JPH0722352B2 - Video tape recorder with integrated camera - Google Patents
Video tape recorder with integrated cameraInfo
- Publication number
- JPH0722352B2 JPH0722352B2 JP1208424A JP20842489A JPH0722352B2 JP H0722352 B2 JPH0722352 B2 JP H0722352B2 JP 1208424 A JP1208424 A JP 1208424A JP 20842489 A JP20842489 A JP 20842489A JP H0722352 B2 JPH0722352 B2 JP H0722352B2
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- Prior art keywords
- layer
- porous
- sound
- thickness
- specific gravity
- Prior art date
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- Soundproofing, Sound Blocking, And Sound Damping (AREA)
Description
【発明の詳細な説明】 [産業上の利用分野] この発明はカメラ一体型ビデオテープレコーダ(以下、
VTRと略す)、特にその筺体の構造に関するものであ
る。DETAILED DESCRIPTION OF THE INVENTION [Industrial application] The present invention relates to a video tape recorder (hereinafter
(Abbreviated as VTR), especially the structure of the housing.
[従来の技術] 第19図は従来のカメラ一体型VTRの分解図であり、第20
図は、その機構部の動作を示す詳細図である。第19図に
おいて(1)はカメラ一体型VTRを(イ)、(ウ)、
(エ)、(オ)方向より覆う意匠構造体である。(6)
はカメラ一体型VTRを機能させるための回路部である。[Prior Art] FIG. 19 is an exploded view of a conventional camera-integrated VTR.
The figure is a detailed view showing the operation of the mechanical section. In FIG. 19, (1) is a camera-integrated VTR (a), (c),
(D) and (e) It is a design structure covered from a direction. (6)
Is a circuit for operating the camera-integrated VTR.
(7)は磁気テープをカセットケースから引き出し、引
き出した磁気テープに信号を記録または磁気テープから
の信号を再生するためのメカ部である。(7) is a mechanical unit for pulling out the magnetic tape from the cassette case and recording a signal on the magnetic tape that is pulled out or reproducing a signal from the magnetic tape.
(8)は、回路部への静電気障害を防ぐ導電性のシール
ドプレート、(9)はシールドプレート(8)と回路部
(6)の接触を防ぐために矢印(ア)方向にシールドプ
レートを覆うように取り付ける非導電性の絶縁シート、
(10)は音声を収音するためのマイクである。(8) is a conductive shield plate that prevents electrostatic damage to the circuit portion, and (9) covers the shield plate in the direction of arrow (a) to prevent contact between the shield plate (8) and the circuit portion (6). Non-conductive insulating sheet to be attached to
(10) is a microphone for collecting voice.
(11)はドラム、(12)は磁気テープ、(13)はカセッ
トケース、(11a)はドラム(11)に取り付けられたヘ
ッドである。(11) is a drum, (12) is a magnetic tape, (13) is a cassette case, and (11a) is a head attached to the drum (11).
次に動作について説明する。Next, the operation will be described.
第20図は、機構部の動作を示しており、磁気テープ(1
2)がカセットケース(13)より引き出されてドラム(1
1)に巻き付く。FIG. 20 shows the operation of the mechanical section, and the magnetic tape (1
2) is pulled out from the cassette case (13) and the drum (1
Wrap around 1).
ドラム(11)は矢印(カ)方向に回転し、また磁気テー
プは矢印(キ)方向に走行する。The drum (11) rotates in the arrow (F) direction, and the magnetic tape runs in the arrow (K) direction.
そして、ヘッド(11a)は磁気テープ(12)に信号を記
録または磁気テープ(12)からの信号を再生する。Then, the head (11a) records a signal on the magnetic tape (12) or reproduces a signal from the magnetic tape (12).
[発明が解決しようとする課題] 従来のカメラ一体型VTRは以上のように構成されている
ので、ドラム(11)に取り付けたヘッド(11a)が磁気
テープ(12)に進入または離脱するときに発生する騒音
は通常の射出成形のプラスチック製の筺体で覆っただけ
では低騒音のカメラ一体型VTRが得られにくく、マイク
(10)にその騒音が集音されてしまうという課題があっ
た。[Problems to be Solved by the Invention] Since the conventional camera-integrated VTR is configured as described above, when the head (11a) attached to the drum (11) enters or leaves the magnetic tape (12). There is a problem that it is difficult to obtain a low noise VTR with a built-in camera simply by covering the generated noise with a normal injection-molded plastic housing, and the noise is collected by the microphone (10).
また、シールドプレート(8)及び絶縁シート(9)を
装着しなければならず、そのためのスペースの確保が困
難であり、部品点数が多くなるため、カメラ一体型VTR
の小型化及びコストダウンを図れないという問題があっ
た。In addition, since the shield plate (8) and the insulating sheet (9) must be mounted, it is difficult to secure a space for that, and the number of parts increases, so that the camera-integrated VTR
However, there is a problem in that it is impossible to reduce the size and cost.
この発明は上記のような問題点を解消するためになされ
たもので、比重変化をもたせた多孔質層の吸音部材を用
いることにより吸音特性を良好なものとすると共に、複
雑な材質にも対応できる静電気シールド効果を有する筺
体を用いて小型のカメラ一体型VTRを得ることを目的と
する。The present invention has been made to solve the above problems, and improves the sound absorption characteristics by using a sound absorbing member of a porous layer having a change in specific gravity, and also supports complicated materials. The purpose is to obtain a small VTR with a built-in camera by using a housing that has a static electricity shielding effect.
[課題を解決するための手段] この発明に係るカメラ一体型VTRは、比重を層の厚さ方
向もしくは面方向に連続的に変化させた多孔質層の吸音
部材と、この吸音部材の内側に融着して一体化した多孔
質層よりも空孔率の小さい非通気性の融合層部材とから
なる多孔質構造体により筺体を構成したものである。[Means for Solving the Problems] A camera-integrated VTR according to the present invention includes a sound absorbing member of a porous layer in which specific gravity is continuously changed in a thickness direction or a surface direction of the layer, and a sound absorbing member inside the sound absorbing member. A casing is composed of a porous structure composed of a non-breathable fused layer member having a porosity smaller than that of the fused and integrated porous layer.
[作用] この発明におけるカメラ一体型VTRは、比重すなわち空
孔率を変化させた多孔質層の部材を装着することにより
各種特性を向上させる。[Operation] The camera-integrated VTR according to the present invention improves various characteristics by mounting the member of the porous layer having a changed specific gravity, that is, a porosity.
例えば、厚み等に応じて空孔率の変化度合を変えて吸音
特性の周波数を制御したり、多孔質層の吸音部材とその
内側に融着された非通気性の融合層部材とを層状にする
と遮音特性が向上する。For example, the frequency of sound absorption characteristics is controlled by changing the degree of change in porosity according to the thickness or the like, or the sound absorption member of the porous layer and the non-air-permeable fusion layer member fused inside thereof are layered. Then, the sound insulation property is improved.
[実施例] 以下、この発明の一実施例について説明する。[Embodiment] An embodiment of the present invention will be described below.
第1図はこの発明によるカメラ一体型VTRの筺体を示す
斜視図であり、図において、(1a)は機構部で発生する
騒音の吸収及び静電気シールド効果を有する多孔質層の
吸音部材と非通気性の融合部材とからなる筺体である。FIG. 1 is a perspective view showing a housing of a camera-integrated VTR according to the present invention. In the figure, (1a) is a sound absorbing member of a porous layer having a sound absorbing effect and a static electricity shielding effect and a non-ventilating member. It is a housing composed of a sex fusion member.
