The invention relates to a vibration damping device for damping vibrations occurring in structures or bodies, by means of resonators incorporated in the damping device.
The use of vibration damping devices based on the principle of resonators included in the device are known in the art. They are used for damping vibrations generated in structures or bodies, either still or in motion, when subject to impulses or forces that cause vibrations.
A damping device which uses resonators as active dynamic absorbers is disclosed in U.S. Pat. No. 5,431,261 where a structure with a large mass is damped by coupling thereto a damping member of smaller mass and continuously monitoring the frequency of excitation of the structure produced by applied load and the displacement of the damping member. The monitored frequency of excitation and displacement of the damping member are processed together with data relative to the mass, stiffness and damping characteristic of the damping member. A signal is outputted to produce a force acting on the damping member proportional to the displacement of the damping member with a controlled time delay to produce a frequency of vibration in the damping member substantially equal to the monitored frequency of excitation of the structure, this produces resonance of the damping member substantially at the monitored frequency of excitation and is effective to damp substantially the vibrations of the structure at the monitored frequency of excitation. The output signal is variable to produce resonance of the damping member variable over a range of frequencies including the natural frequency of vibration of the structure.
The results achieved by means of this damping device are not satisfactory. The harmonic response of the global system after an impulse follows a curve which reaches the desired level after too long a time.
In order to improve the damping efficiency of the damping device to bring it to a level satisfactory for engineering applications, solutions are known which provide for utilisation of damping means using viscosity effects, either alone or in addition to active dampers. However, in order to achieve a rapid damping effect such devices are too heavy, which is not always acceptable in many application, e.g. on spatial or flying vehicles.
It is therefore an objective of the invention to provide a vibration damping device which overcomes the drawbacks set forth and achieves a very high efficiency in a manner that it brings the magnitude of the vibration displacement of the body below the desired level in a very short time after the application of the impulse, such that it can be considered as nearly immediate from a practical point of view. Another objective of the invention is to provide a damping device which has a high efficiency, while maintaining a very low weight.
This result is reached by means of a vibration damping device for damping vibrations of a vibrating or oscillating entity, e.g. a body or a structure or a gas mass, adapted to be connected to the vibrating entity,
the vibrating entity defining at least one respective natural frequency (ωM),
the damping device comprises a predetermined plurality (N) of resonators,
the plurality (N) of resonators have respective natural frequencies (ωN),
with values close to a curve determined by a first formula
where mωM3/r, I/r and t0=π/(4ωM) are the parameters defining the first formula, the density of natural frequencies of the plurality of resonators is comprised within a curve that lies below the envelope curve determined by a second formula,
e(Ω)=1/|Ω−1|
where Ω=ωN/ωM is a nondimensional frequency.
The vibration device according to the invention is very simple and versatile since its application can be applied to different fields of engineering with a very high damping efficiency, regardless of the size of the vibrating structures to which it is applied.
In the following description for conciseness reason we shall refer indifferently to a body or a structure, meaning under this definition also a fluid mass or any other entity which can vibrate. In the following a resonator has to be understood as being either mechanic or electric, depending on the specific embodiment it is used. The damping device comprises a cluster of resonators with a predetermined frequency distribution, that, when attached to a main or “master” structure, is capable of absorbing irreversibly its vibrational or/and acoustic energy produced by a vibrating body. This is possible because a one-way energy flow, from the main structure to the set of resonators, is obtained. This effect holds, with a suitable design of the resonators, even with a mass of the energy sink largely smaller than that of the main structure.
This has the advantage of reducing the global structure weight of main structure and vibration damper, with the advantage that the damping device of the invention can be used in particularly demanding applications like on flying or spatial vehicles.
Moreover, the damping device is able to produce the desired damping effect, even in the absence of any source of energy dissipation by means of a viscous effect. The energy is permanently transferred from the vibrating master structure to the damping device because of its special design.
Thus, a damping device using this principle can be used to effectively damp the motion, either vibration or oscillation, of a large structure, conferring characteristics of lightness of the device itself, that cannot be achieved with traditional damping means.
Different applications of the damping device of the invention are suggested by way of non-limiting examples
Other uses of the invention can be apparent to the person skilled in the art without departing from the scope of the invention.
a shows a curve defining the resonators natural frequencies density of the resonators comprised in embodiments of the damping device of the invention,
b, 23c, 23d show curves defining the natural frequencies distribution of the resonators comprised in embodiments of the damping device of the Invention,
The
The observation of the motion of the master structure 1, shows that it appears damped due to its transfer of energy to the set of resonators 2.
