Cutting tools durability as a simulation parameter in discrete material flow management.
Minciu, Constantin ; Chiscop, Florina ; Olteanu, Elena Luminita 等
1. INTRODUCTION
We define a concentrated fabrication system as a working point that
is served by stocking systems, transfer and transport what ensures its
autonomy functioning, without the interfering of the human operator
(Cotet & Dragoi, 2003). DEFORM is a simulation system for
technological processes based on Finite Elements Method (FEM), designed
to analyze different formation and thermal treatment processes and for
other associated processes from industry. Due to computer aided
simulations for fabrication processes, this advanced program becomes a
primordial instrument for designers and engineers having the following
advantages: it reduces the costs with experimental assays and processing
and processes redesign; it improves tools and matrix's design in
the purpose of lowering the production costs; it reduces the necessary
time for lunching a new product on the market (Bley & Wuttke, 1999;
Nau et al., 1993).
Compared to other software based on finite elements method, DEFORM
is designed for deformation modeling. The friendly interface allows to
easily introducing the entry data and the analyzing parameters; in this
way the user can spend more time modeling instead of learning a new
program.
[FIGURE 1 OMITTED]
An important component is the existence of an optimized
re-digitization system completely automated and adjusted for a large
scale of deformation problems.
With DEFORM it is also possible modelling thermal treatment
processes, like normalization, annealing, chilling, tempering and
ageing. The program allows anticipating durability, residuals stresses,
chilling deformations and mechanicals and materials characteristics.
2. USING DEFORM AS A PARAMETER PROVIDER FOR FLOW SIMULATION
Integrating wear models from the cutting tools in numerical finite
element calculus for estimating wear geometry of the cutting tools from
uncovered carbide. Most of the other cutting models can't give a
direct estimation of the cutting tool's wear and also can't
update the cutting tool's geometry to real scale.
Solid models that can anticipate cutting tools wear using finite
elements can: reduce necessary experimental tests number; make it easier
for the chip's breakage and the cutting edge of the cutting tool;
helps to understanding the wear effect of the cutting tool over the
residual stress and other surfaces features; helps determine wear
constants associated with different wear models of the cutting tool by
calibrating cutting experiences with finite elements simulations; helps
validate the prediction methodology of the wear cutting tool geometry
depending on the cutting conditions and compares the simulation results
to the experimental measures.
The cutting process analyses using DEFORM software gives
complementary parameters necessary to create the parametric model in
Witness (Minciu et al., 2008). Establishing the functional parameters in
Witness, at the working point, for the tool exchanging times is made by
using data obtained for the process simulation (Cotet et al., 2007).
For the studied model, after a number of working cycles, the tool
will be exchanged before the working cycle, in which interval its life
time will expire, due to the calculated durability.
3. THE EXCHANGE PARAMETERS ALGORITHM
Choosing the optimum architecture for the studied system is based
on cutting tools flow optimization correlated with blanks and
piece's flows and cutting processes optimization at working points.
The system designed in Witness is made of a machine tool (lathe turret
machine) supplied with a chain type tool storage room. For transporting
the blanks we considered a conveyor belt (the input conveyor belt from
b1 deposit is named c2 and the conveyor belt for manufactured pieces
towards b4 deposit is c4 in the model).
Tool fitting is made by the same robot that feeds the machine tool
with blanks (marked I in the model).
For the simulation we need to know the operating times (cutting
process duration plus auxiliary times), the time interval after which
the tool needs to be changed (tool's durability), the tool's
exchange time (see fig. 2). The supplying with new tools is done in the
model from depscn deposit (new tools deposit) and the used tools are put
in the depscu deposit (used tools deposit). With the help of a flow
simulation we will be able to identify the flow concentrator and give a
diagnostic regarding the system's productivity. After eliminating
this concentrator we will run a new simulation thus, establishing the
productivity for the optimized system.
This kind of optimization involves an efficiency manipulation of
the materials, lowering transport time and the waiting queues. In this
way we can lower the manufacturing cycle, the production will be more
efficient, increasing the on time delivery performance and the
product's quality.
The biggest part of the research in this aria were focused on
identifying and eliminating the flow concentrators for blank
transporting disregarding the possibility for tools transporting and
their exchanging when used. The results obtained after the process
simulation will be considered as entry data for the flow simulation, in
this way quantizing the choosing of an optimized architecture for this
kind of system.
The simulation of materials flow using discrete values can only be
done in Witness in real time, accelerated time (if we want to visualize
the system's behavior in time), or in de-accelerated time (for
particularization of the actions that lead to a critical moment in
functioning). We choose an accelerated simulation, for a time interval
of 240 hours in attempt of an optimization for medium time in this
flow's functioning. From the calculus algorithms based on rapports
given by Witness, the conveyor belt c4 is the flow concentrator. By
eliminating the flow concentrator (doubling the c4 conveyor belt
capacity), the number of pieces manufactured on the studied time
interval will increase by 20%.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
4. CONCLUSION
Up to now the studies made refer to identifying the flow
concentrator for a flexible system and eliminating it by modifying the
number of working points for balancing the traffic.
The new aspect proposed by this paper consists of the flow
regulation not by modifying the number of working points or structural
modifications, but through correlation between process simulation and
flow simulation at working point level.
The objective of this paper was to choose an optimum architecture
for a flexible fabrication system by eliminating the flow concentrators
as a result of a double modeling analyze type for a working system.
After the flow simulation we will identify the flow concentrators and
then give a diagnostic for the system's productivity.
5. REFERENCES
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Production Systems, Institute of Production Engineering / CAM,
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