(2)はネジ(3)を用いて筺体(1a)で回路部及び機
構部を覆い密閉するように取り付けるときに回路部
(6)のグランド部又は機構部(7)に接触する導電性
の取付首部である。(2) is a conductive part that comes into contact with the ground part of the circuit part (6) or the mechanism part (7) when the circuit part and the mechanism part are attached so as to cover and seal the circuit part and the mechanism part using the screw (3). It is a mounting neck.
第2図は、第1図の取付首部(2)付近を示す断面図で
ある。図において、(17)は比重を層の厚さ方向に変化
させた多孔質層の吸音部材、(16)は多孔質層(17)に
融着して一体化した非通気性の導電性部材(16a)及び
非導電性部材(16b)からなる融合層部材である。FIG. 2 is a sectional view showing the vicinity of the mounting neck portion (2) of FIG. In the figure, (17) is a sound absorbing member of a porous layer in which the specific gravity is changed in the thickness direction of the layer, and (16) is a non-air-permeable conductive member fused and integrated with the porous layer (17). (16a) and a non-conductive member (16b), which is a fusion layer member.
なお、上記実施例では、(1a)の筺体のみ多孔質構造体
としたが筺体(1b)、(1c)、(1d)(第19図参照)も
同様の構造としても良い。また融合層部材(16)を非導
電性部材のみにより構成し、吸音効果のみを得るように
しても良い。In the above embodiment, only the casing of (1a) is a porous structure, but the casings (1b), (1c), (1d) (see FIG. 19) may have the same structure. Further, the fusion layer member (16) may be composed of only a non-conductive member to obtain only the sound absorbing effect.
次に、本発明に用いる吸音材と非通気性の融合層部材と
からなる多孔質構造体(以下多孔質体あるいは層状のも
のは多層材ともいう)の構造、製法、特性について説明
する。なお詳細については平成1年4月28日出願の特願
平01−110996号明細書、名称「多孔質構造体」に記載し
てある。Next, the structure, manufacturing method, and characteristics of a porous structure (hereinafter, a porous body or a layered one is also referred to as a multi-layer material) composed of a sound absorbing material and a non-air-permeable fusion layer member used in the present invention will be described. The details are described in Japanese Patent Application No. 01-110996, filed April 28, 1991, under the name "porous structure".
第3図(A)、(B)は、それぞれ多層材(14)の厚さ
方向に切断した断面を模式的に示す図である。図におい
て、(15)は比重の大きい層、例えば融合層で、通気性
又は非通気性のいずれでもよい。3 (A) and 3 (B) are diagrams schematically showing cross sections of the multilayer material (14) taken in the thickness direction. In the figure, (15) is a layer having a large specific gravity, for example, a fusion layer, which may be breathable or non-breathable.
(16)は比重の小さい多孔質層で、通常は通気性であ
り、空孔率は、厚さ方向に連続的に変化している。(16) is a porous layer having a small specific gravity, which is usually breathable, and the porosity continuously changes in the thickness direction.
(17)は通常比重が融合層(15)と多孔質層(16)の中
間にあるスキン層で、例えば厚さ100ミクロン以下の融
合層である。(17) is a skin layer whose specific gravity is normally between the fusion layer (15) and the porous layer (16), for example, a fusion layer having a thickness of 100 μm or less.
多層材(14)は、融合層(15)と多孔質層(16)とが一
体化しており、同様に融合層(15)と多孔質層(16)と
スキン層(17)は一体化している。In the multilayer material (14), the fusion layer (15) and the porous layer (16) are integrated, and similarly, the fusion layer (15), the porous layer (16) and the skin layer (17) are integrated. There is.
多層材(14)は吸音材として使用するときは、多孔質層
(16)を騒音源側に対面させて、音のエネルギーを吸収
減衰させかつ、融合層(15)で音波が透過するのを防
ぐ。When the multilayer material (14) is used as a sound absorbing material, the porous layer (16) is faced to the noise source side to absorb and attenuate sound energy and prevent the sound wave from being transmitted through the fusion layer (15). prevent.
次に、上記のような多層材(多孔質構造体)(14)を構
成する、層の厚さ方向もしくは層の面方向に比重を連続
的に変化させた多孔質層の製造方法及び特性について説
明する。Next, regarding the manufacturing method and characteristics of the porous layer that constitutes the multilayer material (porous structure) (14) as described above, in which the specific gravity is continuously changed in the thickness direction of the layer or the plane direction of the layer explain.
まず、製造方法について説明する。First, the manufacturing method will be described.
第4図は、多層材の製造方法を説明する金型構成断面図
である。図において、(18)は凹側金型で、例えばアル
ミニウム等の熱伝導性の良い材質で構成されており、
(19)は凸側金型で、同様にアルミニウムで構成されて
いる。FIG. 4 is a cross-sectional view of a die structure for explaining a method for manufacturing a multilayer material. In the figure, (18) is a concave mold, which is made of a material having good thermal conductivity, such as aluminum,
(19) is a convex mold, which is also made of aluminum.
(20)、(21)は各々金型の温度を上げるヒーターで、
凹側金型(18)の方が凸側金型(19)よりも高温にされ
る。(20) and (21) are heaters that raise the mold temperature.
The concave mold (18) is heated to a higher temperature than the convex mold (19).
製法 原料として、熱可塑性樹脂の粒状素材を用いて、多孔質
構造体を成形する場合について説明する。Manufacturing Method A case of molding a porous structure using a granular material of thermoplastic resin as a raw material will be described.
凹側金型(18)の壁部(22)の温度は、凹側金型(18)
と凸側金型(19)によって形成される閉空間(23)内に
入れられる原料である粒状素材の軟化する温度以上で熱
分解温度以下、通常150〜240℃にセットされ、凸側金型
(19)の壁部(24)の温度は、凹側金型(18)の壁部
(22)の温度よりも低い温度、例えば原料となる粒状素
材の軟化する温度付近、通常70〜180℃にセットされ
る。The temperature of the wall (22) of the concave mold (18) is the same as that of the concave mold (18).
And the convex mold is set to a temperature above the softening temperature of the granular material that is the raw material placed in the closed space (23) formed by the convex mold (19) and below the thermal decomposition temperature, usually 150 to 240 ° C. The temperature of the wall part (24) of (19) is lower than the temperature of the wall part (22) of the concave mold (18), for example, near the softening temperature of the raw material granular material, usually 70 to 180 ° C. Is set to.
すると、凹側金型(18)の高温壁部(22)に接触した粒
状素材は溶融し、最終的には比重の大きい層、すなわち
融合層(15)になり、融合の程度により通気性から非通
気性に変化する。Then, the granular material in contact with the high temperature wall portion (22) of the concave side mold (18) is melted and finally becomes a layer having a large specific gravity, that is, a fusion layer (15). Changes to non-breathable.
凸側金型(19)の壁部(24)は高温壁部(22)より低温
のため、壁部(24)から上記融合層(15)までの粒状素
材は、完全流動までには至らないが、半流動状態で、粒
状素材各々が接触部分で溶着し、最終的には上記融合層
(15)に溶着した多孔質層(16)が形成される。Since the wall portion (24) of the convex mold (19) is colder than the high temperature wall portion (22), the granular material from the wall portion (24) to the fusion layer (15) does not reach complete flow. However, in a semi-fluid state, each of the granular materials is welded at the contact portion, and finally the porous layer (16) welded to the fusion layer (15) is formed.