The motion of the resonators is initially phase-coherent causing an energy transfer from the master structure 1 to the set or cluster of resonators 2; subsequently, the motion of the resonators 2 becomes phase-incoherent so that the net force from the cluster to the master becomes almost zero preventing in this way energy from returning back to the master structure 1. However, generally and in the absence of damping, the energy initially absorbed by the cluster of resonators 2 would be transferred back to the master structure 1 after a certain period of time.
By defining appropriately the natural frequencies of the set of resonators 2 comprised
In the damping device of the invention and their distribution along the damping device, two main effects are simultaneously obtained:
i) the energy absorbed by the cluster of resonators is definitely confined within the set of resonators and does not reflect back to the master;
ii) the rate of the energy transfer from the master to the cluster of resonators is maximized, producing a maximum damping effect on the master motion.
These advantages are achieved within the scope of the invention by appropriately defining the mass and/or the natural frequencies of the resonators comprised in the damping device according to the formula that is at the basis of the invention. Hereafter is illustrated the theoretical demonstration of the formula. Let us consider the first point. If the number N of resonators is large, ideally infinite, but with constant total mass, the attached resonators produce a continuous distribution. The equations of the motion of the system are in this case:
where M, KM, xM are the mass, stiffness and displacement of the master structure, respectively; m, k, x the same quantities referred to any single resonator of the attached set. The first equation refers to the master, the second, varying A, to the resonators of the cluster.
From the second of equations (1), the displacement of the continuous set of resonators in terms of the master response can be determined by the convolution integral:
where H is the Heaviside function and ωn(ξ)=√{square root over (k(ξ)/m)}. Substitution of this expression into the first of equation (1) produces:
An Integral-differential equation in terms of xM is determined. More concisely, letting:
the previous equation takes the simpler form:
where
î(t)=I(t)H(t)
is the kernel of the integral part of the previous equation.
Equation (3) implies that the interaction effect between the main structure and the cluster produces, besides a larger static stiffness
This last is produced from an integration of a sinusoidal function with variable frequency. Such an integral is simply evaluated by an asymptotic expansion for t large. It is proved that:
limt→∞Î(t)=0
limt→∞{circumflex over (L)}(t)=0
Looking at the mathematical expression of the kernel, this property has a physical counterpart: for late times the resonator vibrations become phase-incoherent producing on the main structure a net force that vanishes. The kernel has a peak for t=0, initial time at which the resonators are coherent, while, for late times, when the resonators becomes phase-incoherent, it vanishes.
While
and l(t) is replaced by its discrete counterpart
M{umlaut over (x)}
M(t)+(KM+
The properties of the solutions of equations (3) and (4) are different because of the different kernels l(t) and s(t) appear. Thus, while l(t) confers damping-like properties to the master, the same is not obvious for s(t). In order to understand the damping capability in the case of a discrete set of resonators, explore the properties of the general sum:
compared to the properties of the associated integral:
where ξ is a dummy variable. hint(t) has the following asymptotic properties:
If the local property (P2) is extended to any points ξε[0,1] then all the frequency are equal, hint(t) becomes a simple sine function and it is no more decaying. Since h(t) is a discrete approximation of hint(t), their difference is given by the reminder term hint(t)−h(t):
where ξN(t)ε[0,1]. Then:
This expression shows a third interesting property:
P3—The upper bound of the quantity |hint(t)−h(t)| is proportional to
with ξε[0,1].
Properties P1, P2 and P3 suggest those frequency distributions leading to a nearly-vanishing h(t), i.e. to the phenomenon of near-irreversibility. In fact, properties P1 and P2 show that hint(t) vanishes for any non-uniformly flat frequency distributions or for distributions presenting one or more stationary points ξ0. Property P3 provides a criterion to make h(t) closer to hint(t):
must be small within the interval ξε[0,1]. It appears that those distributions of natural frequencies presenting stationary points (one or more) within the interval ξε[0,1] are the candidates to produce a nearly-vanishing impulse response h(t). In fact, in this case hint(t) vanishes for large times and, in addition, since around any stationary point the function
is reasonably small, the value
is also small. This implies that |hint(t)−h(t)| is small: thus, h(t) exhibits asymptotic properties close to those of hint(t), i.e. a decaying trend in the time history of h(t) is expected. Note, that the ratio
is proportional to the modal density δ(ω) of the structure. In fact
being N the total number of modes for ξε[0,1], and dn the number of modes for ξε[ξ, ξ+dξ].
Therefore,
If the natural frequency distribution exhibits one or more stationary points ξ0, they correspond to singularity points to ω0=ω(ξ0) in the structural modal density. Thus, if:
a decaying trend in the impulse response of the structure is expected, even in the absence of any other dissipation effect produced by vibration damping material or by a damping device of the known art.
