Clamping intelligent modular systems for cutting process.
Nita, Raluca ; Avramescu, Valeriu ; Craciunoiu, Stefan 等
1. INTRODUCTION
The evolution of modern society, marked by widespread of the
technological innovation has accelerated products and demands
diversification regarding their performances and imposed precision,
reliability and productivity of manufacturing processes expectations,
systems development in order to be capable to ensure the new
requirements.(Nita & Craciunoiu, 2009) In order to have the
possibility to process all kind of technological operations on
multifunctional machine tools it is important to design modular
structures for pieces clamping. (Paunescu et al., 2006). For answering
to the technological and functional needs of the processing process the
developed structures are equipped with sensors, drive systems, command
and control assets, so the developed fixing systems are able to respond
in real time requirements of the technological process, changing them
functional characteristics depending to the changes occurred in the
process and in the initial working sets.
2. GENERAL INFORMATION
Principal component of a production process is represented from
technically point of view by the technological process, which includes
various activities not only at the organizational level, but also at the
economic, managerial, etc... In order to achieve for pieces with complex
geometrical shapes high dimensional precision, roughness according to imposed technical specifications, it is necessary to adapt the
technological processing to ensure the full complexity of technical
requirements, technological and functional.
Improving the processing technologies is determined by the
evolution of processing, assembly or control equipments. The device, in
general, represents an important component that aims to ensure the
products quality level, work productivity, systems flexibility and
economic efficiency. This objective is achieved by ensuring the piece
positioning accuracy in order to reduce the influence of external
parameters processing, under orientation precision aspect, geometrical
precision, functional precision and adaptability to the product changes
and costs of the process.
Because of the multiple processing posibilities turning, milling,
drilling, broaching, slotting, toothing and plane, exterior and interior
cylindrical, rectification, and spiral, clamping systems it is necessary
to be desing in modular variant, for an easy adaptation to any working
conditions. (Paunescu et al., 2006).
An intelligent clamping device is necessary to respond to the
specific processing needs and to be capable to addapt relatively easy to
any kind of technological process.
Technological and functional needs of working are different from
process to process so that the structures of the developed devices in
order to respond in real time to the effective problems appeared during
the technological process, are equipped with sensors, drive systems,
command and active. (Nita & Craciunoiu, 2009)
Intelligent devices have the possibility to change their behavior
as an adaptation to changes in the internal and external medium, through
intelligence being understood by the ability of a system to achieve a
particular purpose or to have a desired behavior under conditions of
uncertainty, namely the emergence unexpected events and unexpected and
incomplete and insufficient information to decide what to do. They are
able to take decisions in these circumstances of uncertainty, being
different of those that are scheduled to perform repetitive operations,
also capable of changing their own behavior but on the basis of orders
given by a human operator.
3. DATA ACQUISITION SYSTEM--INTEGRANT PART OF AN INTELLIGENT DEVICE
Data acquisition represents the process of obtaining data from an
external source of computing system, through the measuring process some
the systems parameters, in the frame of supervision and management of
industrial processes; because the measurement and recording of data not
satisfies the requirements of leadership, were imposed multiple
functions required for the data acquisition systems, namely:
* Converting the physical phenomenon in a measure that can be
measured.
* Getting signals from sensors for the purpose of extracting
information.
* Data analysis and presentation in a useful form.
* Command signals generation for the exectoin elements from the
adjustment loops coupled with the data acquisition system.
While a classical measurement system process throughout the whole
measurement chain the signal received from the transducers only in
analog form, a computerized measurement system transform the signal in a
measured value from an analog to a digital form. After this
transformation, all the respectively signal processing are actually
numerical processing, performed in a system based on microprocessor
(computer).
[FIGURE 1 OMITTED]
4. TECHNICAL AND FUNCTIONAL
CHARACTERISTICS OF THE INTELLIGENT MODULAR DEVICES
Dominant feature of a flexible fixing system also refers to the
possibility of easy adaptation to the type of process: the process of
cutting (turning, milling, drilling, grinding etc.). It should ensure a
high level of work productivity and of the product quality and economic
efficiency (Costea & Rachieru, 2005).The modular fixing elements
offers the possibility of constructing a variety of devices for
orientation and fixing, multifunctional (Costea & Rachieru, 2005),
through some families of products in which construction to retrieve
assemblies or identical parts, taking into consideration the concept of
"Baukasten" games, (Costea & Rachieru, 2005) being
possible to achieve such complex structures of elements of fixing
devices by combining in a multitude of variations of the same components
called modules (Costea & Rachieru, 1998; Prospectes, 2009).