この多孔質層(16)は通常は通気性であるが、バインダ
ーなどの素材の混合材によっては非通気性になる。The porous layer (16) is normally breathable, but it becomes non-breathable depending on a mixture of raw materials such as a binder.
このようにして比重の大きい層と比重の小さい多孔質層
を一体的に同時に成形することができる。In this way, a layer having a large specific gravity and a porous layer having a small specific gravity can be integrally molded at the same time.
粒状素材の直径が0.2mm以下になると、空孔径が小さく
なって、多層材の機能、例えば吸音特性が低下する。When the diameter of the granular material is 0.2 mm or less, the pore diameter becomes small, and the function of the multilayer material, for example, the sound absorbing property is deteriorated.
また、空孔径を大きくしようとすると、粒子間の融着度
合が少なくなり、機械的強度が低下する。更に、直径が
3mm以上になると、吸音特性が低下する。Further, if the pore diameter is increased, the degree of fusion between particles is reduced and the mechanical strength is reduced. Furthermore, the diameter is
If it is 3 mm or more, the sound absorption characteristics deteriorate.
なお、熱可塑性樹脂の粒状素材原料としては、代表的な
ものとして、PP(ポリプロピレン)、AS(アクリルスチ
ロール)、スチロールなどを用いることができる。In addition, as a granular material raw material of the thermoplastic resin, PP (polypropylene), AS (acrylic styrene), styrene, and the like can be typically used.
又、熱可塑性樹脂の粒状素材にバインダーとして、メチ
ルエチルケトン(MEK)セルロース、ワニス、アセトン
を吹付けたり、混ぜたりすると、多層材の粒状素材各々
の固着力が増し、機械的強度が向上して、取扱い性が良
くなる。Further, as a binder to the granular material of thermoplastic resin, spraying or mixing methyl ethyl ketone (MEK) cellulose, varnish, and acetone, the adhesion of each granular material of the multilayer material is increased, the mechanical strength is improved, Improves handleability.
製法 原料として、熱硬化性樹脂の粒状素材を用いて多層材を
成形する場合について説明する。Manufacturing Method A case of molding a multilayer material using a granular material of thermosetting resin as a raw material will be described.
製法と同様にして、凹側金型(18)の壁部(22)の温
度は、粒状素材の軟化する温度以上で熱分解以下にセッ
トされ、凸側金型(19)の壁部(24)の温度は、凹側金
型(18)の壁部(22)の温度よりも低い粒状素材の軟化
する温度付近にセットされる。Similar to the manufacturing method, the temperature of the wall portion (22) of the concave die (18) is set to not less than the temperature for softening the granular material and not more than thermal decomposition, and the wall portion (24) of the convex die (19) is set. ) Is set to a temperature near the softening temperature of the granular material, which is lower than the temperature of the wall portion (22) of the concave die (18).
ここにおいて金型(18)、(19)内に熱硬化性樹脂、例
えばフェノール、PBT(ポリブチレンテレフタレー
ト)、PET(ポリエチレンテレフタレート)などの粒状
素材で直径0.2〜3mm程度の粒子を、バインダーとなる例
えばセルロース、ワニス、各種接着剤などと混合して投
入し、金型(18)、(19)を加圧しながら閉じ、数分〜
数時間加熱する。Here, a thermosetting resin such as phenol, PBT (polybutylene terephthalate), PET (polyethylene terephthalate) or other granular material having a diameter of 0.2 to 3 mm is used as a binder in the molds (18) and (19). For example, it is mixed with cellulose, varnish, various adhesives, etc. and added, and the molds (18) and (19) are closed while being pressed, and the mixture is blown for several minutes.
Heat for several hours.
この加熱は上述した金型(18)、(19)のセット温度で
行われ、加圧力は加熱状態で1kg/cm2〜数ton/cm2であ
る。This heating is performed at the set temperature of the molds (18) and (19) described above, and the pressing force is 1 kg / cm 2 to several tons / cm 2 in the heated state.
このようにすると、凹側金型(18)の温度壁部(22)に
接触した粒状素材は軟化し、バインダーで接着されて比
重の大きい層となり、軟化の程度により、通気性から非
通気性に変化する。By doing so, the granular material contacting the temperature wall portion (22) of the concave mold (18) is softened and is bonded with a binder to form a layer having a large specific gravity. Depending on the degree of softening, breathable to non-breathable. Changes to.
凸側金型(19)の壁部(24)は高温壁部(22)により低
温のため、壁部(24)から上記の比重の大きい層(15)
までの粒状素材は、完全流動までには至らないが、半流
動状態で、粒状素材各々が接触部分でバインダーで接着
されて、最終的には、上記の比重の大きい層(15)に接
着した多孔質層(16)が一体的に形成される。Since the wall portion (24) of the convex mold (19) has a low temperature due to the high temperature wall portion (22), the layer (15) having a large specific gravity from the wall portion (24).
Although the granular materials up to the above do not reach full fluidity, in the semi-fluid state, the granular materials are adhered to each other by the binder at the contact portion and finally adhered to the layer (15) having a large specific gravity. The porous layer (16) is integrally formed.
この多孔質層(16)は通常は通気性であるが、バインダ
ーの混合量が多くなると、非通気性になる。The porous layer (16) is normally breathable, but becomes non-breathable when the amount of the binder mixed increases.
さらに、多層材の多孔質層の比重を、多孔質層の層面方
向に変化させようとするには、低温側の金型の温度を上
記層面方向に沿って変化すればよい。Further, in order to change the specific gravity of the porous layer of the multilayer material in the layer surface direction of the porous layer, the temperature of the mold on the low temperature side may be changed along the layer surface direction.
すると低温側の金型の中でも、より高温部に対向する多
孔質層部分は、比重が大きくなり、より低温部に対向す
る多孔質層部分は比重が小さくなる。Then, in the mold on the low temperature side, the specific gravity of the porous layer portion facing the higher temperature portion becomes large, and the specific gravity of the porous layer portion facing the lower temperature portion becomes small.
一方、上述の製法においては、多層材が一体的に成形で
きるので、金型を変えることにより、種々の形状、特に
複雑な形状の多層材にも容易に対応できる。On the other hand, in the above-mentioned manufacturing method, since the multilayer material can be integrally molded, it is possible to easily cope with various shapes, particularly complicated shapes of the multilayer material, by changing the mold.
次に、このようにして製造された、層の厚さ方向もしく
は層の面方向に比重を連続的に変化させた多孔質層の各
種特性及び応用等について説明する。Next, various characteristics and applications of the porous layer produced in this manner, in which the specific gravity is continuously changed in the thickness direction of the layer or the surface direction of the layer, will be described.
(i)吸音特性 第5図は、製法で成形された厚さ10mmの多孔質構造体
(ほとんど全域多孔質層)における厚さ方向の空孔率
(比重)分布例を示す図である。(I) Sound Absorption Property FIG. 5 is a diagram showing an example of a porosity (specific gravity) distribution in the thickness direction of a 10 mm-thick porous structure (almost all porous layer) formed by the manufacturing method.
第5図中、曲線A、Cは、空孔率が厚さ方向にほぼ一様
な特性を示し、それぞれ約25(%)、約10(%)のもの
であり、曲線Bは、空孔率が厚さ方向に分布を有し、10
〜20(%)の範囲で連続的に変化しているものである。In FIG. 5, curves A and C show characteristics in which the porosity is substantially uniform in the thickness direction, which are about 25 (%) and about 10 (%), respectively, and curve B is the porosity. The ratio has a distribution in the thickness direction, 10
It is one that changes continuously within the range of ~ 20 (%).
