Functional and technological remodelling in optimizing manufacturing networks architecture.
Anghel, Florina ; Popa, Cicerone Laurentiu ; Aurite, Traian 等
1. INTRODUCTION AND DEFINITIONS
Prior to any manufacturing process a simulation for the existing
material flow is needed in order to identify the bottlenecks where the
material flow is slowed down or even blocked. There are a number of
simulation programs which can be used in this matter. For our study case
we choose Witness simulation program. Our algorithm is based on the
description of the modelling process in Witness, of the machines used
and of the manufacturing parametrical values (Ilar et al., 2008).
In this way one can obtain valuable information regarding
productivity, the necessary number of machines, the personal involved in
the production cycle and both the manufacturer and the beneficiary will
know an approximate production cost (Anghel et al., 2008).
We consider a material flow and process synchronous simulation the
simulation of a model where at the level at the work point the process
simulation is concomitant with the material flow simulation.
A multipolar synchronous simulation can be defined as an integrated
system for monitoring more than two manufacturing systems material flow
simulations that are interconnected in virtual enterprise architectures
(Popa & Cotet, 2008). We agree that the virtual enterprise
represents a temporary alliance of enterprises who wish to share
resources and aptitudes for the purpose of making a product in the
shortest time possible, at the smallest price possible, and with the
maximum satisfaction of the client (Camarinha-Matos et al., 1997).
We define diffused manufacturing systems as architectures with more
than two working points connected by transport and transfer systems and
using buffers. 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.
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 (Sanchez, 2001).
[FIGURE 1 OMITTED]
2. MANUFACTURING NETWORKS SIMULATION
The first manufacturing system consists in: debtor machine (D1),
lathe machine (S1), milling machine (F1), boring and grinding machine ([MAR.sub.1]), each of them having an operator supervising the
production cycle. After studying the activity reports we found a
bottleneck at S1 machine caused by the big working times the blank has
to spend on this machine. Because of this flow concentrator both D1
machine and C1 conveyor are blocked most of the time (for example D1 is
blocked 55% of the time) (fig. 1). For optimising the first
manufacturing system we can use functional remodelling; it consists in
changing some of the machines placement, the order of some operations,
the speed of some conveyors or manufacturing times or technological
remodelling; it consists in reconsidering all the system data: the type
of the machines, tools, materials used etc. The new system is remodelled
and a material flow simulation for the system must be done.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
In the same way we build a model for the second manufacturing
system (fig. 2). Taken in consideration the operations required for
manufacturing the pulley wheel we could establish the machine-tools
used. These are, as symbolised in figure 2: a lathe machine (S2),
milling machine (F2), boring and grinding machine (MAR2). For each
machine there is an operator present with the role of supervising the
operation. All parts are collected in a buffer. For transporting blanks
among working points we used conveyor belts. Due to significant
concentrators identified on S2, C1 and C2 we obtain low productivity for
this system. The third manufacturing system will be used for the product
assembly. The entrance for this system will be the outputs from the
first and the second system. It contains the following elements: three
buffers (B1, B2 and B3), three conveyor belts and a single work point.
[P.sub.1] and [P.sub.2] represent the parts produced by systems 1 and 2.
Because of the flow concentrators identified in systems 1 & 2
we obtained a low productivity in the assembly system, thus creating the
necessity of system remodeling (fig. 3). Also, after studying the
activity report for M1 machine it resulted that this machine is blocked
almost half the working time.
3. MANUFACTURING NETWORKS REMODELLING
In order to optimise the first system we used functional
remodelling, but the results were not very satisfying and bottlenecks
were still present. We had to do a technological remodelling by adding
another lathe machine and conveyor. An NPV analysis was performed
confirming that the increasing productivity justifies the investment
done. In figure 4 we presented the optimised model for the first system.
After running the simulation we could notice an important improvement
concerning the material flow (fig. 4). The assembly point is now working
97% of the time. For the second system the functional remodelling
worked. We eliminated the flow concentrators and, thus we optimised the
system by simply changing the order of some operations and the conveyor
speed.
[FIGURE 4 OMITTED]
The bottlenecks determined were on F2 and F22 machines (60% of the
time the system is blocked; 35% the system is working properly; 4% is
waiting for parts and 1% for human activities). After remodelling the
results are: 15%--system blocked; 81%--system working; 3% is waiting for
parts and 1% for human activities. On the third system one can notice a
general improvement due to the fact that the inputs are coming more
rapidly and because of the functional remodelling applied on this
system. The machine blockage was reduced from 49% to 8%.
4. CONCLUSION
In order to optimize manufacturing network architectures we need to
create first isolated models to estimate the productivity level for each
node of the network. Using discrete material flow simulation for those
models we can identify the bottlenecks generating productivity loss. But
for the entire manufacturing network we need a multipolar synchronous
simulation model providing more accurate results regarding the network
efficiency. The flow concentrators identified on each system have an
impact over the entire architecture due to the fact that the three
models from our study case function as enterprise nodes. Thus a flow
concentrator found on one of the supply systems can reduce productivity
for the assembly system. Using multipolar simulation the bottlenecks
identified on material flow simulation can be the same with the ones
found on isolated simulations, or different ones can appear.
Any manufacturing network architecture can be optimized in two ways
using functional or technological remodeling (an economic analysis must
confirm the necessary investment). The manufacturing architecture
optimisation was done as follows: the first system was technologically
remodelled and for systems 2 & 3 we used functional remodelling. In
our future research we intend to study the effects of synchronizing process and material flow simulation in optimizing manufacturing
networks architecture based on functional and technological remodelling.
5. REFERENCES
Anghel, F.; Cazacu, D. A.; & Dobrescu, T. (2008). Virtual
Machine Tools Models in Assembling Systems Material Flow Management
(2008). 0025-0026, Annals of DAAAM for 2008 & Proceedings of the
19th International DAAAM Symposium, ISBN 978-3-901509-68-1, ISSN 1726-9679, pp 013, Editor B. Katalinic, Published by DAAAM
International, Vienna, Austria 2008, 22-25 Octombrie, Trnava, Slovacia
Camarinha-Matos, L.M.; Carelli, R.; Pellicer, J. & Martin, M.
(1997). Towards the virtual enterprise in food industry, Proceedings of
the ISIP'97 OE/IFIP/IEEE International. Conference on Integrated
and Sustainable Industrial Production, ISBN 0-412-79950-2, Portugal, May
1997, Chapman & Hall, Lisboa
Ilar, T., Powell, J. & Kaplan, A. (2008). Simulation of
production lines-The importance of breakdown statistics and the effect
of machine position, In: International Journal of Simulation Modelling
LJSIAIM, Volume 7, no. 4, December 2008, pp.176-185, ISSN 1726-4529,
Vienna.
Popa, C.L. & Cotet C.E. (2008). Multipolar distributed material
flow simulation of a virtual enterprise, Proceedings of The 19th
International DAAAM SYMPOSIUM, ^Intelligent Manufacturing &
Automation:Focus on Next Generation of Intelligent Systems and
Solutions, Katalinic, B. (Ed.), pp. 1103-1104, ISBN 978-3-901509-68-1,
ISSN 1726-9679, Published by DAAAM International, Vienna
Sanchez, S. M. (2001). ABC's of output analysis, Proceedings
of The 2001 Winter Simulation 2001, Peters, B.A., Smith, J.S., Medeiros
D.J., CD-ROM, Presses Association for Computing Machinery (ACM), New
York.
ANGHEL, F[lorina]; POPA, C[icerone] L[aurentiu] & AURITE,
T[raian] *
* Supervisor, Mentor
