Influence of kinematic parameters on the deterministic vibrations of the linear-elastic connecting rod: component of a rod lug mechanism.
Bagnaru, Dan Gheorghe ; Grozea, Marius-Alexandru ; Nanu, Gheorghe 等
1. INTRODUCTION
The researches that were done until now by several authors
determined only the transversal displacements for vibrating beams, but
which do not move. This involves restrictions of the conditions.
We propose an original method, based on an iterative method of
determining the field of transversal displacements of the
linear-viscoelastic rod of a rod lug.mechanism. In our future studies,
for the same problem we analyze now, we will determine the influence of
the aleatoary vibrations.
2. THEORETICAL RESULTS
By distributing the coupling terms between the longitudinal and
transversal vibrations (Bagnaru, 2005), as well as the terms which
confer to the mathematical model the quality of an invariant model in
time, it results the model as the matrix:
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII]. (1)
As a result of an iterative process, it results the mathematic
model in 'j' approximation, in the form:
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII]. (2)
The solution in 'j' approximation will be:
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII],
where [u.sup.(j).sub.1,c])(n,t) and [u.sup.(j).sub.2,s] (n,t) are
the Fourier transforms finite in cosine and sine respectively, of the
longitudinal elastic displacement, and transversal respectively.
The process of successive approximations is considered completed
when, for ([for all])n,
[parallel]{[u.sup.(j)]}-{[u.sup.(j-1)]}[parallel] [less than or equal
to] [epsilon] occurs, where [epsilon] > 0 and small enough depending
on the required calculation precision, and
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII].
With {F} = {0}, {f } = {0} and m = 0 in equation (1), it results
the mathematic model of the free vibrations, in a first approximation,
having the form:
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII].
We will only present the transversal displacement, solution of
equation ([1.sup.(1)]
[MATHEMATICAL EXPRESSION NOT REPRODUCIBLE IN ASCII] (3)
[FIGURE 1 OMITTED]
3. NUMERICAL APPLICATION
If we situate ourselves in the concrete case when the lengths of
the connecting rod in OL45 and the lug are: L = [L.sub.b] = 1 [m], r =
0,075 [m], and the width and thickness of the connecting rod are b =
0,04 [m], h = 0,005 [m] respectively, we obtain, by using relation (3),
the numerical values of the transversal elastic displacement (in the
middle of the connecting rod), presented in table 1 These values are
comparable with those experimentally obtained (see figures 2-5), the
error being around 6,695% .
4. EXPERIMENTAL TESTS
The experimental tests were made on a stand, using a device
composed of the acquisition electronic system Spider 8 for the numeric
measurement of the analogical data, the signal conditioner NEXUS
2692-A-0I4, accelerometers Bruel & Kjaer 4382, the inductive linear
translator WA300 and Notebook IBM ThinkPad R51.
We analysed the dynamic response (Harrison, 1997) to variable
strains of the connecting rod made of OL 45 universal iron.
The mechanism connecting rod lung was driven by a three-phase
alternating current engine of 25 KW power, with constant turation of
1500 [rot/min]m, with the aid of a friction variator, so that variable
turations of 60 ... 240 [rot/min] could be achieved at the level of the
connecting rod.
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
In order to determine the dynamic response (Routh, 2003), we used
an accelerometer Bruel & Kjaer 4391 successively installed in the
middle of the connecting rod (pt. 2) on vertical and longitudinally
horizontal directions reported to the plane of the connecting rod. The
run/stroke was determined at the level of the slide by the inductive
translator WA 300, the slide having the value of 140[mm].
In the middle of the connecting rod, the fundamental harmonic has
the major contribution. The contribution of the harmonics of order 4 and
5 increases with the turation speed growth.
5. CONCLUSIONS
The field of the longitudinal displacements has an insignifiant
influence on the stress or deformation states. That is why we did not
give the solution of the ecuation ([1.sup.(1)]) as a function which
characterize this field, too.
The paper is extremely important for blueprint activity where one
must take into consideration the influence of dynamic parameters upon
the vibrations (Bagnaru & Marghitu, 2000) to which the connecting
road of this system is submitted, a constitutive part of, say, an
internal combustion engine.
6. REFERENCES
Bagnaru, D., Marghitu, D.B. (2000). Linear Vibrations of
Viscoelastic Links, 20th Southeastern Conference on Theoretical and
Applied Mechanics (SECTAM-XX), April 16-18, 2000, Callaway Gardens and
Resort, Pine Mountain, Georgia, USA, pp 1-7
Bagnaru, D. (2005). The influence of the vibrations upon the stress
and deformation states in case of the linear-elastic connecting rod for
a slider crank machanism R(RRT), Annals of the Oradea University.
Fascicle of Management and Tehnological Enginering, pp 97-104, ISSN 1583-0691.
Fu, K.S., Gonzalez, R.C. & Lee, C.S.G. (1997). Robotics,
McGraw-Hill
Harrison, H.R. (1997). Advanced Engineering Dynamics, John Wiley
& Sons Inc., New York
Routh, E.J. (2003). Dynamics of a system of rigid bodies, Part l
& Part 2, Macmillan
Tab. 1. The numerical values of the transversal elastic
displacement
Transversal Frequency Frequency 1,5381 1,3916
displacement 2,8198 3,0030 (Hz) [Hz] [Hz]
on the (Hz)
direction
OT [mm] -- -- 0,14 0,13
V[mm] 21 20 -- --
