NL9201387A - Method and device for preserving paper documents and books - Google Patents

Abstract

The invention relates to a method for preserving (conserving) archivalia (archive material) by bringing the archivalia to be preserved into substantially permanent contact with a gas- or vapour-forming deacidifying agent (deacidifier), the deacidifying agent being selected from the group consisting of ammonia, morpholine, cyclohexylamine carbonate. The archivalia are brought into contact with the gases or vapours formed by the deacidifying agent by the archivalia being placed in a gastight container at the bottom of which a reservoir with deacidifier is located. The invention further relates to a device for implementing the method.

Description

METHOD AND APPARATUS FOR CONSERVATION OF PAPER DOCUMENTS AND BOOKS

The present invention relates to a method and device for the preservation of paper documents and books, hereinafter referred to as archival materials.

Currently, archives and libraries around the world are destroying documents and books because the acidity of the paper increases (with a decrease in pH) that the paper cellulose breaks down, causing the paper to lose its consistency and become unmanageable.

The cause of this acidification process must be sought in the invention of mechanical papermaking around 1800. For the so-called gluing of the paper web to be formed, it appeared that the use of resin alum was necessary. Gluing is necessary because unglued paper acts as blotting paper and is therefore indescribable.

Before 1800, for gluing handmade paper, the finished sheets were dipped in a gelatin solution and then dried. In retrospect, resin alum gluing proved to have the major drawback that sulfuric acid is split off. This sulfuric acid has a destructive effect on cellulose, the main raw material of paper, while gelatin did not have this drawback.

In the 19th century, the demand for paper became so great that the available quantity of rags as a source of cellulose became insufficient. From about 1850, other sources of cellulose, such as all kinds of wood, were found, which were removed from the non-cellulose components, such as lignin and hemicellulose, by aggressive cooking processes. Lignin causes the paper to brown. However, these treated cellulosics are more sensitive to acidification than cellulose from linen and cotton rags since they have already been affected quite severely by the cooking processes.

Various methods have already been developed to neutralize the acids found in acidic archives. Aqueous solutions of calcium bicarbonate, magnesium bicarbonate and calcium hydroxide are very suitable for this.

Unfortunately, wet paper loses an important part of its strength, which can be disastrous for archives that are already in poor condition. Another drawback is the fact that, in the case of aqueous deacidification of books, the entire book must be disassembled, after which each page must be deacidified and dried, before it can be bound again into a book. These manual operations greatly increase costs.

A deacidification method that does not have these drawbacks is processing with the indirect acting diethyl zinc gas (DEZ). This deacidification method, known as the DEZ method, is based on the property of DEZ to decompose in contact with a small amount of moisture in the paper into ethylene gas and zinc oxide (ZnO), which binds the acids. In order to form a so-called alkaline reserve in the paper, the ZnO is converted into zinc carbonate with carbon dioxide. This buffer is necessary to neutralize any acids formed later, for example by acid rain.

Since at the natural equilibrium moisture content of paper (8-10% at 65% relative humidity) the DEZ can cause an explosion, the paper must be pre-dried to the lowest possible moisture content. However, this small residual amount is already sufficient to decompose the DEZ into zinc oxide and ethane.

In recent years, a number of deacidification tests of books with DEZ have been carried out under the responsibility of the Library of Congress (LOC, United States). For the pre-drying of the books, the impregnation in vacuum with DEZ gas, the conversion of the formed zinc oxide with CO2 into zinc carbonate and finally for the DEZ-free rinsing of tanks and books, large NASA vacuum tanks were used. These tests have seen a number of explosions in recent years, which have put the DEZ process in an unfavorable light. Later, the project was transferred to Texas-Alkyls (AKZO) who made a number of improvements that would reduce the chance of explosions. J.C. Thomson, in his publication "Mass-deacidification; Thoughts on the Cunha report", Restorator 9, number 3 (1988), p. 147-162, however, still many disadvantages of the process. It is likely that the DEZ process in Europe has little chance of success, because the processing will have to take place in one central deacidification company. This naturally entails a large number of logistical problems. In addition, in general, librarians and archivists would prefer to carry out the deacidification process in-house.

Another method of non-aqueous deacidification uses the chemical compound methyl methoxymagnesium carbonate (MMMC) dissolved in a mixture of methanol and Freon-113. The latter is known as CFC and affects the ozone layer. The use of CFCs will therefore soon be prohibited. The process is described in U.S. Pat. U.S. Patent 4,318,963. The action of MMMC is based on its ability to decompose as soon as it comes into contact with water, which is normally present in paper in an amount of 8-10%. This produces magnesium hydroxide and magnesium carbonate, which neutralize the acids in the paper and form what is known as an alkaline reserve. Freon's low boiling point of 40 "C makes an MMMC solution suitable for spraying with a spray gun (called" soft spray method "), which forms a fine mist. As soon as it comes into contact with the paper surface to be deacidified, the MMMC decomposes into its components. In this way, besides flat documents, books can also be deacidified by spraying sheet by sheet. It is clear that this is a very laborious method and unsuitable for mass deacidification.

Mass deacidification of books means deacidification by means of an deacidification liquid and then drying a large number of books and / or documents at the same time, for example in a tank. In indirect processes, such as with DEZ and MMMC, the books must first be pre-dried to the lowest possible moisture content, as otherwise the deacidification liquids will decompose first at the side edges of the book and cause an uneven pH distribution. Cellulose now contains 2 to 3% retained water that cannot be removed even in deep vacuum above 100 ° C. Pre-drying to absolute dryness is therefore impossible and it does not seem likely that deacidification processes requiring the paper to be pre-dried will be very successful. For flat documents that are never pre-dried, the spray forms an alkaline jelly-like layer with a high concentration of magnesium carbonate and magnesium hydroxide and a high pH.