この種の多孔質構造体を吸音材として利用する場合に
は、その吸音特性が問題になる。When this kind of porous structure is used as a sound absorbing material, its sound absorbing characteristic becomes a problem.
第6図は第5図に示す三種類の空孔率分布を有するサン
プルにおける垂直入射吸音率をJIS A1405「管内法によ
る建築材料の垂直入射吸音率の測定法」により測定した
結果を示す。FIG. 6 shows the results of measurement of the normal incident sound absorption coefficient of the samples having three kinds of porosity distributions shown in FIG. 5 by JIS A1405 “Measuring method of vertical incident sound absorption coefficient of building materials by in-pipe method”.
なお、曲線Bの厚さ方向に空孔率分布を有するサンプル
では、空孔率が10(%)の方を音波を入射する面とし
た。In the sample having the porosity distribution in the thickness direction of the curve B, the porosity of 10 (%) was set as the surface on which the sound wave is incident.
図から判るように、空孔率分布を有するサンプル(曲線
B)が最も吸音率特性が良いことを確認した。As can be seen from the figure, it was confirmed that the sample having the porosity distribution (curve B) had the best sound absorption coefficient characteristic.
以上説明した多孔質層を形成する樹脂粒は形状が球状の
ほか、円筒状、円柱状、立方体などでもよい。ひげ付き
の熱可塑性樹脂粒はひげの部分が溶融しやすいので、原
料として好適である。The resin particles forming the porous layer described above may have a spherical shape, a cylindrical shape, a cylindrical shape, a cubic shape, or the like. The beard-bearing thermoplastic resin particles are suitable as a raw material because the beard portion is easily melted.
又、多層材の軽量化を図る目的で、例えば発泡した中空
粒状素材や発泡性素材を原料として利用することもでき
る。Further, for the purpose of reducing the weight of the multilayer material, for example, a foamed hollow granular material or a foamable material can be used as a raw material.
更に、補強用として原料に短繊維を混入させてもよい
し、バインダーとして糸状の熱可塑性樹脂を原料に混入
させてもよい。Furthermore, short fibers may be mixed into the raw material for reinforcement, or a filamentous thermoplastic resin may be mixed into the raw material as a binder.
なお、多孔質体としての特性、特に吸音特性に対し、粒
状素材の形状や長径には、より優れた特性を有する範囲
があることを確認した。以下に説明する。It has been confirmed that the shape and major axis of the granular material have a range having more excellent characteristics with respect to the characteristics of the porous body, particularly the sound absorbing characteristics. This will be described below.
第7図には、粒状素材の形状を変えた場合の素材入射吸
音率の特性バラツキ(サンプル数5個での特性のバラツ
キ)を示す図である。曲線Aは粒状素材が直径0.8(m
m)、長さ1(mm)の円筒形状のもの、曲線Bは直径1
(mm)の球体状のものである。FIG. 7 is a diagram showing the characteristic variation of the material incident sound absorption coefficient (the characteristic variation when the number of samples is 5) when the shape of the granular material is changed. Curve A has a diameter of 0.8 (m
m), length 1 (mm) cylindrical shape, curve B has diameter 1
(Mm) spherical shape.
なお、いずれも多孔質層の厚さは10(mm)であり、吸音
率を測定した周波数は2(KHz)である。同図より、球
体状のもの(曲線B)は、サンプルの違いによる特性の
差が少なく、極めて安定していることが判る。In each case, the thickness of the porous layer is 10 (mm), and the frequency at which the sound absorption coefficient is measured is 2 (KHz). From the figure, it can be seen that the spherical shape (curve B) has very little difference in characteristics due to the difference in samples, and is extremely stable.
この理由は、球体状の場合、粒状素材どうしの接触点が
一個所となるので、成形時に粒状素材の層状態が安定し
て均一になるためである。The reason for this is that, in the case of a spherical shape, there is only one point of contact between the granular materials, and the layer state of the granular material becomes stable and uniform during molding.
このように、特にサンプル間で特性の安定性を要する場
合などには球体状(球体もしくは楕円体)にする方が、
より好ましい多孔質構造体を得ることができる。In this way, it is better to make it spherical (sphere or ellipsoid) especially when stability of characteristics is required between samples.
A more preferable porous structure can be obtained.
また、吸音特性は、粒状素材の長径によっても異なるこ
とを確認した。第8図に、粒状素材の長径と吸音率の関
係を示す。It was also confirmed that the sound absorption characteristics differ depending on the major axis of the granular material. FIG. 8 shows the relationship between the major axis of the granular material and the sound absorption coefficient.
サンプルの厚さは10(mm)で、測定周波数は2(KHz)
である。粒状素材を径を小さく過ぎたり、大きくし過ぎ
たりすると、音波が多孔質体内に侵入しにくくなった
り、多孔質体の固有音響インピーダンスが空気側の固有
音響インピーダンスと整合しなくなったりして吸音率が
低下する。The thickness of the sample is 10 (mm) and the measurement frequency is 2 (KHz).
Is. If the diameter of the granular material is made too small or too large, it becomes difficult for sound waves to enter the porous body, or the specific acoustic impedance of the porous body does not match the specific acoustic impedance of the air side, and the sound absorption coefficient Is reduced.
第8図より、粒状素材の長径は、実用的な範囲では0.2
〜3.0(mm)、好ましくは1.0〜2.0(mm)の範囲とする
ことにより、吸音特性を良好にできることを確認した。From Fig. 8, the major axis of the granular material is 0.2 in a practical range.
It was confirmed that the sound absorption characteristics can be improved by setting the range to 3.0 (mm), preferably 1.0 to 2.0 (mm).
次に、本発明に用いる多孔質構造の他の実施例について
説明する。Next, another embodiment of the porous structure used in the present invention will be described.
多孔質構造体は、層の厚さ方向もしくは層の面方向に比
重を連続的に変化させた多孔質層と、この多孔質よりも
空孔率が小さく比重の大きい中実層とを層状にしたもの
である。The porous structure is formed by layering a porous layer whose specific gravity is continuously changed in the thickness direction of the layer or the surface direction of the layer and a solid layer having a smaller porosity and a larger specific gravity than this porous layer. It was done.
この中実層は、粒状素材が熱可塑性樹脂の場合は、融合
層になり、融合の程度により通気性から非通気性まで変
化する。When the granular material is a thermoplastic resin, this solid layer becomes a fusion layer, and changes from breathable to non-breathable depending on the degree of fusion.
また、粒状素材が熱硬化性樹脂の場合には、粒状素材が
軟化しバインダーで接着されて比重の大きい層となり、
軟化の程度により通気性から非通気性まで変化する。When the granular material is a thermosetting resin, the granular material is softened and adhered with a binder to form a layer having a large specific gravity,
It changes from breathable to non-breathable depending on the degree of softening.
次に、このような多孔質構造体の代表的な製造方法につ
いて説明する。Next, a typical method for manufacturing such a porous structure will be described.
