JPS58183381A - Method of sealing joint - Google Patents
Method of sealing jointInfo
- Publication number
- JPS58183381A JPS58183381A JP6622682A JP6622682A JPS58183381A JP S58183381 A JPS58183381 A JP S58183381A JP 6622682 A JP6622682 A JP 6622682A JP 6622682 A JP6622682 A JP 6622682A JP S58183381 A JPS58183381 A JP S58183381A
- Authority
- JP
- Japan
- Prior art keywords
- joint
- copper plates
- hull
- copolymer
- rubber
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63B—SHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING
- B63B59/00—Hull protection specially adapted for vessels; Cleaning devices specially adapted for vessels
- B63B59/04—Preventing hull fouling
Abstract
Description
【発明の詳細な説明】
本発明は、海水に接する船舶、海洋構造物等の外面銅板
貼り目地部のシール方法に関するものである。DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a method for sealing the joints of external copper plates of ships, marine structures, etc. that are in contact with seawater.
従来、船体の海水に接する部分の汚れ防止策として、第
1図(上面図)および第2図(断面図)に示すように、
短冊状の銅板1を絶縁層5を介して船体自体の鋼板4に
接着することが知られている。なお、第1,2図中の2
は銅板1間の目地で、通常、有機系弾性シーリング材が
用いられる。Conventionally, as a measure to prevent contamination of the parts of the hull that come into contact with seawater, as shown in Figure 1 (top view) and Figure 2 (cross-sectional view),
It is known to adhere a rectangular copper plate 1 to a steel plate 4 of the ship's hull itself via an insulating layer 5. In addition, 2 in Figures 1 and 2
is a joint between the copper plates 1, and an organic elastic sealant is usually used.
第1.2図に示す状態で航走する船体外板の銅板1は、
絶縁層3によって鋼板4と電気化学的に絶縁されている
ため、海水中では銅1のみが自然腐食によって減耗し、
第3図中1′ で示すような厚みになってしまう1.こ
れに反し目地2は有機系弾性シーリング材のため、腐食
による厚みの減耗がなく、目地2は第3図に示すごとく
、長年月の間には突起部となる3、その結果、航走時に
水中抵抗が増加し、汚れ防止による抵抗低減の本来の効
果が阻害される。The copper plate 1 of the hull outer plate sailing in the state shown in Fig. 1.2 is
Since it is electrochemically insulated from the steel plate 4 by the insulating layer 3, only the copper 1 is depleted by natural corrosion in seawater.
1. The thickness becomes as shown by 1' in Figure 3. On the other hand, since joint 2 is an organic elastic sealant, its thickness does not deteriorate due to corrosion, and as shown in Figure 3, joint 2 becomes a protrusion over many years3, and as a result, when sailing, Underwater resistance increases, and the original effect of reducing resistance by preventing fouling is inhibited.
本発明は、銅板の腐食減耗に準じて目地が減耗し、水中
抵抗を増加しない目地シール方法を提供するものである
、。The present invention provides a joint sealing method in which the joint is worn down in accordance with the corrosion wear and tear of the copper plate and does not increase underwater resistance.
すなわち本発明は、目地材として、銅板の腐食減耗に準
じて該目地材もほぼ同速度で減耗し、しかも海洋生物が
忌避する毒性を有すると共に銅板の温度変化による伸縮
緩和の柔軟性がある材料を使用して目地のシールを行う
方法に関し、上記目地材として、トリブチルチン・メタ
アクリレートあるいはトリフェニルチ/・メタアクリレ
ートなど有機スズ系共重合物又は有機スズ系共重合物を
ゴム変性して得られるものを使用することを特徴とする
ものである。In other words, the present invention uses a material that can be used as a joint material, which wears out at almost the same rate as the copper plate corrodes, has toxicity that is repelled by marine life, and is flexible enough to moderate expansion and contraction due to temperature changes of the copper plate. Regarding the method of sealing joints using It is characterized by the use of
本発明方法は、船舶、海洋構造物等に適用することがで
きる。The method of the present invention can be applied to ships, marine structures, etc.