Own tests, in which the books were pre-dried and then immersed in an MMMC solution, showed that the deacidification of the sheets was uneven, although the penetration of the solvent was good. The pH measured over the leaf was therefore uneven (Table 1).

TABLE 1 pH distribution over the pages before and after impregnation of a closed book by means of the MMMC method.

UNTREATED IMPREGNATED IMPREGNATED

AND DRIED AND DRIED

a.d. AIR UNDER VACUUM

It is clear from table 1 that only the edges of the> leaf are well neutralized, but the middle part is not. This is probably because the small amount of taped water of 2 & 3% that remains in the paper after pre-drying is already sufficient to decompose the MMMC as soon as its solution comes into contact with the paper, ie at the edges.

Other problems that can arise when impregnating books with MMMC solutions and generally with organic solvents are: softening of certain glues, discolouration of pressure and graphics and extraction of brown discoloration. Another problem is the fact that until now it has not been possible to remove the last residues of methanol from the paper, even in deep vacuum, which causes the treated books to 'stink' on storage.

From the above it can thus be concluded that solutions of MMMC in organic solvents are also unsuitable for mass deacidification of books.

The object of the present invention is to provide a method and apparatus for preserving archival materials by mass deacidification, thereby avoiding the above-outlined problems.

This is achieved by the invention by substantially permanently contacting the preservatives to be preserved with a gas or vapor-forming deacidification agent.

Preferably, the gas or vapor-forming deacidification agent is selected from the group consisting of ammonium bicarbonate, ammonia, morpholine, cyclohexylamine carbonate. In particular ammonia gas that develops from ammonia, this is a 25% solution in water. Most preferred is ammonium bicarbonate. Since this is a solid which slowly secretes ammonia, there is no problem with the moistening of the archives and the predominant ammonia odor is also avoided.

Said deacidification agents are already known per se. The difficulty is that the acids that cause paper decay are strong acids and can only be neutralized with strong bases. However, the above-mentioned gaseous bases are weak, so that the action is only of short duration. However, by now keeping the archives substantially in permanent contact with the deacidification agent, a permanent neutralization is achieved.

The invention further provides an apparatus for carrying out the method comprising a gas-tight container, a deacidification agent reservoir and a gas-permeable partition between the reservoir and the preservatives of the archives.

The archives are stored, for example, in gastight cardboard archive boxes, in which the powdered ammonium bicarbonate or a layer of foam rubber impregnated with 25% ammonia or morpholine is placed on the bottom. Above it is a metal grid on which the books rest. There may be a pH indicator in or on the archive box to indicate the concentration of the deacidification agent.

The present invention is illustrated by means of the accompanying figure, in which a partly broken away perspective view of an embodiment of a device according to the invention is shown.

A filing box 1, for instance made of gastight cardboard, contains a layer of foam 2. The foam is impregnated with deacidifying agent and is covered by means of a preferably metal grid 3. On the grid are the books to be treated 4. In the lid has a pH indicator 5 included.

Experimental treatments have shown that the books are impregnated with the neutralizing gas within a few hours and that the pH distribution over the sheet is good (Table 2).

TABLE 2 pH distribution over the pages before and after treatment according to the invention

NOT TREATED TREATED

It is possible to use the archives during storage. However, after impregnation and before use, the objects must be degassed in the air or in a forced air flow. In this condition, the blades remain neutral for several weeks (pH about 7.0). After this they have to be placed back in the archive boxes.

The gas deacidification described above can be permanent or temporary, for example when the archives are selected for a neutralizing liquid impregnation, which provides a permanent deacidification. Until then, it is possible with the aid of the present invention to stop the decay of the paper in a simple and relatively inexpensive manner. The method can also be carried out in any archive and requires no expensive installation and little or no extra space.

Claims (14)

1. A method for the preservation of archival materials, by substantially permanently contacting the archival materials to be preserved with a gas- or vapor-forming degreaser. Process according to claim 1, characterized in that the deacidification agent is selected from the group consisting of ammonium bicarbonate, ammonia, morpholine, cyclohexylamine carbonate. Method according to claim 1 or 2, characterized in that the archives are brought into contact with gases or vapors formed by the deacidification agent by placing the archives in a gastight container, on the bottom of which is a reservoir with deacidification agent. . A method according to claim 3, characterized in that the deacidification agent in gaseous or vapor form is released through a layer of a porous material impregnated with the deacidification agent. A method according to any one of claims 1-4, characterized in that the archives are first degassed for use for a desired purpose. Method according to claim 5, characterized in that degassing takes place in the air. Method according to claim 5, characterized in that degassing takes place in a forced air flow. Apparatus for carrying out the method according to any one of claims 1-7, comprising a gastight container, a deacidification agent reservoir and a gas-permeable partition between the reservoir and the archives to be preserved. Device according to claim 8, characterized in that the container is a gastight cardboard archive box. Device according to claim 8 or 9, characterized in that the deacidification agent reservoir is a layer of porous material. Device according to claim 10, characterized in that the porous material is foam rubber. Device according to any one of claims 8-11, characterized in that the gas-permeable partition is formed by a grid of inert material. Device according to claim 12, characterized in that the inert material is an inert metal. Device according to any one of claims 8-13, characterized in that the device is provided with a pH indicator.