製法例− 製法において、凹側金型(18)の壁部(22)の温度を
150℃にセットし、凸側金型(19)の壁部(24)の温度
を100℃にセットし、ABS樹脂として、電気化学工業株式
会社製GTR−40(グレード)、軟化する温度86℃の熱可
塑性樹脂の粒状素材、直径1mmの球状粒子を金型に入
れ、金型(18)、(19)を閉じた。この時、壁面(2
2)、(24)間の距離は10mmであった。Manufacturing method-In the manufacturing method, the temperature of the wall (22) of the concave mold (18) is
Set the temperature of the wall part (24) of the convex mold (19) to 100 ° C, set it to 150 ° C, and use GTR-40 (grade) manufactured by Denki Kagaku Kogyo Co., Ltd. as ABS resin, and the softening temperature 86 ° C The granular material of thermoplastic resin of 1 and spherical particles having a diameter of 1 mm were put into a mold, and the molds (18) and (19) were closed. At this time, the wall (2
The distance between 2) and (24) was 10 mm.
この状態で20分間経過(つまり加熱状態を持続)させて
金型(18)、(19)を開放した。なお、加熱状態のとき
の加圧力は100kg/cm2であった。In this state, the molds (18) and (19) were opened by allowing 20 minutes to elapse (that is, maintaining the heating state). The pressure applied in the heated state was 100 kg / cm 2 .
このようにして成形した多層材(14)を第9図に示す。
この多層材(14)は厚さが10mmでその中の融合層(15)
の厚さは約1mm、多孔質層(16)の厚さは約9mmであっ
た。The multilayer material (14) thus molded is shown in FIG.
This multi-layer material (14) has a thickness of 10 mm and the fusion layer (15) in it.
Had a thickness of about 1 mm, and the porous layer (16) had a thickness of about 9 mm.
製法例−3 製法において、凹側金型(18)の壁部(22)の温度を
180℃にセットし、凸側金型(19)の壁部(24)の温度
を130℃にセットし、ABS樹脂として、電気化学工業株式
会社製GTR−40(グレード)、軟化する温度86℃の熱可
塑性樹脂の粒状素材、直径1mmの球状粒子を金型に入
れ、金型(18)、(19)を閉じた。この際、壁面(2
2)、(24)間の距離は10mmであった。Manufacturing Example-3 In the manufacturing method, the temperature of the wall portion (22) of the concave mold (18) is changed to
Set the temperature of the wall (24) of the convex mold (19) to 130 ° C, set it to 180 ° C, and use GTR-40 (grade) manufactured by Denki Kagaku Kogyo Co., Ltd. as ABS resin, and the temperature of softening 86 ° C The granular material of thermoplastic resin of 1 and spherical particles having a diameter of 1 mm were put into a mold, and the molds (18) and (19) were closed. At this time, the wall (2
The distance between 2) and (24) was 10 mm.
この状態で15分間経過させて金型(18)、(19)を開放
した。なお加熱状態のときの加圧力は100kg/cm2であっ
た。In this state, the molds (18) and (19) were opened for 15 minutes. The applied pressure in the heated state was 100 kg / cm 2 .
このとき成形した多層材(14)は厚さが10mm、その中の
融合層(15)の厚さは約1mm、多孔層(16)の厚さは約9
mmであったが、製法例−2の成形多層材(14)に比
べ、多孔層(16)の表面部の融合化が一部分進み、30μ
m程度のスキン層が形成された。The multilayer material (14) molded at this time has a thickness of 10 mm, the fusion layer (15) in it has a thickness of approximately 1 mm, and the porous layer (16) has a thickness of approximately 9 mm.
However, compared with the molded multi-layer material (14) of Production Example-2, the fusion of the surface of the porous layer (16) progressed partially,
A skin layer of about m was formed.
製法例−2 製法において、凹側金型(18)の壁(22)の温度を20
0℃にセットし、凸側金型(19)の壁部(24)の温度を1
50℃にセットし、熱硬化性樹脂として、フェノール樹脂
(明和化成株式会社製、MW−752(グレード)、軟化す
る温度190℃)で直径1mmの粒状素材を、バインダーとな
る粉末状セルロース15重量%と共に金型に入れ、金型
(18)、(19)を閉じた。Manufacturing Example-2 In the manufacturing method, the temperature of the wall (22) of the concave mold (18) is set to 20.
Set to 0 ℃, and set the temperature of the wall (24) of the convex mold (19) to 1
Set to 50 ℃, as a thermosetting resin, phenolic resin (Maywa Kasei Co., Ltd., MW-752 (grade), softening temperature 190 ℃), a granular material with a diameter of 1mm, powder cellulose 15 serving as a binder The mold (18) and (19) were closed by placing them in the mold together with%.
壁面(22)、(24)間の距離は10mmであった。この状態
で25分間経過(つまり加熱状態を持続)させて金型(1
8)、(19)を開放した。The distance between the walls (22) and (24) was 10 mm. In this state, the mold (1
8) and (19) were opened.
なお加熱状態のときの加圧力は150kg/cm2であった。こ
のように成形した多層材(14)は厚さが10mmで、その中
の比重の大きい層(15)の厚さは約1mm、多孔質層(1
6)の厚さは約9mmであった。The applied pressure in the heated state was 150 kg / cm 2 . The thus-formed multilayer material (14) has a thickness of 10 mm, and the layer (15) having a large specific gravity therein has a thickness of about 1 mm, and the porous layer (1
The thickness of 6) was about 9 mm.
なお熱硬化性樹脂を熱可塑性樹脂でコートした粒状素材
を原料として用いてもよい。A granular material obtained by coating a thermosetting resin with a thermoplastic resin may be used as a raw material.
次に、上記のようにして成形された多層材(層状の多孔
質構造体)の特性等について説明する。Next, characteristics and the like of the multilayer material (layered porous structure) molded as described above will be described.
(i)空孔率 第10図は成形された多層材の空孔率を示す曲線図で曲線
実−2、実−3はそれぞれ製法例−2、製法例
−3によって製造された多層材の厚さ(mm)に対する空
孔率(%)を示す。(I) Porosity FIG. 10 is a curve diagram showing the porosity of the formed multi-layered material. Curves Real-2 and Real-3 are the multi-layered materials produced by Production Example-2 and Production Example-3, respectively. The porosity (%) with respect to the thickness (mm) is shown.
融合層(15)はいずれも非通気性で、実−2の多孔質
層(16)は厚さ方向に空孔率が連続的に変化し、表面
(低温側)で空孔率が最大となる。実−3の多孔質層
(16)は厚さ方向に空孔率が連続的に変化するが、多孔
質層(16)の中央で空孔率が最大になり表面部(低温
側)で空孔率が低下する。The fusion layers (15) are all non-breathable, and the porosity of the solid-2 porous layer (16) changes continuously in the thickness direction, and the porosity becomes maximum on the surface (low temperature side). Become. The porosity of the real-3 porous layer (16) continuously changes in the thickness direction, but the porosity becomes maximum at the center of the porous layer (16) and becomes void at the surface (low temperature side). Porosity decreases.
すなわち、表面部の空孔率は、多孔質層(16)の最大の
空孔率と融合層(15)の空孔率の中間であり、部分的に
融合したスキン層(17)が形成されていることを示して
いる。That is, the porosity of the surface portion is between the maximum porosity of the porous layer (16) and the porosity of the fusion layer (15), and a partially fused skin layer (17) is formed. It indicates that
なお比重は材質が同じであれば、当然ながら空孔率が小
さいほど大きい。It should be noted that the specific gravity is larger as the porosity is smaller, if the materials are the same.
(ii)層状多孔質構造体の特性 多層材を吸音材として使用する場合にはその吸音特性が
問題になる。(Ii) Characteristics of Layered Porous Structure When a multilayer material is used as a sound absorbing material, its sound absorbing characteristic becomes a problem.