This means that the effect of damping observed in the motion of the principal structure, is completely independent of any energy dissipation effect, based on viscous properties of fluids or of bodies, on which are generally based traditional vibration dampers.
The previous theoretical analysis leads to introduce in the natural frequency distribution within the cluster, points for which
or, generally, points for which this quantity is small. These points are called frequency accumulation points.
The best frequency distributions that allow to produce pseudo-damping are determined on the basis of mathematical considerations. More precisely their form is determined by solving the following differential equation: (equation 5) where:
m is the total mass of the cluster of resonators,
r is the bandwidth parameter, with r<mωM
l is the tuning parameter, with l<mωM3 and
ω(ξ) is the desired frequency distribution within the cluster.
Assigned r, m, l following the criteria shown ahead, the frequency distribution is determined by solving numerically the above differential equation.
However, since
is the density δ(ω) of the resonators within the cluster, i.e. it counts the number of resonators contained within the frequency band dω, the previous equation produces directly an expression for δ(ω). In fact,
being N the total number of harmonics for ξε[0,1], and dn the number of harmonics for ξε[ξ, ξ+dξ]. Therefore,
the previous equation produces:
A practical use of the previous equations is now presented. It is perfectly equivalent to use equations 5 or 6 to select the natural frequency of the resonators of the device, although they lead to different procedures illustrated ahead. The use of the following nondimensional form is more convenient for purposes of design of a damping device according to the invention:
where the nondimensional frequency Ω=ω/ωM is considered, and ωM is the natural frequency of the master to which the cluster is applied. Analogously for the modal density:
The parameter
is assigned, while the parameters can be varied depending on the considered application. The table below shows typical
values for
Higher values of
produce in general better performances of the damping device, provided that the fabrication technology of the resonators is sufficiently accurate to make resonators showing differences in their natural frequencies when placed consecutively in the damping device of the invention. The differences in the natural frequencies of resonators placed near to each other must be in the order of 1/δ(Ω) for Ω=1.
The curves m, n, o, p, q, r shown in the
Two procedures to determine the physical characteristic of the resonators of the cluster, namely their individual mass and stiffness, are presented to show practical uses of the optimal curves for making damping devices according to the invention. The first is based on the frequency distribution curve, the second is based on the resonator density curve. They are conceptually identical although involve a different technique of representation of the characteristics of a damping device of the invention.
The first procedure based on the frequency-distribution-curve starts with the choice of the parameters for example looking at the values of the table. For purpose of illustration consider the Case 5 for which the values are
Numerical integration of equation (1) produces the curve in the picture below. Once the number N of the resonators is selected, on the y-axis the frequency associated to any of the resonators in the cluster is determined. For example, given N=100, and known the master natural frequency ωM, the resonator number 20 is found on the x-axis at the abscissa 20/N=0,2. The corresponding frequency value Ω is 0.97 to which corresponds the physical value of the natural frequency ω=ΩωM=0.97 ωM.
The second procedure based on the resonators density curve starts with the choice of the parameters
for example looking at the values of Table 1. For purpose of illustration consider the Case 5 of table 1 for which we have the value
The following curve
is plotted as in the
The area under the curve is equal to 1. On the x-axis is represented the nondimensional frequency Ω while on the y-axis is the function
where the number N is predetermined following some considerations according to which a higher N produces in general better performances of the damping device but costs and technical production problems are increased. The curve gives the number of resonators which must have frequencies within a given frequency band.
The following procedure leads to determine the natural frequencies of the resonators within the damping device:
a) The x-axis is subdivided into small frequency intervals and for each of them a small trapezium AiBiCiDi in
b) The area of AiBiCiDi is multiplied by the number N of resonators and the resulting number NiAB represents the number of the resonators of the device that must have natural frequency within the frequency interval AiBi.
c) The individual frequencies of the resonators belonging to the frequency interval AiBi are determined by the relationship:
The steps a), b), c) are used for each of the frequency intervals of the x-axis.
Once all the natural frequencies of the resonators ωt of the device are determined by the illustrated procedure, their physical parameters can be determined.
