JPH05240298A - Damping material - Google Patents

Abstract

PURPOSE:To maximize the damping effect by establishing the impedance matching condition to be expressed by the specified formula with the composition of at least one kind of a substance selected among the group of the conductive substances and the semi-conductive substances, and a piezoelectric ceramics and a polymer. CONSTITUTION:A piezoelectric ceramics has a property of the piezoelectric constant of 100-thousandsX10<12>m/V, and for example, 3 or 4 components which are basically composed of barium titanate, lead zirconate titanate or the like, and fine particles of carbon black, acetylene black or the like can be used for the conductive substance, while the covalent substance of Si or the like or the metallic oxide of Cu2O, ZnO or the like can be used for the semi- conductive substance, and the phenol resin, the epoxy resin or the like can be used for the polymer. The impedance matching conditions is established to be expressed by the formula R=1/omegaC (where, R: resistance, omega: frequency of piezoelectric ceramics, C: capacitance of piezoelectric ceramics). This constitution allows the damping control effect to be improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vibration damping material. More specifically, the present invention is useful in a wide range of fields such as electricity, machinery, chemistry, civil engineering and transportation,
It relates to an extremely high-performance damping material.

[0002]

2. Description of the Related Art Conventionally, as a method for effectively damping vibrations, a vibration-damping steel plate having a viscoelastic layer sandwiched between materials, a vibration-absorbing alloy, and the like have been known, and have already been put into practical use. However, in the case of this conventional material,
Although vibration damping effect can be obtained to some extent, vibration-absorbing steel plates have problems in terms of delamination from the steel plate and workability.In the case of vibration-absorbing alloys, heat treatment costs are high and damping performance deteriorates due to processing. There was a problem such as.

As a solution to these drawbacks, a vibration damping material using piezoelectric ceramics has been proposed.
For example, an energy conversion composition comprising at least one substance selected from a conductive substance or a semiconductive substance, a piezoelectric ceramics and a polymer, wherein mechanical vibration energy applied to the composition is converted into electric energy. A vibration damping material characterized by being converted and further converted into heat energy to be dissipated is already known, and has been newly proposed by the inventor of the present invention.

Since the vibration damping material using this piezoelectric ceramic can be compounded with a polymer, it is characterized by good moldability and workability, and is lightweight. Is what is attracting attention. However, in spite of such excellent characteristics, regarding the damping material as the composite material of the ceramic and polymer, how to utilize the non-uniformity of the composition for improving the damping effect, The improvement of damping effect is
Almost no consideration has been given to what can be used as an index. For this reason, despite the above-mentioned expectations, the recent technological development has been sluggish.

The present invention has been made in view of the above circumstances, and is a new index which can maximize the damping effect while making the most of the characteristics of the conventional piezoelectric ceramic damping material. It is an object of the present invention to provide a vibration damping material of a piezoelectric ceramic composite type, which enables material development in line with it.

[0006]

In order to solve the above problems, the present invention provides at least one substance selected from the group of conductive substances and semiconductive substances, a piezoelectric ceramics and a polymer. Which is characterized by satisfying an impedance matching condition represented by the following formula: R = 1 / ωC (R: resistance, ω: frequency of piezoelectric ceramics C: capacitance of piezoelectric ceramics) To provide damping material.