第11図は垂直入射吸音率を比較する曲線図で、垂直入射
吸音率を前述のJIS A 1405により測定した結果を示
す。FIG. 11 is a curve diagram for comparing the normal incident sound absorption coefficient, and shows the result of measuring the normal incident sound absorption coefficient according to JIS A 1405 described above.
曲線実−2は製法−2で製造した多層材で厚さ10mm
のもの、曲線「従」は従来の吸音材であるウレタンフォ
ームで厚さ10mmのものの特性をそれぞれ示す。Curve 2 is a multi-layered material manufactured by manufacturing method 2 with a thickness of 10 mm
And the curve "Following" show the characteristics of the conventional sound absorbing material urethane foam with a thickness of 10 mm.
図からも判るように、多層材の垂直入射吸音率は従来の
吸音材(ウレタンフォーム)のそれと同等以上の特性を
有することを確認した。As can be seen from the figure, it was confirmed that the normal-incidence sound absorption coefficient of the multilayer material has characteristics equal to or higher than that of the conventional sound absorption material (urethane foam).
第12図は同様な垂直入射吸音率の特性曲線図で、いずれ
の曲線も前述の方法で製造した多層材の特性で、実−
2、実−3はそれぞれ製法例−2、製法例−3で
製造した厚さ10mmの多層材の特性を示す。Fig. 12 is a similar characteristic curve of normal incidence sound absorption coefficient. All curves are the characteristics of the multilayer material manufactured by the above-mentioned method.
2 and Example 3 show the characteristics of the multi-layered material with a thickness of 10 mm produced in Production Example-2 and Production Example-3, respectively.
なお、製法例−3のものの特性が良好な理由は表面部
の空孔率の最適化の影響と思われる。In addition, it is considered that the reason why the characteristics of the manufacturing method example-3 are good is the optimization of the porosity of the surface portion.
(iii)スキン層の効果 次に、スキン層により吸音特性が向上する現象の解明及
びその最適厚さについて説明する。(Iii) Effect of Skin Layer Next, elucidation of the phenomenon that the sound absorption characteristics are improved by the skin layer and its optimum thickness will be described.
まず、多孔質体素材としてABS樹脂を用いて、厚さ10mm
のサンプルを前述の製法により製作した。First, using ABS resin as the porous material, the thickness is 10 mm.
Was prepared by the above-mentioned manufacturing method.
このサンプルの空孔率分布の実測結果を第13図に、空孔
率の小さい方を音波入射面なしでその垂直入射吸音率特
性を第14図に示す。The measurement result of the porosity distribution of this sample is shown in FIG. 13, and the normal incidence sound absorption coefficient characteristics of the one with smaller porosity without the sound incident surface are shown in FIG.
図から明らかなように、このサンプルでは、400(Hz)
という低周波で吸音率が最大となり、しかもその値が90
(%)を越える良好な吸音特性が得られた。As can be seen from the figure, in this sample, 400 (Hz)
The sound absorption coefficient becomes maximum at the low frequency, and the value is 90.
Good sound absorption characteristics exceeding (%) were obtained.
このとき、このサンプルの音波入射面側の低空孔率部を
顕微鏡で破断観察した結果、その表面が厚さ30ミクロン
程度の、ほぼ非通気性のスキン層になっていることが見
出された。At this time, as a result of fracture observation of the low porosity portion on the sound wave incident surface side of this sample with a microscope, it was found that the surface was a skin layer of about 30 microns in thickness, which was almost impermeable. .
さらに、スキン層の厚さを種々変更して吸音特性の試験
を行った結果、スキン層の厚さが100ミクロンを越える
と、スキン層が質量としてではなく、弾性膜(バネ系)
として働くようになり、最高吸音率の周波数は、逆に上
がってしまい、所要の効果は得られなかった。Furthermore, as a result of conducting sound absorption characteristic tests by changing the thickness of the skin layer, when the thickness of the skin layer exceeds 100 microns, the skin layer is not a mass but an elastic film (spring type).
As a result, the frequency of the highest sound absorption coefficient rose on the contrary, and the desired effect was not obtained.
従って、スキン層の厚さは100ミクロン以下が妥当であ
ることを確認した。Therefore, it was confirmed that the skin layer thickness of 100 μm or less is appropriate.
上記の層状の多孔質構造体は、主として二層の場合で説
明してきたが、三層あるいは任意層・任意材質の多孔質
構造体とすることもできる。Although the above-mentioned layered porous structure has been mainly described in the case of two layers, it may be a three-layer structure or an arbitrary layer / arbitrary material porous structure.
第15図は、スキン層(17)、多孔質層(16)及び非通気
性の中実層(15)よりなる三重層の多孔質構造体(14
a)の断面図を示す。FIG. 15 shows a triple-layer porous structure (14) comprising a skin layer (17), a porous layer (16) and a non-breathable solid layer (15).
The cross section of a) is shown.
これを、吸音材として用いる場合には、前述したよう
に、スキン層(17)及び多孔質層(16)により優れた吸
音特性を有し、かつ非通気性の中実層(15)が遮音体と
なるので、吸音と遮音の両機能を効果的に発揮する構造
体とすることができる。When this is used as a sound absorbing material, as described above, the skin layer (17) and the porous layer (16) have excellent sound absorbing properties and the non-breathable solid layer (15) is sound-insulating. Since it becomes a body, it can be a structure effectively exhibiting both sound absorbing and sound insulating functions.
なお、上記例に限らず、各分野でその用途に応じて、任
意層・任意材質の多孔質構造体として応用できることは
いうまでもない。Needless to say, the present invention is not limited to the above example, and can be applied as a porous structure of an arbitrary layer and an arbitrary material depending on the application in each field.
さらに、粒状素材に樹脂粒以外の粒を含む素材を用いる
ことにより、多孔質構造体の機能を拡大させることがで
きる。以下、その一実施例を説明する。Furthermore, the function of the porous structure can be expanded by using a material containing particles other than resin particles as the granular material. An example will be described below.
まず、製造方法について説明する。First, the manufacturing method will be described.
製法例−1 第16図は金型(18)、(19)の空間(23)に2種類の粒
を含む素材を入れ金型(18)、(19)を閉じたところを
示す断面図である。Manufacturing Example-1 FIG. 16 is a cross-sectional view showing the mold (18), the space (23) of the (19) is filled with a material containing two kinds of particles, and the molds (18) and (19) are closed. is there.
凹側金型(18)内に、最初に長径が約0.2mmの鉄粒(2
5)を積み厚さが約1mmになるように充填し、その後、長
径が約1mmのABS樹脂粒(26)(製法例−2に使用した
ものと同じもの)を閉空間(23)の高さ(10mm)より約
2mmほど高くなるように充填する。In the concave mold (18), first insert iron particles (2 mm
5) are stacked so that the stacking thickness is approximately 1 mm, and then ABS resin particles (26) with a major axis of approximately 1 mm (the same as those used in Production Example-2) are filled in the closed space (23). About 10 mm
Fill so that it is about 2 mm higher.
充填後、凸側金型(19)(第16図では板状金型)を凹側
金型(18)に密着接合させることにより、上記鉄粒(2
5)とABS樹脂粒(26)の充填層を圧縮し、閉空間(23)
内に異種粒の充填層を形成する。After filling, the convex side mold (19) (plate-shaped mold in FIG. 16) is closely bonded to the concave side mold (18), so that the iron particles (2
5) and the packed bed of ABS resin particles (26) are compressed to form a closed space (23)
A filling layer of different grains is formed therein.
