JPH029480B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a heterogeneous wave reflection prevention material that is used by being attached to the surface of an object that reflects radio waves in the air and sound waves in water.

[Prior art]

As a medium for wireless communication, radio waves are used in the air, and sound waves are used in water. However, these media have drawbacks such as diffuse reflection when there are obstacles such as offshore structures or ships near the communication path, which can cause ghosts and noise on the receiver and interfere with communication. .

For this reason, conventional practice has generally been to attach radio wave absorbing materials to the parts of such obstacles that are exposed in the air, and to attach sound absorbing materials to the parts submerged in water.

However, if this obstacle has a part that is submerged in the sea or exposed in the air, that part needs to have the function of both sound absorption and radio wave absorption in the different media of water and air. , Such a material capable of absorbing radio waves and sound has not been proposed to date because the frequencies of sound waves and radio waves are significantly different.

[Purpose of the invention]

The present invention provides objects that reflect radio waves and sound waves (e.g., iron, wood, FRP, concrete, stone, etc.) that can act as a radio wave absorbing material in the air and as a sound absorbing material in water. The object of the present invention is to provide a material for preventing the reflection of waves in different media, which is used by being attached to the surface of a material.

[Structure of the invention]

Therefore, in the present invention, an outer layer and an inner layer made of a rubber compound or a synthetic resin compound are integrally laminated, the outer layer contains conductive carbon, and the inner layer has a mesh of 20 to 500 meshes. The gist of the present invention is a heterogeneous wave reflection preventing material characterized by containing a filler having a particle size.

Hereinafter, the configuration of the present invention will be explained in detail with reference to the drawings.

FIG. 1 is an explanatory cross-sectional view of an example of the different-medium wave reflection preventing material of the present invention. In this figure, a different medium wave reflection preventing material 1 is formed by integrally laminating an outer layer 2 made of a rubber compound or a synthetic resin compound and an inner layer 3 made of a rubber compound or a synthetic resin compound. In order to laminate the outer layer 2 and the inner layer 3, they may be attached to each other using a suitable adhesive. outer layer 2
may have a single layer or multiple layers. In addition, the inner layer 3 is
Here, it is composed of four layers: the top layer 3a, the first intermediate layer 3b, the second intermediate layer 3c, and the bottom layer 3d, but it is sufficient as long as it has at least one layer.

When using this different medium wave reflection preventing material 1, for example, an adhesive may be applied to the lower surface of the bottom layer 3d and the applied surface may be attached to the surface of the reflective object 4. Further, after pasting the bottom layer 3d on the surface of the reflective object 4, the second intermediate layer 3c, the first intermediate layer 3b,
The top layer 3a and the outer layer 2 may be sequentially laminated.

(1) The outer layer 2 functions as a transmissive layer that takes in sound waves without reflecting them, and an absorption layer that absorbs radio waves without reflecting them. In order to prevent sound waves from being reflected, the specific acoustic impedance of water (in the case of seawater, impedance (ρc) = 1.5 × 10 ⁵ g/cm ²
It is necessary to have a specific acoustic impedance close to s). For this reason, the outer layer 2 is made of a rubber compound or synthetic resin compound in which a vulcanizing agent or the like is added to the rubber or synthetic resin compound.
It was constructed to take a value of 10 ⁵ g/cm ² s, which is very close to that of seawater (for reference,
For air: ρc = 40g/cm ²・s, for steel:
ρc=4.6×10 ⁶ g/cm ²・s). The value of ρc can be obtained by appropriately selecting the components and amounts of the rubber compound or synthetic resin compound.

Examples of the rubber used here include chloroprene rubber (CR) and nitrile rubber (NBR). Among these rubbers, CR is preferably used in consideration of processability and adhesiveness.

Further, the synthetic resin is, for example, a thermoplastic resin such as vinyl chloride resin or polyethylene, or a thermosetting resin such as phenol resin, epoxy resin, melamine resin, or polyester resin.

