Complementary economic validation algorithm in optimizing manufacturing architectures.
Chiscop, Florina ; Carutasu, Nicoleta Luminita ; Parpala, Lidia Florentina 等
1. INTRODUCTION
Our optimizing algorithm takes into account that before any
manufacturing process starts we use the marketing studies to include the
customer demands in the preliminary product modelling phase. Then we use
the CAE module to simulate the real product behaviour in exploitation in
order to validate our preliminary product virtual prototype.
When this 3D model validated we need to study in detail the product
manufacturing processes determining the necessary tools and machines as
elements of the preliminary manufacturing architecture. In order to
optimize and eventually validate this preliminary manufacturing
architecture the next step is to virtually simulate the material flow in
order to identify and eliminate eventual flow concentrators that slow
down or even block the production.
For the analysis that will be made in order to eliminate the
concentrators we need to choose between a functional remodelling; (it
consists in changing some of the machines placement, the order of some
operations, the speed of some conveyor belts or manufacturing times) and
a technological remodelling; (it consists in reconsidering all the
manufacturing structure system data: the type of the machines, tools,
transport and transfer facilities etc ). The new system is remodelled
and a material flow simulation for the system is done (Anghel et al.,
2009). We define diffused manufacturing systems as architectures with
more than two working points connected by transport and transfer systems
and using buffers (Coulouris et al., 1995). When taking in consideration
concentrated systems we can define them as architectures based on a
single work point surrounded & assisted by transport, transfer &
deposit facilities (Cotet & Dragoi, 2003).
If technological remodelling is chosen, after using an economical
analysis to compare the necessary investment with the increasing
productivity benefits we finally validate the product as well as the
manufacturing architecture design (Cotet et al., 2009). Here we are.
If the classical economic validation algorithm uses mainly net
present value based analysis in our new methodology we include also a
cost/ use value report.
2. A FEW STEPS IN MANUFACTURING ARCHITECTURE ECONOMIC VALIDATION
ALGORITHM
We will briefly present here the cost/use value report methodology
used twice in our economic validation algorithm.
In order to illustrate this algorithm we will use a study case for
remodelling the manufacturing architecture of a milling machine main
shaft without increasing the production expenses.
In our case study we optimize a diffused manufacturing system
(Chiscop et al., 2010). The easiest way of doing that is by using
functional remodelling, changing some of the machine placement in the
production site, the order of some operations, etc. Of course if this
doesn't work we will have to consider technological remodelling,
modifying the manufacturing architecture. A new simulation must be
performed to validate the optimized manufacturing architecture.
For our study case we use the manufacturing cycle of a milling
machine main shaft. We will start by determining the manufacturing
processes required in order to obtain the shaft starting from a blank
with a diameter of 80 mm and length equal to 345 mm. Then we must
calculate the manufacturing time needed in order to establish the number
and type of the machine tools used in the production site.
For calculating the necessary time we must know some technical
parameters from the machines used, like the cutting speed, rotation
parameter, as well as the crossing numbers for each process, stroke, the
blank's diameter, etc.
It is very important to do a correct calculus of the necessary
times because these will lead to a correct parameterization of the
machines when running the simulation. If the necessary times are not
calculated correctly the results obtained from the simulation are
incorrect and so the manufacturer can't rely on them.
A number of 23 manufacturing processes were established. For each
manufacturing processes we calculated the manufacturing cycle time.
We determine the manufacturing times for all the operations, so in
this phase we know the total amount of time that takes to manufacture
the shaft. Now we can establish the machine tools used in the
manufacturing process: debtor machine, lathe machine, milling machine,
boring and grinding machine.