以下、本発明方法を第1.2図に示す船体外板に適用す
る場合を例にして説明する。Hereinafter, the method of the present invention will be explained using an example in which the method of the present invention is applied to a hull shell plate shown in FIG. 1.2.
第1,2図において、銅板1の形状は特に制限はなり、
゛短冊状、正方形、その他いずれでもよいが、目地幅に
は制限がある。すなわち、目地幅が極端に狭い場合は目
地材のシール作業が困難になり、広過ぎると流木等の衝
撃によって破損しやすくなるため、通常は約1〜10I
IIIfiとする1、捷た目地2の深さは、銅板1の海
水中自然腐食減耗を想定した耐用年数で決定される。In Figures 1 and 2, there are no particular restrictions on the shape of the copper plate 1;
``It may be strip-shaped, square, or any other type, but there is a limit to the joint width. In other words, if the joint width is extremely narrow, it will be difficult to seal the joint material, and if it is too wide, it will be easily damaged by the impact of driftwood, etc., so it is usually about 1 to 10 I.
The depth of the cut joint 2, which is referred to as IIIfi, is determined based on the service life of the copper plate 1 assuming natural corrosion and wear and tear in seawater.
この目地2に充填する目地材には、有機スズ系共重合物
であるトリブチルチン・メタアクリレートあるいはトリ
フェニルチン・メタアクリレートの共重合物(以下オル
ガノ・メタリック・コポリマー−L−OMPと略す)の
単独または前髪レーヨン社製、商品名ダイヤナール)a
J*−197o )が使用できる。The joint material filled in this joint 2 is made of a copolymer of tributyltin methacrylate or triphenyltin methacrylate (hereinafter abbreviated as organo-metallic copolymer - L-OMP), which is an organotin-based copolymer. Alone or manufactured by Banga Rayon Co., Ltd., product name Dianal) a
J*-197o) can be used.
この目地材を銅板1と同じ高さまで充填する1、目地2
の材料OMPは、水中抵抗によってセルフポリ/フグ(
自己研磨)を受けて、銅1の海水中自然腐食減耗(o、
o1〜0.’ 05 mm 7年)に相当するOMPの
減耗となる。この状況を第4図に示す。また、OMPは
海水のp)(8付近で加水分解を生じ、チン・ハイドロ
オキザイドとして溶出し、防汚に極めて有効な毒物であ
る。なお、防汚に有効な溶出速度の最低値は1〜2μf
7cm2/ day であるが、ここに使用するOM
Pはこの範囲を十分に満足する。更に、とのOMPは常
温で柔軟性があり、熱応力の緩和に有効である。Fill this joint material to the same height as copper plate 1 1, joint 2
The material OMP is self-poly/puffer (
natural corrosion loss (o,
o1~0. '05 mm 7 years) is equivalent to OMP wear. This situation is shown in Figure 4. In addition, OMP is hydrolyzed in seawater at p) (around 8) and is eluted as chin hydroxide, which is an extremely effective poison for antifouling.The minimum elution rate effective for antifouling is 1. ~2μf
7cm2/day, but the OM used here
P satisfies this range. Furthermore, OMP is flexible at room temperature and is effective in alleviating thermal stress.
実施例
150 X 70 X 1w+mt軟鋼板に目地幅5咽
で、0.5+mmt 銅板を接着し、この目地部にト
リブチルチン・メタアクリレ−) (OMP)又はトリ
フェニルチン・メタアクリレートのゴム変性物(三菱レ
ーヨン社製ダイヤナールMR1970) (ゴム変性
OMP )をヘラ2回塗りで充填したものを試験片とし
、該試験片の目地部曲げテスト(試験片の目地部の裏側
に相当する部分に2o■φ棒を当て、90°折り曲げテ
スト)、常温海水浸漬テスト(6ケ月間浸漬)及び海水
中回転同船テスト(直径1ff+、周速16ノツト)を
実施した。Example 150 X 70 A test piece was filled with Dianal MR1970 (manufactured by Rayon Co., Ltd.) (rubber-modified OMP) with a spatula applied twice, and a joint bending test was performed on the test piece (2° A 90° bending test by applying a rod), a room-temperature seawater immersion test (immersion for 6 months), and a seawater rotation ship test (diameter 1ff+, circumferential speed 16 knots) were carried out.
