Basically aspects in order to reduce the vibration of machine tools with nonconventional materials structure.
Paun, Loredana ; Predincea, Nicolae ; Avramescu, Valeriu 等
1. INTRODUCTION
The modern tools-machines match overwhelmingly demands flexibility,
increased productivity, simple cinematic structure, modern drives made
on CNC equipment with a large number of axles (5 or more). Also, they
are specific: high rigidity, high accuracy, good dynamic and thermal
behavior.
The paper presents a study regarding the dynamic behavior of the
structure elements which are made of composite materials of a CNC
machines for multiple operations of turning, milling, drilling, boring,
toothing, etc.
In order to reduce the weight of machine, the frame is made of
composite material, adopting compensating solutions to reduce vibrations
and providing the necessary rigidity. These composite materials are
formed by pultrusionate profiles made of fiber glass embedded in a mass
of thermal resin (www.fiberline.com).
During the processing function of cutting conditions parameters,
appear some unbalanced forces that cause vibrations that contribute to
precision processing and final quality of the processed part. Besides
the vibrations which are generated during the processing may occur also
some vibrations from the surrounding area (other machine tools,
equipment, sources generating vibrations etc.). To attenuate this, the
technique solution is to mount isolators on the multifunctional machine
foundation--vibration shock--to prevent the transmission of vibrations
from the source of harmful to the environment and the environment in
multifunctional machine tool.
2. ALGORITHM FOR OPTIMIZATING THE ABSORBTION ELEMENTS OF VIBRATIONS
In isolation anti_vibrators study, is considered a multifunctional
machine tool with 8 axes, which can be considered a rigid body composed
of 12 pillars, 11 sleepers and 2 carriers, which are strutting by 180
metal corner units. This assumption has the significance that its
frequencies of cutting and manufacturing elements are different than
parts of the stiff under isolation, so practically not influenced it. To
determine an algorithm for calculating need to use modeling--figure 1.
[FIGURE 1 OMITTED]
The machine is considered as one rigid body of mass m, elastic
seated on the floor. This model has 6 degrees of freedom--so 6 own
pulsations--namely 3 translations along the axes x, y, z and 3 rotations
around these axes.
It is known that the amortizations had little influence on own
pulsations and on their modes of vibration. Therefore, to study the own
pulsations, the mathematic model will be characterized by mass m, mass
moments of inertia from the three axes of coordinates and elastic
constants of items absorption vibrations. In equations of the rotation
motion, are intervening the moments of inertia of the masses. The moment
of inertia of a body of mass m from the zy plane has the expression:
J = [integral] [x.sup.2]dm (1)
As the multifunctional machine can be similar to a parallelepiped
of mass m, with [a.sub.x], [a.sub.y] and [a.sub.z] sides, then the
moments of inertia of the rigid towards the tried axles x, y, z are the
following:
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] (2)
For the 6 degrees of freedom, if the main elastic axes of the
damping elements coincide with the axes of coordinates, the constants
are: [k.sub.x], [k.sub.y], [k.sub.z], [k.sub.[phi](x)],
[k.sub.[phi](y)], [k.sub.[phi](z)].
The body is lean on a certain number of elastic supports. It may be
a bearer 1, which has on the directions of its elastic axes, the main
constants [k.sub.p1], [k.sub.r1] and [k.sub.q1]. These elastic axes have
the directories cosine [[lambda].sub.xp], [[lambda].sub.xq],
[[lambda].sub.xr], [[lambda].sub.yp], [[lambda].sub.yq],
[[lambda].sub.yr], [[lambda].sub.zp], [[lambda].sub.xq],
[[lambda].sub.zr] toward the xyz tried. Another bearer 2, may be
represented by its elastic constants [k.sub.x2], [k.sub.y2], [k.sub.z2]
which are determined on the parallel directions with the coordinate
axes. It notes, too, by [a.sub.x], [a.sub.y], [a.sub.z] the coordinates
binding point between the rigid body and the elastic bearers.
3. VIBRATION INSULATORS APPLICATION
The multifunctional machine is designed to perform various cutting
operations which means some features of dynamic action. The issue of
vibrations amortization to the machine involves solving three sequences:
to reduce vibrations to a minimum the operator's own group, reduced
to a minimum the transmission of vibrations in the machine and reducing
to a minimum the transmission of vibrations from the machine to the
floor and back hall (Buzdugan, 1980).
Vibration behavior of machine tools, for modes of vibration where
occurring the relative movements between tool and piece of work can be
improved through amortization. It can improve the behavior at vibrations
by choosing the corresponding vibration of the cutting, the tool
geometry and much less the geometry of processing piece. The cutting
system and the tool geometry influence the self excitation vibrations
that result in inadequate processing. It is well described in literature
(Harris & Crede, 1969) that, during processing of a piece may appear
self excitation vibrations--that there are areas of the processing
machine in which vibration is amplified although far from the resonance
of the structure. The cutting should be operated so as to be outside the
self excitation vibrations because during this system the surface
quality of the piece that process falls below the projected level. In
this sense should be well controlled the technological process
parameters.