The outer layer 2 further contains conductive carbon. This is to improve radio wave absorption ability.
Examples of conductive carbon include acetylene black, which is a high structure carbon black,
It is a powder such as Furness Black. In the case of acetylene carbon, the amount of conductive carbon contained is 30 to 60 parts by weight per 100 parts by weight of rubber or synthetic resin. This is because if it is less than 30 parts by weight, the mixture will have no electrical conductivity, while if it exceeds 60 parts by weight, the effect of the mixture will hardly change and processing will become difficult.

The thickness of this outer layer 2 is approximately 1 to 20 mm.

(2) The inner layer 3 has a function as a sound absorbing layer that absorbs sound waves. For this reason, it is made of a rubber compound or a synthetic resin compound and has a relatively large amount of filler inside. That is, sound absorption is achieved by converting and consuming sound wave energy into shear deformation in the vicinity of the filler. This is because medium particles on the same wavefront have different vibration speeds.
This is because the relative velocity between adjacent particles of different materials causes shear deformation and consumes vibration energy. Here, although the specific gravity of the filler is not specified, it is preferable that the specific gravity is 2.0 or more.

This filler is shown as powder 5 in FIGS. 1 and 2. The powder 5 is metal powder or inorganic powder with a particle size of 20 to 500 mesh. Examples of the metal powder include ferrite powder, aluminum powder, zinc powder, and copper oxide powder. In addition, examples of the inorganic powder include calcium carbonate powder and mica powder.

The inner layer 3 contains at least one kind of these metal powders or inorganic powders. The content thereof is not particularly limited, but may be at least 5 parts by weight per 100 parts by weight of rubber or synthetic resin.

Note that although most of the radio waves are absorbed by the outer layer 2, the radio waves that are partially transmitted enter the layer 3. Therefore, when using metal powder, the amount should be 300~
It is preferable to increase the amount to about 400 parts by weight, which causes dimagnetic absorption of radio waves. That is, the inner layer 3 can completely absorb the radio waves that have passed through the inner layer 3 to some extent. In this case, if the amount is less than 300 parts by weight, the radio wave absorption performance of the compound will be lost, while if it exceeds 400 parts by weight, the processability of the compound will deteriorate.

The thickness of this inner layer 3 is approximately 1 to 100 mm.
FIG. 3 shows an example of the heterogeneous wave reflection prevention material of the present invention, which has an outer layer 2 made of rubber or a synthetic resin compound and an inner layer 3 made of a rubber or synthetic resin compound, as detailed in FIG. 1. It is integrally layered. Both the outer layer and the inner layer are composed of one layer each, and the outer layer 2 functions as a transmission layer that takes in sound waves without reflecting them, and an absorption layer that absorbs radio waves without reflecting them. The inner layer 3 is a sound wave absorbing layer, is made of a rubber compound or a synthetic resin compound, contains the powder 5 described above, and absorbs sound energy. At this time, as described in Example 1 and described above, when the amount of mixed metal powder is increased, dimagnetic absorption occurs with respect to the incident electric current, and the radio wave absorption property is improved. Furthermore, the particle size of the metal powder is
100 to 500 mesh is preferable for sound absorption effect.

When the outer layer 2 and the inner layer 3 are used reversed, for example, when the outer layer 2 is on the inside and the inner layer 3 is on the outside in FIG. Although there is no problem, since conductive carbon having a radio wave absorption function is not mixed in the inner layer 3, the inner layer 3 does not function as a matching layer, and radio wave absorption performance cannot be expected.
In the structure in which the outer layer 2 and the inner layer 3 are interchanged as described above, there arise problems such as an inability to exhibit sufficient radio wave absorption performance. Therefore, in the present invention, as shown in FIGS. 1 and 3, the outer layer 2
must be placed on the outside and the inner layer 3 on the inside.

Examples are shown below.

Example 1 A sheet with a thickness of 10 mm was made using the following composition A using a normal rubber product processing method, and this sheet was
The outer layer 2 was prepared by vulcanization by hot pressing at 160° C. for 30 minutes.

Blend A Chloroprene rubber 100 parts by weight Acetylene carbon 40 parts by weight Process oil 10 parts by weight Anti-aging agent 1.5 parts by weight Lubricant 2 parts by weight Acid acceptor 4 parts by weight Vulcanizing agent 5 parts by weight Vulcanization accelerator 0.5 parts by weight In addition, the following Inner layer 3 was prepared by hot press molding at 160° C. for 30 minutes using the formulation B.

