紙パ技協誌 34 巻, 5 号

海外技術ニュース

クラフトパルプ工場全体の操業の経済性に及ぼす苛性化システムの重要性を考えると, ここで往々共通的に発生する操業上の問題点を解決することにより, 容易に工場全体の操業効率を高めることができる。この記事は, 苛性化工程でしばしば経験される諸問題, それら諸症状, ならびに解決法等について述べたものである。

乾燥機を組合せた流動層炉による廃水汚泥の焼却処理

The fluidized bed incineration plant has been installed at Katsuta Mill for burning the total quantity of sludges generated.
This plant consists of a fluidized bed incinerator and a rotary dryer. The key point of this system is the savings of energy or fuel oil use.
It has been on stream from May 1979, and now under satisfactory conditions. Autogeneous incineration has been achieved.

工場紹介 (21)

Mishima Paper Co., established in 1918, is now composed of a head office (Tokyo), two mills (Harada and Suita) and a research institute.
Harada Mill, which we are going to introduce here, is on the outskirts of Fuji City well-known for its fine view of national adoring mountain, and the other is in Suita City where the world famous EXPO 70 was once held.
In and around Harada district, people have been long blessed with an abundance of clean spring water, and that is why our predecessors first had a thought of founding there a mill for the purpose of manufacturing cigarette-paper more than 60 years ago …… unknown technology as it was in those days. Ever since Harada Mill has continued to produce various kinds of high grade paper, most of which are light-weight, to enrich daily life or expedite business, and now holds the paramount position in the field of making specialty paper.
The mill area is about 100, 000m² and the employees are nearly 450. The main products are as follows :
For cigarette use …… cigarette-paper, tipping or wrapping paper, etc.
For business use ………… copying, typing, bond, instruction or contract, pocket note-book, etc.
For other special use …… India used to dictionary, water dissolving, various kinds of converted paper, etc.

リグニンの水溶性化に関する研究 (1)

水溶性クラフトリグニンの製造を目的として, 酸化剤-サルファイト処理による, リグニンモデル化合物のスルホン化反応機構, および本反応に対するクラフトリグニンの反応性について検討した。その結果, 本反応によってクラフトリグニンがほぼ完全に水溶性化し得ること, およびそれがクラフトリグニン中の主としてカテコール構造およびα-カルボニル基を有しないグアイアシル構造のフェノール性水酸基の隣接位に対するスルホン化反応に基づくと考えられることが明らかになった。

中性サルファイト法高収率パルプの紙質に及ぼすリファイニング温度の影響

Neutral sulfite precooked birch chips were refined in the Asplund Laboratory Defibrator (type D) at various temperatures (20°C, 120°C and 180°C). The effects of refining temperatures on the physical property and morphological structure of the resulting pulps were discussed.
The effect of refining temperature on the sheet property depends largely on the precooked yield. Regardless of any refining temperatures, unbeaten pulp fiber prepared from precooked chip of 84% yield was a little peeled off by partial fibrillation rather than intercellular cutting. The secondary wall and the compound middle lamella were observed on its surface at same time. There was recognized no distinct difference in fiber length distribution and its morphological structure between unbeaten and beaten pulps. At same sheet density, pulp from open discharge refining had better sheet strength as compared to pressurized refining, because pulp from the former had much amounts of fines with higher water retention value than the latter.
In the case of pulp prepared from precooked chip of higer yield (94%), refining temperature affected remarkably fiber length distribution and surface characteristic of pulps. Pulp fiber refined at 20°C was damaged heavily, and its surface was mainly covered by the secondary wall. On the other hand, fiber surface produced at pressurized refining was smooth and covered by the compound middle lamella. Sheet strength increased linearly as sheet density increased, regardless of any refining temperatures.
It would be concluded that the sheet strength of higher precooked yield (94%) pulp depends only on sheet density, while that of lower precooked yield (84%) pulp on the property and content of fines in addition to sheet density. Exposure of the secondary wall on fiber surface had no relation to the sheet strength directly.

紙のZ方向における圧縮特性

The present paper deals with the theoretical consideration on the relations between sheet density, pressure, and Z-direction compressive modulus of paper. It is assumed that paper as a non-homogeneous substance consists of voids and pulp fibers which are distributed homogeneously. A new concept of total interfiber contact area, on which stress effectively acts, under compressed conditions can be introduced into the relation between sheet density and pressure. The total interfiber contact area is expressed by the product of the number of contact points between pulp fibers per unit volume, and the mean contact area at a contact point. When the pressure applied to a sheet is low, the voids are reduced while the pulp fibers are not deformed : the number of contact points increases with increasing pressure while the mean area of contact does not change. When the compressive pressure applied to a sheet is high, the pulp fibers are deformed : the number of contact points shows a saturated value while the mean contact area increases with increasing pressure. On the assumption mentioned above, the relations between applied pressure, sheet density, and Z-direction compressive modulus were derived theoretically. A correlation between the theoretical and experimental results on the handmade papers was satisfactory over a wide range of pressure.

板紙の圧縮強さ試験における機差の検討について

The compressive strength (ring crush) of paperboard is an important property to estimate the compressibility of box and therefore the ring crush in cross direction has been specified in the Japanese Industrial Standard of linerboard and corrugating medium. At present, compression testing apparatus by beam type are generally used to measure ring crush strength, however, this method has been a subject of discussion for a long time because of their instrumental errors of more than 10 percent.
Under the circumstances, the Linerboard Technical Committee of Japan Paper Association studied the factors of these errors, making comparison of the data obtained with the use of the beam type and strain gauge type of apparatus The result was that among many factors the level of parallelling of the upper and lower compression platens with each other had a most significant effect on the errors. As for the strain gruge type of apparatus we used, they turned out to be poorer in preciseness than well-cared beam type ones. The reason seems to be that we used the type mainly designed for measuring tensile strength. However, it is considered that a strain gauge type is essentially superior to a beam type in terms of instrumental precision. We expect that a special type of strain gauge testing apparatus will be developed to measure the ring crush.