In order to achieve the most accurate operating conditions for the
machine tools processing devices, concerning the orientation, the
geometry, the size and the functionality, these devices have been
supplied with sensors meant to deliver accurate information during the
processing procedure.
Cutting forces size are influenced by cutting regimes, the
mechanical properties of the material of the half finished product, and
have percussive nature at the first contact with the tool and variable
during the cutting process as a result of the material unevenness and
tools wear. Since there is no precise mathematical model to express tool
shape depreciation, we use sensors that provide information about the
size of the cutting forces, because they reflect the state of wear of
the tool. (Nita & Craciunoiu, 2009)
Data collected at the sensors level are transmitted to a computer,
which aims to ensure the active command of the processing. Signals can
be taken directly by measuring tool geometry, the distance between the
tool and the piece, the vibrations of the tool and also of the part,
clamping force, and cutting forces. The data are compared with normal
values, typical for work conditions, and for the given results of the
clamping force and cutting force can be adjusted, up to complete hold of
working process, to ensure the processing conditions of geometrical,
orientation, dimensional and functional precision.(Nita &
Craciunoiu, 2009). The novelty of fixing devices, besides the high
degree of modularization, flexibility, automatically adjusting to the
effective work condition appeared during the technological process with
the help of sensors, drives systems, command and active control.
The construction of modular fixing devices ensure them the maximum
flexibility, so that by combining different modules can be obtained
different types and constructive variants corresponding to a variety of
technological needs, by fast converting a variant of the device to
another and a type of production to another in case of changing the
production type. (Paunescu & Bulea, 2006)
Depending on the data collected by sensors, after their analysis
through a program in which optimal values are recorded as such that
process to take place in conditions of optimal safety, from the
functional point of view and of the work parameters, is done an active
command system based on control loop, which allows control of the
device. In this way it is realized the connection between the process
and the intelligent clamping device, through a feedback of control,
based on the signals acquired by the sensors. After the signals are
compared with values which are predefinited, thanks to the system of
active control, the variable parameters of the device (such as clamping
force, tools rotation) are modified in order to achieve even pieces with
complex geometrical shapes at high dimensional precision, roughness
according to imposed technical specifications.
[FIGURE 2 OMITTED]
For obtaining systems with higher performances that the classic
ones, the typical performance of the command software should include:
the command of the informational flux, the command of the processing
process, monitoring and command of the performances, visualization the
system functional stage.
5. CONCLUSIONS
Designed devices must have a high level of modularization,
productivity, flexibility and adaptation, both for flexible
configuration of processing systems and for guidelines and systems for
specialized processing.
Dominant feature of a flexible fixing system also refers to the
possibility of easy adaptation to the type of process: the process of
cutting (turning, milling, drilling, grinding etc in the conditions of
the small and medium production requirements. Because the fixing system
it's designed from modular elements that can be combined depending
on the type of process and of the imposed fixing restrictions can be
used in most of the activities domains. In order to answer to the
technological and functional needs of specific process the developed
structures are equipped with sensors, drive systems, command and control
assets, in order to be able to respond in real time requirements of the
technological process, changing them functional characteristics
depending to the changes occurred in the process and in the initial
working sets.
6. REFERENCES
Costea, A. & Rachieru, N. (2005). Flexibilitatea si
performanftle echipamentelor de prelucrare. Optimizarea proiectarii
dispozitivelor, Bren Publishing, ISBN 973-648-391-63, Bucharest
Costea, A. & Rachieru, N. (1998). The increase of performances
and technological flexibility of multi-purpose machines through the
equipment with multi-functional modules. ICMaS'98, Technical
Publishing, ISBN 973-311236-4, Bucharest
Nita, R.; Craciunoiu, S.; Avramescu, V. & Marin, G. (2009).
Inteligent fixing sistems on multifunctional machine tools, Proceedings
of the 13th International Conference ModernTechnologies, Quality and
Innovation, ISSN 2066-3919 Iasi, 2009
Paunescu, T.; Bulea, H. & Paunescu, R. (2006). Dispozitive
Modulare. Construcfie, Exploatare, vol. I. Technical Publishing of
Transilvania University, ISBN (10) 973-635723-6, Brasov
Prospectes of the firmes (2009). Hohenstein--Germania, Mauser-Werk
Oberndorf GmbH Germania, Helge F. Mara Prazizionswerkzeuge--Austria,
Norelem Franca