The piezoelectric ceramics preferably used in the present invention have a piezoelectric constant of 100 to several thousands × 10 ^-12 m.
/ V, for example, barium titanate (BT), lead zirconate titanate (PZ).
T), lead lanthanum zirconate titanate system (PLZ
T), a lead-titanate (PT) -lead zirconate (PZ) -based three-component system or a four-component system is preferably used. Nb, as a three-component or four-component element
Mg, Ni, Zn, Mn, Co, Sn, Fe, Cd, S
b, Al, Yb, In, Sn, Y, Ta, Bi, W, T
l, Re, etc. are used. The average particle diameter of the piezoelectric ceramic particles is preferably about 3 to 50 μm, and the piezoelectric ceramic particles have a volume fraction of 40 to 8 in the composite.
It is preferable to add about 0 vol%. Volume fraction is 80 vo
If it exceeds 1%, the composite material may become too hard, and the workability may deteriorate, which is not preferable. When the volume fraction is 40 vol% or less, the efficiency of conversion of vibration energy into electric energy becomes low, which may not be preferable. Although the kind of the conductive substance is not limited, for example, conductive carbon black fine particles such as carbon black and acetylene black, metal and oxide fine powder such as Fe and Ni, and TiO.
₂ Oxide particle surface coated with conductive material Sn, Sb, etc. to give conductivity, or fine powder, or TiO, Ti ₂
Fine powders of O ₃ and TiO _2-x (0 <x <0.05) can be used. The kind of the semiconductive substance is not particularly limited, but for example, a covalent bond substance such as Si, or C
Metal oxides such as u ₂ O and ZnO can be used. It is preferable to add the above conductive substance and semiconductive substance so that the internal resistivity of the composite is in the range of 10 ⁵ to 10 ⁹ Ω · cm, and more preferably 10 ⁶ to 10 ⁸ Ω · cm. Add as shown. The average particle size of conductive materials and semi-conductive materials is 1/10 of the average particle size of piezoelectric ceramic particles.
Ultrafine powder having a particle size of about 0, that is, 0.5 μm or less is preferable, and ultrafine particles of 0.05 μm or less is more preferable. Of course, these rules are not limiting.
Examples of the polymer material include thermosetting resins such as phenol resin and epoxy resin, polyethylene, polypropylene, styrene resin, polyvinyl chloride, polyvinylidene fluoride, polytetrafluoroethylene, thermoplastic general-purpose plastics such as polyurethane, and polyamide. Engineer plastics such as polyester, polyether, special engineering plastics and various polymer alloys can be used. Further, natural rubber or synthetic rubber such as silicone rubber can be used. By using a polymer material, attenuation by the material itself can be expected. In particular, when polyvinylidene fluoride (PVDF), which is a piezoelectric polymer having a high dielectric constant, is used, the piezoelectric effect (piezoelectric constant) of the entire composite compound can be enhanced by performing the polarization treatment at high temperature. Therefore, the efficiency of converting mechanical energy into electrical energy is increased, and the energy conversion effect is increased. The optimum resistance value must be selected to obtain the highest conversion efficiency, but conversely the energy conversion efficiency can be adjusted by changing the resistance value.

Further, in the present invention, a semiconductor ceramic is also used based on the principle of the previous term. A small amount of additive elements such as La, Ce, Sm, Dy, Y, Ta, Nb, Nd, B in the piezoelectric ceramics having the characteristics of the previous period
A method for converting the piezoelectric ceramic itself into a semiconductor by adding i, Cu, etc.
Semiconductor ceramics can be obtained by a method of converting the surface of a particle into a semiconductor by a reduction treatment in a _two- gas atmosphere, or a method of using both of them together. In principle, it is possible to provide a damping effect with only semiconductor ceramics. Further, this semiconductor ceramic powder may be compounded with a polymer material. The compounding ratio of the semiconductor ceramics is preferably such that the internal resistivity of the compound is in the range of 10 ⁵ to 10 ⁹ Ω · cm, and more preferably 10 ⁶ to 10.
Add as shown to be 10 ⁸ Ω · cm.

The energy conversion efficiency can be changed by changing the composition ratio of the conductive material and the semiconductor material in the composition and the kind and amount of the rare earth element added to the ceramics. In the composition of the present invention having such a constitution, as a composite of at least one substance selected from the group of the above-mentioned conductive substance and semi-conductive substance, piezoelectric ceramics and polymer, the following formula R = The impedance matching condition represented by 1 / ωC (R: resistance, ω: frequency of piezoelectric ceramics C: capacitance of piezoelectric ceramics) is satisfied.

This condition is derived from the production of numerous composite materials and the evaluation of their vibration damping effect. That is,
Assuming that energy is dissipated through the resistor R, when R = 1 / ωC where the above impedance matching is established,
The damping efficiency is maximum. At this time, the time (τ) at which the amplitude becomes 1 / e when the peak of the attenuation curve is approximated by an exponential function becomes the minimum.

In order to further enhance the vibration control effect, the present invention also has a preferred embodiment in which a piezoelectric ceramic having a large electromechanical coupling coefficient is blended. The above is realized as an integrated composite material as a vibration damping material, but here, integration means a state in which mechanical energy applied to an object can be substantially converted into thermal energy. The means for integration are not particularly limited. Specific integration methods include, for example, bonding and spraying,
A suitable gap may be filled, or a so-called sandwich structure may be used in which the composition of the present invention is formed into a sheet and then sandwiched between the vibrators.