The physical parameters to be determined depend on the realization of the resonators. If they are masses on elastic springs, the associated mass mi and the stiffness ki, can be determined. For example, one can select the value for mi equal to μ such that the total mass of the resonators is Nμ. This could be an appropriate small fraction f of the mass M of the master structure, for example f=0,1. Thus,
The individual stiffness of the resonators follows as ki=μωi2
In the embodiment where the damping device comprise resonators consisting of beams, i.e. clamped-free beams, once the characteristic section of the beams is assigned by the width b and the thickness h, for example the same for all the resonators, providing the cross section area A, the material mass density ρ, the Young modulus E, and the cross section moment of inertia Y, then the length Li of each beam is determined on the basis of the calculated natural frequencies ωi. In fact:
For example, if the device is to be applied to a vibrating panel with one of its natural frequency at ωM=2π150 rad/s with the following choice: E=2.1·1011 N/m2, p=7800 kg/m3, b=0.002 m, h=0.002 m the previous formula, with the parameters of Case 5 presented in the table, provides the distribution of the beam lengths within the cluster shown in
On the y-axis the length of the beam of the cluster (meter), on the x-axis the ξ=variable. The practical use of this graph is the following. Selected the number N of the resonators to be used within the damping device, for example N=100, all the lengths of the 100 beams of the cluster can be determined. For example the resonator number 20 is found on the x-axis at the abscissa 20/N=0.2. The corresponding length is L20=0.1077 m.
By means of the definition of the characteristics of the resonators along the general formula indicated above, the damping device achieves thus the following advantages:
i) a suitable distribution of natural frequencies within the damping device can be selected in order to optimize the process of energy absorption by the cluster of resonators. More precisely, even in absence of any viscous damping mechanism connected to the vibrating body such optimized distribution retains the energy within the damping device without releasing it back to the principal structure;
ii) the damping device can include, purposely, Impact effects in order to optimize the energy sharing among the resonators of the set, enhancing the energy absorption properties of a sink unit;
iii) It is possible to apply the damping device of a continuous structure, e.g. a panel, or a wall, to damp its motion, which is not possible by means of dampers of the known art, or at least is not as efficient. In this embodiment, a whole cluster of resonators is attached to a single point of a vibrating structure, to maximise the damping effect.
A single damping device according to the invention comprising resonators 2′ In the shape of beams is shown in
Different embodiments of damping devices comprising resonators distributed according to the procedure described which fall within the scope of the invention. All these damping devices use a resonators density curve that lies below the envelope curve described by the equation,
as plotted in the
Some embodiments of the damping device of the invention and some examples of specific applications to damp vibrations, oscillation or movements of structures are hereinafter illustrated.
In a first alternative embodiment of the device according to the invention the cluster of resonators 50 with the appropriate natural frequency distribution, determined using the formula set forth above, can be made by means of an electromechanical circuit.
In an alternative embodiment of the damping device according to the invention, the cluster of resonators according to the invention having the frequency distribution given by the formula set forth above, can be made also by means of acoustic ducts 60 connected to a room 61.
With reference to
In this application, a systematic distribution of a plurality of damping devices having micro-dimensions, like mini-beams with size of order 10−2 m or smaller, along a structure is provided. The number of damping devices depends on the size of the structure. An example of such an application is shown in
Since the characteristic size of the damping device is very small compared to the dimensions of the structure, it can be considered part of the microstructure of the material. The resulting system, due to its special micro-structure, has the capability of converting its macro-scale oscillations into micro-scale vibrations of its micro-structure, replicating, at an extreme large number of points, the effect shown by the curves of
The impulse response of a structure with and without the damping device is compared in
Vibrating Surface with a Damping Device
The device can incorporate also means for adjusting frequencies. An adjustment mechanism, is shown in
The adjustment mechanism is a linear clamp that moves in and out to change the lengths of the mounted resonators, thus changing their frequencies to the desired values. These values can be indicated by means of marks on the external cover of the damping device.
The adjustment mechanism has a locking screw 10, a tuning screw 11, a support 12 to fixthe housing 13 of the device to the master structure to damp.
The damping device can also be applied to a rotating shaft 20 with a system of radially mounted beams 2′″ fixed to a central support 22 as sketched in
The damping system shown as an example in
The two set of resonators cooperate to absorb the master's energy as in the other applications and is explained in the theoretical background above. The master structure corresponds to the floating vessel 70, oscillating under the influence of the waves, that transfers its energy to the two groups of resonators 71 and 72 at a rate controlled by the natural frequency distribution within the set of resonators.
In this application, a device as that just described where the energy of exciting waves is transferred from the floating vessel 80 to the sets 83 and 84 of resonators is recovered in terms of a compressed gas filling a tank.
There are provided two sets 83, 84 of resonators, each comprising a plurality of resonators, and all oronly part of the resonators can have a floating mass 81, 82, which is supported by an elastic element 85, 86 The floating masses 81, 82 in their motion act as a piston in a respective pump chamber 87, 88. Through an appropriate circuit comprising automatic valves, air is compressed from the atmospheric pressure to the air tank 89 in which the air stored under pressure.
Number | Date | Country | Kind |
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RM2005A000150 | Mar 2005 | IT | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/061250 | 3/31/2006 | WO | 00 | 9/26/2007 |