[FIGURE 1 OMITTED]
Before starting any production cycle it is advisable to perform a
cost/use value report analysis and then run a material flow simulation
using dedicated software. The information gathered can be useful both
for beneficiary and manufacturer. For example we can learn about the
productivity rates, displacement of the work points, auxiliary
manufacturing times, and human operators' role. For our case study
we define 9 main functions. The calculated use values for those
functions are presented in table 1. In figure 1 the structure of those
functions associated costs is presented. The report of use value and
costs is presented in figure 2. One can use this representation in order
to check if for some functions the use value is smaller than the
associated costs.
Using the data obtained we are going to build the model for the
production site (figure 3). The elements presented in this model are:
machine tools (debtor machine--D1, lathe machine--S1, milling
machine--F1, boring and grinding machine MAR1), each of them having an
operator (L1 to L4) supervising the production cycle, conveyor belts (C1
to C4) used for transporting the blank (P1) from one work point to
another and buffer (B2) for depositing parts.
For building the model and simulating the material flow we choose
Witness simulation software. We agree here with the thesis that within
the class of stochastic simulation models, one further distinction is
necessary: simulations can be either terminating (sometimes called
finite) or non-terminating in nature, with specific algorithms for each
category.
After the model is finished we run a simulation for a finite period
of the time (one month), 22 working days, 16 working hours a day and
obtained a productivity of 138 pieces.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
The first problem that we noticed was the bottleneck situated on S1
entrance caused by the big manufacturing times that this machine has.
This means that the material flow is either slowed down or stopped
causing problems throughout the whole system. The manufacturing time on
S1 is 3 times bigger than the one of the D1.
3. CONCLUSIONS
After analysing the results obtained we can start thinking about
optimising the system. And because the biggest problem represents the
bottleneck on the S1 entrance after excluding functional remodelling due
to 1/4 reports of effective manufacturing times at D1 and S1 work
points, we consider adding another lathe machine, two conveyor belts and
a human operator.
After rebuilding the model we run a simulation for this new model
and obtained an increasing of the productivity of over 30%. In this way
we eliminated the bottleneck presented in the previous manufacturing
architecture. In this point, before we can continue with the
optimisation process aiming for higher productivity rates we must have
in mind that by modifying the architecture, especially by adding work
points we raise the production costs. That implies a second economic
validation based on the cost/use value report.
4. REFERENCES
Anghel, F.; Popa, C. L. & Aurite T. (2009). Functional and
Technological Remodelling in Optimizing Manufacturing Networks
Architecture (2009). 0809-0810, Annals of DAAAM for 2009 &
Proceedings of the 20th International DAAAM Symposium, ISBN 978-3-901509-68-1, ISSN 1726-9679, Editor B. Katalinic, Published by
DAAAM International, Vienna, Austria 2009, November, Vienna, Austria
Cotet, C.E.; Popa, C. L.; & Anghel, F. (2009). Manufacturing
architecture design using discrete material flow management, In:
International Journal of Simulation Modelling IJSIMM, volume 8, no. 4,
December 2009, pp.206-214, ISSN 1726-4529, Vienna
Cotet, C.E., Dragoi, G.S. (2003). Material Flow Management in
Validating Concentrate and Diffused FMS Architectures, In: International
Journal of Simulation Modelling IJSIMM, no. 4, December 2003,
pp.109-120, ISSN 1726-4529, Vienna
Chiscop F.; Popa C. L. & Cotet C. E. (2010). Product and
Manufacturing Architecture Design using Virtual Modelling and Simulation
Techniques, The Fifth International Conference on Optimization of the
Robots and Manipulators--OPTIROB 2010, pp. 241-245, ISBN:
978-981-08-5840-7
Coulouris G., Dollimore J., Kindberg T.. Distributed Systems:
Concepts and Design, Addison-Wesley 1995, ISBN 0-201-62433-8
Tab. 1. Functions description
Symbol Function name [U.sub.v]
A Driving motion 20.99
B Fixing elements 16.05
C Positioning elements 16.05
D Sealing 3.70
E Allows access 1.23
F Takes shocks 11.11
G Bearing function 7.41
H Takes loads 7.41
I Centering elements 16.05