In order to improve the processing, to reduce the vibrations, could
increase a rigidity of the assembly made by tool and the processed piece
or to the shocks amortization which are applied to the tool or to
improve the tool geometry.
A special issue of amortization presents a vibration attenuation of
the vertical, parallel pillars, which close to the main locker on the
side. Because the two primary components from the main chanson of
resistance do not enter in resonance, is proposed:
a) A simultaneous amortization solution--one against the other. The
amortization is made through two rubber pads that can be charged with
the task of relative distance by simultaneously using a threaded
spindle. Force to be charged with the two pads will be determined
experimentally. It is possible that the loading force to be uniform
across all pairs of dampers or to vary according to a mathematical
function. By the vibration measurements will determine the positions of
the double dampers placement and their number.
b) Between the two vertical pillars must be a minimum mass
difference for 1,41 for the two pillars do not enter in resonance at the
same time.
Under machine structure we propose to place some isolators--elastic
dampers--considering that the floor is rigid and immobile. In this case,
the proportions which control the quality of isolation are the
displacement amplitude of the multifunctional machine during the
operations to achieve that was designed and sent ground forces.
Result that the structure of a multifunctional machine tool has a
dual role: to provide some support by static pressure on the floor
through the insulator and to contribute to the isolation anti_vibration.
4. THE CALCULATION OF RUBBER IZOLATORS VIBRATIONS
The amortization problem raises three issues: the dimensioning
calculations, choice calculations and a location efficient insulator of
vibration on the rubber foundation.
Many companies have launched on the market of vibration isolators,
rubber (Buzdugan, 1986), but presenting basic information or summary.
The only company that is respected in this area is firm Trelleborg
(www.trelleborg.com) which provides users with a computer program and
diagrams choice of types of insulators in their own catalogs. Entry
data:
--Machine mass: 2000 kg
--Number of insulators--variable: 4, 6, 8, 10
--Rotation speed of the main engine: 0 - 5000 rpm
--The type of equipment that is mounted: machine tools, RAEM class,
maximum performance from vibrations and noise.
Calculations were performed with RAEM chart. Summary of
calculations is presented in table 1 (Broch, 1973).
In the first stage, the four vibration isolators rubber will be
placed in the corners of the base frame that forms the foundation of the
multifunctional machine. These measurements will be the reference.
In the second stage, the isolators will be move simultaneously on
the foundation of the machine to the edge bars because different
processing schemes have completely different characteristics and
generates different vibrations. These measurements will show where to
place, in the final, the vibration isolators and maximum degree of
damping which can be obtained.
In the third stage, when it will be simultaneous processing
operations, will make measurements for confirmation again, the correct
position of the vibration insulator rubber.
5. CONCLUSIONS
Of all the possible variations, the best insulation to ensure a
vibration insulator of 1500-40 which will achieve the performance of
damping of 87% to a number of turns of 1200 rpm of the main engine and
99% when its number of turns passes 2400 rpm. Trelleborg diagrams also
shown that if the frequency of the main engine of the multifunctional
machine falls below 7 Hz value--equivalent to number of turns below 420
rpm--it's possible entry to resonate of insulators--rubber bumpers.
The completed entry in resonate of the insulators--rubber bumpers is
produced at a turns of the main engine of 5 Hz -300 rpm.
From the above we recommend the use of work range with the main
engine over 420 rpm. From calculations show, confirming theoretical
considerations and the equations above, the degree of damping of
vibrations with isolators--selected bumper rubber increases with
increasing engine speed.
6. REFERENCES
Harris, C.; Crede E.(1969). Shocks and vibrations handbook,
McGraw-Hill, New York
Buzdugan, Gh., (1980). The antivibration isolation of the machine
tools. Academiei Publishing RSR, Bucharest
Buzdugan, Gh., (1986). Material strength. Academiei Publishing,
Bucharest
Broch, J., (1973). Mechanical vibration and shock measurements.
*** (2008) www.fiberline.com Fiberline composites, Accesed on
2009-02-20
***(2008) www.trelleborg.com Trelleborg Industrial AVS, Accessed on
2009-02-18
Tab. 1. The calculation of rubber izolators vibrations
Number Charge/ Types of Degree of Ridging
of insulator, insulators damping, damper,
insulators daN which may % mm
be use
4 500 1500-40 87 2,8
500 1500-60 70 6,0
6 333 800-40 81 4,5
333 350-60 70 5,5
8 250 800-40 65 6,8
250 350-60 45 3,0
10 200 350-40 82 6,8
200 800-40 65 5,3
200 350-60 45 3,0
