine the service

level.

5. The building blocks that will be provided in this study can

be adapted to solving other real-life spare parts inventory

control problems.

6. Finally, it can be very useful as an effective and

interesting spare parts inventory pedagogical tool, both in

the academic and commercial Institutions.

1.5 Scope and Limitations

The study of the operating realities of the Spare Parts Complex

of Anambra Motor Manufacturing Company Limited (ANAMMCO) informed

this work.

The thrust was on the continuous review inventory models, which

in any case are better than periodic review for spare parts

inventory. For effective control, continuous review models

require companies whose inventory database systems are

computerized.

The study did not set out to develop database inventory models

but the decision-support models using mathematical and simulation

approaches. These models will be compatible with the case study

inventory databases and indeed should be easily interfaced with

standard databases of leading software manufacturers Like

Microsoft and Oracle Corporations


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