以上の条件で、ABS樹脂粒の軟化する温度86℃より高い
温度、つまり凹側金型温度を150℃、凸側金型温度を100
℃に昇温し、約20分加熱する。鉄粒(25)の融点は約15
00℃であることから、その鉄粒の粒形状は保持された状
態となる。Under the above conditions, the softening temperature of ABS resin particles is higher than 86 ℃, that is, the concave mold temperature is 150 ℃ and the convex mold temperature is 100 ℃.
Heat to ℃ and heat for about 20 minutes. The melting point of iron particles (25) is about 15
Since the temperature is 00 ° C, the particle shape of the iron particles is maintained.
一方ABS樹脂粒は、特に凹側金型(18)の壁部(22)は
高温であることから、それに接触する鉄粒も高温とな
り、鉄粒(25)と接触するABS樹脂粒(26)は溶融し、
溶融したABS樹脂粒が鉄粒(25)を取り巻くように流動
する。On the other hand, the ABS resin particles (26) that come into contact with the iron particles (25) are also high in temperature because the walls (22) of the concave side mold (18) are also high in temperature. Melts,
The molten ABS resin particles flow so as to surround the iron particles (25).
加熱後、冷却されて成形された多層体(14)は、厚さが
10mmでその中鉄粒(25)が混入された融合層(15)は厚
さが約1mm、多孔質層(16)は厚さが約9mmの一体化した
積層体となった。融合層(15)の比重は、鉄粒を含まな
い場合は、ABS樹脂の比重そのものとなり、1.05gr/ccで
あるが、鉄粒を入れた場合は融合層のみを切断し、その
比重を測定した結果、4.4gr/ccであった。After heating, the multilayered body (14) cooled and molded has a thickness of
The fused layer (15) having an iron particle (25) mixed therein with a thickness of 10 mm was about 1 mm in thickness, and the porous layer (16) was an integrated laminate with a thickness of about 9 mm. The specific gravity of the fusion layer (15) is 1.05 gr / cc when it does not contain iron particles, and it is 1.05 gr / cc, but when iron particles are added, only the fusion layer is cut and the specific gravity is measured. As a result, it was 4.4 gr / cc.
多層材の多孔質層を吸音材とし、融合層を遮音材として
利用する場合、遮音材としてはその比重が大きいほど遮
音特性が向上するので、この多層材は遮音特性に優れ
る。When the porous layer of the multilayer material is used as the sound absorbing material and the fusion layer is used as the sound insulating material, the larger the specific gravity of the sound insulating material is, the more the sound insulating property is improved. Therefore, the multilayer material is excellent in the sound insulating property.
従来は、ABS樹脂のような比重の軽い材料の遮音度を上
げるには、その材料の厚さを厚くするか、鉄板などの金
属を貼りつけることが必要であったが、この製造方法で
は溶融する部分に比重の大きい材料を混入させることに
より、多孔質層と比重のさらに大きい融合層を持つ多層
材を容易に実現できる。Conventionally, in order to increase the sound insulation of a material with a low specific gravity such as ABS resin, it was necessary to increase the thickness of the material or to attach a metal such as an iron plate. By mixing a material having a large specific gravity in the portion to be filled, a multilayer material having a porous layer and a fusion layer having a larger specific gravity can be easily realized.
次に、特性例(遮音特性)について説明する。Next, a characteristic example (sound insulation characteristic) will be described.
第18図はこの多層材の遮音度特性を示す曲線図である。FIG. 18 is a curve diagram showing the sound insulation characteristic of this multilayer material.
曲線実−2、曲線実−1はそれぞれ製法例−2で
製造した多層材(鉄粒なし)の厚さ10mmのもの、製法例
−1で製造した多層材(鉄粒入り)の厚さ10mmのもの
の遮音特性を示す。Curve Ex-2 and Curve Ex-1 have a thickness of 10 mm for the multilayer material (without iron particles) manufactured in Manufacturing Example-2, and a thickness of 10 mm for the multilayer material (containing iron particles) manufactured in Manufacturing Example-1. The sound insulation characteristics of the above are shown.
この遮音特性は第17図の特性測定器を用いて測定した。
パイプ(27)(100mmφ)の中に、測定する多層材(1
4)を挿入し、その前後にマイクロホンNo.1、No.2(3
0)、(31)を設置する。This sound insulation characteristic was measured using the characteristic measuring device shown in FIG.
Inside the pipe (27) (100 mmφ), measure the multilayer material (1
4) and insert microphones No. 1 and No. 2 (3
Install 0) and (31).
パイプ(27)の一方端よりスピーカ(28)で音を入射さ
せる。パイプ(27)の他端は閉じており、その閉端に
は、長さ約1000mmのグラスウール(29)を充填してお
り、閉端で音が反射しないように処理されている。スピ
ーカ(28)で放射され、多層材(14)に入射する入射波
の音圧レベルはマイクロホンNo.1(30)で測定し、多層
材を透過する透過波の音圧レベルは、マイクロホンNo.2
(31)で測定される。A speaker (28) emits sound from one end of the pipe (27). The other end of the pipe (27) is closed, and the closed end is filled with glass wool (29) having a length of about 1000 mm, which is processed so that sound is not reflected at the closed end. The sound pressure level of the incident wave radiated from the speaker (28) and incident on the multilayer material (14) is measured with the microphone No. 1 (30), and the sound pressure level of the transmitted wave passing through the multilayer material is the microphone No. 2
Measured at (31).
なお、多層材の遮音度(dB)は、入射波の温圧レベルか
ら透過波の音圧レベルを差引いた値で評価した。The sound insulation level (dB) of the multilayer material was evaluated by the value obtained by subtracting the sound pressure level of the transmitted wave from the temperature level of the incident wave.
第18図に示すように、鉄粒入りのもの(実−1)が、
鉄粒なしのもの(実−2)より約10dB遮音度が向上し
ている。As shown in Fig. 18, the one containing iron particles (actual-1)
Approximately 10 dB better sound insulation than the one without iron particles (actual-2).
上述実施例においては、樹脂粒に混合する粒を鉄粒とし
たが、他の金属、ガラスや比重の大きい材料でも同様の
効果を発揮する。In the above-mentioned embodiment, the particles mixed with the resin particles are iron particles, but other metals, glass, and materials having a large specific gravity also exhibit the same effect.
又、上述実施例においては、遮音特性の向上のみ説明し
たが、電磁シールドにアルミニウムなど電磁シールドに
効果のある材料を混入させてもよく、更に融合層や多孔
質層の強度向上にグラスフィアバなどを、樹脂粒に混入
して成形してもよい。Further, in the above-mentioned examples, only the improvement of the sound insulation property is explained, but a material effective for the electromagnetic shield such as aluminum may be mixed in the electromagnetic shield, and glass fiber or the like may be further used for improving the strength of the fusion layer or the porous layer. Alternatively, the resin particles may be mixed and molded.
[発明の効果] 以上のように、この発明によれば、カメラ一体型VTRを
覆う筺体を、比重を層の厚さ方向に連続的に変化させた
多孔質層の吸音部材と、その内側に融着して一体化した
非通気性の融合層部材とにより構成したので、吸音特性
を向上できる。[Effects of the Invention] As described above, according to the present invention, the housing that covers the camera-integrated VTR is provided with the sound absorbing member of the porous layer in which the specific gravity is continuously changed in the thickness direction of the layer and the inside of the sound absorbing member. Since it is composed of the non-breathable fusion layer member that is fused and integrated, the sound absorption characteristics can be improved.