結果は下表に示す通りであった。The results were as shown in the table below.
なお、OMP、 ゴム変性OMP 、 いずれもヘ
ラ2回塗りで作業完了することから、シール施工性は良
好ということができる。In addition, since both OMP and rubber-modified OMP can be completed with two coats with a spatula, it can be said that the sealability is good.
第1図は通常の船体外板を説明するだめの図(上面図)
、第2図はその断面図、第3図は従来の船体外板の長年
月使用後の状態を説明するための図、第4図は本発明方
法を適用した船体外板の長年月使用後の状態を説明する
ための図である1゜
復代理人 内 1) 明
復代理人 萩 原 亮 −
第3図
第4図
[・続袖正占:
昭和 57’ト 8 月 、7’−11441’ +
f’l庁1ζ信°若杉和夫殿1、°1司′1)I/、小
11B和57年特許願第66226号
2 、4h ’Jl’ 、、hと14:V 、 、、
、、7−7、ヵθ2:3 、 ?1M 41 る名
“1往Iヒンノ関係 特許出llIn人11 ゛l
東京都七代111区丸の内二ロ45番1号11 ど
(62[]) :、菱+ji[乳株人会社7補正の
対象
「図面」
8補正の内′容
(1)図面の第6図を別紙の通り訂正する。Figure 1 is a diagram (top view) to explain the normal hull skin.
, Fig. 2 is a cross-sectional view thereof, Fig. 3 is a diagram for explaining the state of a conventional hull shell plate after many years of use, and Fig. 4 is a diagram showing the state of a hull shell plate to which the method of the present invention has been applied after many years of use. This is a diagram to explain the state of 1゜Responsible agent 1) Resurgent agent Ryo Hagiwara - Figure 3, Figure 4 '+
f'l Agency 1ζ Shin ° Kazuo Wakasugi 1, ° 1 Tsukasa' 1) I/, Elementary 11B Japanese Patent Application No. 66226 2, 4h 'Jl' , , h and 14: V , , ,
,,7-7,Kaθ2:3, ? 1M 41 Name “1 out of 1 Hinno-related patent issuer llIn person 11 ゛l
45-1-11, Marunouchi 2-ro, Nanadai 111-ku, Tokyo amended as shown in the attached sheet.
Claims (1)
方法において、該目地部に有機スズ系共重合物又は有機
スズ系共重合物をゴム変性したものを充填することを特
徴とする目地/−シル方法A method for sealing the joints of external copper plates of ships, marine structures, etc., characterized in that the joints are filled with an organic tin-based copolymer or a rubber-modified organic tin-based copolymer. -Sill method
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP6622682A JPS58183381A (en) | 1982-04-22 | 1982-04-22 | Method of sealing joint |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP6622682A JPS58183381A (en) | 1982-04-22 | 1982-04-22 | Method of sealing joint |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| JPS58183381A true JPS58183381A (en) | 1983-10-26 |
Family
ID=13309708
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP6622682A Pending JPS58183381A (en) | 1982-04-22 | 1982-04-22 | Method of sealing joint |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JPS58183381A (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US4987036A (en) * | 1988-06-02 | 1991-01-22 | Seamark Systems Limited | Marine antifouling |
-
1982
- 1982-04-22 JP JP6622682A patent/JPS58183381A/en active Pending
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US4987036A (en) * | 1988-06-02 | 1991-01-22 | Seamark Systems Limited | Marine antifouling |
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