The press used is controlled so that the product thickness is 8 mm.

Blend B Chloroprene rubber 100 parts by weight Furnace carbon 30 parts by weight Ferrite powder (200 mesh) 310 parts by weight Plasticizer 15 parts by weight Anti-aging agent 2 parts by weight Vulcanizing agent 4 parts by weight The above outer layer 2 and inner layer 3 are adhesive It was attached to the surface of the reflective object 4 via an agent. In this case, first,
4 plies of inner layer sheet on reflective object 4 (total 32mm)
Thickness) were applied one after another, and then one ply (10 mm thick) of the outer layer sheet was applied. This allows radio wave absorption and
A sound absorbing material (total thickness of 42 mm) was obtained.

The radio wave/sound wave absorption performance of this product was as follows.

The measurement was performed by irradiating this product with waves of a certain frequency (radio waves or sound waves) at a constant intensity, and calculating the return loss (dB) from the strength of the waves reflected from the product. As a result of measurement, sound wave reflection loss in water: 10 dB or more at frequencies 10 to 300 KHz,
Radio wave return loss in the air: Frequency 8 to 12 GHz
showed an effect of more than 10dB.

Example 2 Outer layer 2 was prepared by the compounding method described in Example 1. However, the sheet thickness was 2 mm. Inner layer 3 was prepared into a 2 mm thick sheet by heating and pressing in a mold at 160°C for 30 minutes using the following formulation.

Blend C Chloroprene rubber 100 parts by weight Furnace carbon 30 parts by weight Mica powder (100 mesh) 10 parts by weight Plasticizer 15 parts by weight Anti-aging agent 2 parts by weight Vulcanizing agent 4 parts by weight The resulting sheet outer layer 2 mm thick, inner layer 2 mm thick Thin layered radio wave/sound wave absorbers having a total thickness of 4 mm were obtained by sequentially pasting the layers onto the surface of the reflective object 4.

The absorption performance of this product was as follows.

Sound wave reflection loss in water: Frequency 50~
It showed an effect of more than 10 dB at 300 KHz, and an effect of more than 10 dB in the radio wave reflection loss in the air: frequencies of 8 to 12 GHz.

Example 3 The same method as in Example 1 was carried out except that the formulation B was replaced with the following formulation.

Formulation D Chloroprene rubber 100 parts by weight Furness Carbon 40 parts by weight Plasticizer 16 parts by weight Anti-aging agent 3 parts by weight Vulcanizing agent 5 parts by weight The absorption performance of this product was as follows.

Sound wave reflection loss in water: Frequency 10~
It showed an effect of more than 10 dB at 100 KHz, and an effect of more than 10 dB in the radio wave reflection loss in the air: frequencies of 8 to 12 GHz.

〔Effect of the invention〕

As explained above, according to the present invention, since the different medium wave reflection prevention material is constructed from the outer layer 2 and the inner layer 3 as described above, this prevention material has both radio wave absorption and sound wave absorption performance at the same time. Can be done.
Therefore, if this preventive material is attached to the surface of a structure such as a submersible that floats on the ocean or sinks in water, the surface of the structure will be damaged when the structure is exposed in the air. Since it is possible to eliminate the reflection of radio waves and the reflection of sound waves when submerged in water, it is possible to sufficiently prevent communications from being interfered with by such structures.

[Brief explanation of drawings]

FIG. 1 is an explanatory cross-sectional view of an example of the different-medium wave reflection prevention material of the present invention, and FIG. 2 is an explanatory cross-sectional view taken along the line A--A. FIG. 3 shows another cross-sectional view of the different medium wave reflection preventing material of the present invention. 1...Different medium wave reflection prevention material, 2...Outer layer, 3
...Inner layer, 4...Reflective object, 5...Powder.

Claims (1)

[Claims] 1 An outer layer and an inner layer made of a rubber compound or a synthetic resin compound are integrally laminated, the outer layer contains conductive carbon, and the inner layer has a particle size
A heterogeneous wave reflection preventing material characterized by containing at least one kind of metal powder or inorganic powder of 20 to 500 meshes.