また、融合層を厚さ100ミクロン以下のスキン層とする
と、さらに吸音特性を向上させることができる。Further, when the fusion layer is a skin layer having a thickness of 100 μm or less, the sound absorbing property can be further improved.
また、比重を変化させた多孔質層の一側面に、この多孔
質よりも空孔率が小さい中実層を他側面に厚さ100ミク
ロン以下のスキン層を設けると、相乗的に特性の向上が
図れる。Also, by providing a solid layer with a porosity smaller than that of the porous layer on one side of the porous layer with a changed specific gravity and a skin layer with a thickness of 100 μm or less on the other side, the characteristics are synergistically improved. Can be achieved.
更に、多孔質構造体を構成する粒子素材を導電性材料を
用いたことにより静電気シールド性能の向上も図れ、装
置の小型化及びコストダウンを図ることができる。Furthermore, by using a conductive material as the particle material forming the porous structure, the electrostatic shield performance can be improved, and the device can be downsized and the cost can be reduced.
また、精度の高いものが得られる効果がある。Further, there is an effect that a highly accurate one can be obtained.
第1図はこの発明の一実施例によるカメラ一体型VTRを
覆う筺体の一部を示す。第2図は第1図の一部断面図を
示す。第3図は本発明に用いる多層材(多孔質構造体)
の模式的断面図、第4図は多孔質構造体を製造する金型
構成断面図、第5図は本発明に用いる多孔質構造体の第
1の実施例であり、多孔質構造体の厚さに対する空孔率
を示す曲線図、第6図は第5図に空孔率曲線を示した多
孔質構造体の垂直入射吸音率の特性曲線図、第7図は多
孔質層を形成する粒状素材の形状を変えた場合の垂直入
射吸音率の特性のバラツキを示す特性図、第8図は粒状
素材の直径と吸音率の関係を示す特性図、第9図は層状
の多孔質構造体を一部断面で示す図、第10図は本発明に
用いる第3の実施例の多孔質構造体の厚さに対する空孔
率を示す曲線図、第11図及び第12図は従来のものと第10
図に空孔率曲線を示した多孔質構造体との垂直入射吸音
率の特性を比較する曲線図、第13図は本発明に用いるス
キン層を有する多孔質構造体の空孔率を示す曲線図、第
14図は第13図に空孔率曲線を示したスキン層を有する多
孔質構造体の垂直入射吸音率の特性曲線図、第15図は本
発明に用いる任意層状の多孔質構造体を示す断面図、第
16図は鉄粒入り多孔質構造体を製造するための金型構成
断面図、第17図は遮音特性を測定する特性測定器の説明
図、第18図は本発明に用いる二種類の多孔質構造体の遮
音度特性曲線図、第19図は従来のカメラ一体型VTRの構
成を示す分解図、第20図は第19図の機構部を詳細に示す
模式図である。 図において、(1)は筺体、(15)は多層材(多孔質構
造体)、(16)は融合層(比重の大きい層、中実層)、
(17)は多孔質層である。 なお、図中、同一符号は同一又は相当部分を示す。FIG. 1 shows a part of a housing which covers a camera-integrated VTR according to an embodiment of the present invention. FIG. 2 shows a partial sectional view of FIG. FIG. 3 shows a multilayer material (porous structure) used in the present invention.
FIG. 4 is a schematic sectional view of a mold for producing a porous structure, FIG. 5 is a first embodiment of the porous structure used in the present invention, and the thickness of the porous structure is Fig. 6 is a characteristic curve diagram of the normal incidence sound absorption coefficient of the porous structure whose porosity curve is shown in Fig. 5, and Fig. 7 is a granular diagram forming the porous layer. Fig. 8 is a characteristic diagram showing the variation in the characteristics of the normal incident sound absorption coefficient when the shape of the material is changed, Fig. 8 is a characteristic diagram showing the relationship between the diameter of the granular material and the sound absorption coefficient, and Fig. 9 is a layered porous structure. FIG. 10 is a partial sectional view, FIG. 10 is a curve diagram showing the porosity with respect to the thickness of the porous structure of the third embodiment used in the present invention, and FIG. 11 and FIG. Ten
A curve diagram comparing the characteristics of the normal incidence sound absorption coefficient with the porous structure showing the porosity curve in the figure, and FIG. 13 is a curve showing the porosity of the porous structure having the skin layer used in the present invention. Figure, first
FIG. 14 is a characteristic curve diagram of the normal incidence sound absorption coefficient of the porous structure having a skin layer showing a porosity curve in FIG. 13, and FIG. 15 is a cross section showing an arbitrary layered porous structure used in the present invention. Figure, first
FIG. 16 is a sectional view of a mold structure for producing a porous structure containing iron particles, FIG. 17 is an explanatory view of a characteristic measuring device for measuring sound insulation characteristics, and FIG. 18 is two kinds of porous materials used in the present invention. FIG. 19 is a sound insulation characteristic curve diagram of the structure, FIG. 19 is an exploded view showing the structure of a conventional camera-integrated VTR, and FIG. 20 is a schematic diagram showing in detail the mechanism section of FIG. In the figure, (1) is a housing, (15) is a multilayer material (porous structure), (16) is a fusion layer (a layer with a large specific gravity, a solid layer),
(17) is a porous layer. In the drawings, the same reference numerals indicate the same or corresponding parts.
───────────────────────────────────────────────────── フロントページの続き (51)Int.Cl.6 識別記号 庁内整理番号 FI 技術表示箇所 H04N 5/225 E H05K 5/02 J 7362−4E ─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. 6 Identification code Internal reference number FI Technical display location H04N 5/225 E H05K 5/02 J 7362-4E
Claims (1)
体型ビデオテープレコーダにおいて、比重を厚さ方向も
しくは面方向に連続的に変化させた多孔質層部材と、多
孔質層部材の一側に融着した非通気性の融合層部材とか
らなる多孔質構造体により筺体を構成したことを特徴と
するカメラ一体型ビデオテープレコーダ。1. A camera-integrated video tape recorder comprising a housing for covering an internal device, wherein a porous layer member having a specific gravity continuously changed in a thickness direction or a surface direction, and one side of the porous layer member. A camera-integrated videotape recorder, characterized in that a casing is made up of a porous structure composed of a non-breathable fusion layer member fused to.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP1208424A JPH0722352B2 (en) | 1989-08-11 | 1989-08-11 | Video tape recorder with integrated camera |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP1208424A JPH0722352B2 (en) | 1989-08-11 | 1989-08-11 | Video tape recorder with integrated camera |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| JPH0371777A JPH0371777A (en) | 1991-03-27 |
| JPH0722352B2 true JPH0722352B2 (en) | 1995-03-08 |
Family
ID=16555992
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP1208424A Expired - Fee Related JPH0722352B2 (en) | 1989-08-11 | 1989-08-11 | Video tape recorder with integrated camera |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPH0722352B2 (en) |
Families Citing this family (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JP2007006722A (en) * | 2005-06-28 | 2007-01-18 | Meitec Corp | Flying insect-trapping net |
-
1989
- 1989-08-11 JP JP1208424A patent/JPH0722352B2/en not_active Expired - Fee Related
Also Published As
| Publication number | Publication date |
|---|---|
| JPH0371777A (en) | 1991-03-27 |
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