Filetype PDF | Posted on 06 Feb 2023 | 2 years ago
Authentication
digital resources
142x Filetype PDF File size 0.77 MB Source: home.iitk.ac.in
PRODUCTION PLANNING AND SCHEDULING IN
MULTI-STAGE BATCH PRODUCTION ENVIRONMENT
A THESIS
SUBMITTED IN PARTIAL FULFILLMENT OF THE REQUIREMENTS
FOR THE FELLOW PROGRAMME IN MANAGEMENT
INDIAN INSTITUTE OF MANAGEMENT
AHMEDABAD
By
PEEYUSH MEHTA
Date: March 15, 2004
Thesis Advisory Committee
__________________________[Chair]
[PANKAJ CHANDRA]
__________________________[Co-Chair]
[DEVANATH TIRUPATI]
__________________________[Member]
[ARABINDA TRIPATHY]
1
Production Planning and Scheduling in
Multi-Stage Batch Production Environment
By
Peeyush Mehta
ABSTRACT
We address the problem of jointly determining production planning and scheduling
decisions in a complex multi-stage, multi-product, multi-machine, and batch-production
environment. Large numbers of process and discrete parts manufacturing industries are
characterized by increasing product variety, low product volumes, demand variability and
reduced strategic planning cycle. Multi-stage batch-processing industries like chemicals,
food, glass, pharmaceuticals, tire, etc. are some examples that face this environment. Lack of
efficient production planning and scheduling decisions in this environment often results in
high inventory costs and low capacity utilization.
In this research, we consider the production environment that produces intermediate
products, by-products and finished goods at a production stage. By-products are recycled to
recover reusable raw materials. Inputs to a production stage are raw materials, intermediate
products and reusable raw materials. Complexities in the production process arise due to the
desired coordination of various production stages and the recycling process. We consider
flexible production resources where equipments are shared amongst products. This often
leads to conflict in the capacity requirements at an aggregate level and at the detailed
scheduling level. The environment is characterized by dynamic and deterministic demands
of finished goods over a finite planning horizon, high set-up times, transfer lot sizes and
perishability of products. The decisions in the problem are to determine the production
quantities and inventory levels of products, aggregate capacity of the resources required and
to derive detailed schedules at minimum cost.
We determine production planning and scheduling decisions through a sequence of
mathematical models. First, we develop a mixed-integer programming (MIP) model to
determine production quantities of products in each time period of the planning horizon. The
objective of the model is to minimize inventory and set-up costs of intermediate products and
finished goods, inventory costs of by-products and reusable raw materials, and cost of fresh
raw materials. This model also determines the aggregate capacity of the resources required
to implement the production plan. We develop a variant of the planning model for jointly
planning sales and production. This model has additional market constraints of lower and
upper bounds on the demand. Next, we develop an MIP scheduling model to execute the
aggregate sales and productions plans obtained from the planning model. The scheduling
model derives detailed equipment wise schedules of products. The objective of the
scheduling model is to minimize earliness and tardiness (E/T) penalties.
We use branch and bound procedure to solve the production-planning problem.
Demand of finished goods for each period over the planning horizon is an input to the model.
The planning model is implemented on a rolling horizon basis.
2
We consider flowshop setting for the finished goods in the production environment.
The due dates of finished goods are based on the customer orders. We report some new
results for scheduling decisions in a permutation flowshop with E/T penalties about a
common due date. This class of problems can be sub-divided into three groups- one, where
the common due date is such that all jobs are necessarily tardy; the second, where the due
date is such that the problem is unrestricted; and third is a group of problems where the due
date is between the above two. We develop analytical results and heuristics for flow shop E/T
problems arising in each of these three classes. We also report computational performance on
these heuristics. The intermediate products follow a general job shop production process with
re-entrant flows. We develop heuristics to determine equipment wise schedule of
intermediate products at each level of the product structure. The due date of an intermediate
product is based on the schedule of its higher-level product.
The models developed are tested on data for a chemical company in India. The results
of cost minimization model in a particular instance indicated savings of 61.20 percent in
inventory costs of intermediate products, 38.46 percent in set-up costs, 8.58 percent in
inventory costs of by-products and reusable raw materials, and 20.50 percent in fresh raw
material costs over the actual production plan followed by the company. The results of the
contribution maximization model indicate 42.54 percent increase in contribution. We also
perform sensitivity analysis on results of the production planning and scheduling problem.
The contribution of this research is the new complexities addressed in the production
planning and scheduling problem. Traditional models on multi-stage production planning and
scheduling are primarily based on assembly and fabrication types of product structures and
do not consider the issues involved in recycling process. Scheduling theory with E/T
penalties is largely limited to single machine environment. We expect that models developed
in this research would form basis for production planning and scheduling decisions in multi-
stage, multi-machine batch processing systems. The sensitivity analysis of the models would
provide an opportunity to the managers to evaluate the alternate production plans and to
respond to the problem complexities in a better way.
3
Acknowledgements
I wish to express my deepest gratitude to my thesis advisor Professor Pankaj Chandra.
He has been a tremendous source of learning for me during my stay at IIMA. Professor
Chandra has been a great motivator, and has a significant share in my academic grooming.
Much of the credit for this work goes to Professor Devanath Tirupati, co-chair of my thesis
committee. He has been very patient with me and has provided very useful research training. I
would also like to thank Professor Arabinda Tripathy, member of my thesis committee for
providing very useful feedback throughout my work.
I am grateful to Professor Diptesh Ghosh, Professor P. R. Shukla, Professor Ashok
Srinivasan and Professor Goutam Dutta for their useful feedback on my thesis. I am also
thankful to Professor Shiv Srinivasan for giving some pointers on the drafting of this
document.
I wish to especially thank my wife Ritu, as this thesis would not have been possible
without her support. She has a major share in raising our daughter Riti, and her break from her
professional career helped me to stay focused on my work Riti always provided the much-
needed break from the thesis work. I dedicate this work to my parents. They have eagerly
waited to see me accomplish this work. Dhiraj, my brother, has been, as always, a source of
encouragement.
I would like to thank my colleagues Bharat, Rohit, Satyendra and all those with whom
I have interacted at various stages of my thesis. The staff members of FPM office, computer
center and library have obliged me in more ways than one.
4
no reviews yet
Please Login to review.