The piezoelectric ceramic particles contained in the composition integrated with the vibrating body can convert the vibration energy into electric energy and further dissipate the electric energy as heat energy to rapidly damp the vibration.
In this case, when the polymer material is used as a matrix of the composite, it has a role of increasing the mechanical softness of the composite, facilitating the forming process, and making it possible to form a sheet having a large area. Further, it can be molded into a shape suitable for mounting on a target vibrating object.

Further, by changing the composition ratio of the conductive material and the semiconductive material in the composition and the composition ratio of the rare earth element or the like added to the piezoelectric ceramics, the damping rate of vibration can be adjusted. It is also possible to selectively damp frequency oscillations. That is, by changing the above composition ratio, a composition having a desired attenuation rate in a desired frequency band can be obtained so as to meet the above impedance matching conditions. In this case, it is also effective to give a gradient to the composition distribution.

The vibration damping material of the present invention as described above is suitably used as various soundproofing members. For example, a soundproof effect can be obtained by integrating the composition according to the present invention with a box for housing a window for a house, an electric motor, or a device generating noise. As described above, the sheet-shaped composition of the present invention may be adhered to these materials, or the melted composition may be sprayed. Further, it may be filled in a gap such as a window frame.

The present invention will be described in more detail with reference to the following examples.

[0016]

[Examples] Piezoelectric ceramics PZT was used as the piezoelectric particles.
(Fuji titanium industry PE60A), carbon black (CB: TOKAI SEAST 30 as conductive particles
0) was used. Unify the volume fraction of piezoelectric particles to 50%,
Change the conductivity by changing the filling amount of CB,
The correspondence with the damping efficiency was evaluated. Further, the effect on the damping efficiency was evaluated by changing the ceramics to PLZT (7/65/35) having a large electromechanical coupling coefficient. PVDF was used as the polymer matrix. The above raw materials were kneaded (190 ° C.) with a mixing roller and press-molded (210 ° C., 21 minutes) to give a film having a thickness of 0.5 mm. The sample is made into a cantilever shape of 40 mm x 15 mm, vibration is given from a vibration exciter, the residual vibration is read by a non-contact displacement sensor, and the peak of the obtained damping curve is approximated by an exponential function, and the amplitude becomes 1 / e Then, the time (τ) was calculated. The damping efficiency of the composite material was evaluated by the value of τ.

PZT / CB / PVDF system, and PLZT
FIG. 1 shows the change of τ with respect to the CB volume fraction in the / CB / PVDF system. In each system, τ is C
It changed to take the minimum value in the vicinity of the B fraction of 6.5%. Further, FIG. 2 shows changes in the conductivity of the sample with respect to the CB volume fraction. The piezoelectric body generates an alternating voltage due to vibration, and when the frequency is ω and the electrostatic capacitance is C, the impedance of the piezoelectric body is 1 / ωC, and if the energy is dissipated through the resistor R, impedance matching will occur. When R = 1 / ωC holds, the vibration damping efficiency becomes maximum.
At this time, τ becomes the minimum. At the minimum value of r in each system,
It is considered that such impedance matching conditions are satisfied. Further, as is clear from the results of FIG. 1, it was found that a system filled with PLZT particles having a large electromechanical coupling coefficient can obtain a greater damping effect.

[0018]

According to the present invention, there is provided a new piezoelectric ceramic-polymer composite damping material capable of exhibiting a greater damping effect.

[Brief description of drawings]

FIG. 1 is a correlation diagram of carbon black content and τ value as an example.

FIG. 2 is a correlation diagram of carbon black content and conductivity as an example.

Claims (3)

[Claims] 1. A composition comprising at least one substance selected from the group of conductive substances and semi-conductive substances, and piezoelectric ceramics and polymers, wherein R = 1 / ωC (R: resistance) , Ω: frequency of piezoelectric ceramics C: capacitance of piezoelectric ceramics), which is a damping material characterized by satisfying an impedance matching condition. 2. The vibration damping material according to claim 1, which is formed by blending piezoelectric ceramics having a large electromechanical coupling coefficient. 3. The vibration damping material according to claim 1, wherein the composition distribution is graded.