DE2046224C3 - Durable melamine / formaldehyde resin solutions and processes for their manufacture - Google Patents

Description

The invention relates to a method for the production of melamine / formaldehyde resin solutions good storage stability.

It is known to produce melamine / formaldehyde resin solutions by adding an aqueous formaldehyde solution, their pH is brought to a value between 7.5 and 9.5 with the help of a lye or soda solution has been mixed with melamine and possibly water and the mixture by heating lets react to a temperature between 85 ° C and the boiling point. The condensation reaction will then continued until the desired degree of condensation has been achieved, taking the fact into account it has to be borne in mind that the reaction continues for a moment while the reaction mixture cools down persists.

The water tolerance is usually used as a measure of the degree of condensation, in this case expressed as the percentage by weight of solids to which the resin solution is used to produce a permanent Phase separation must be diluted. The water tolerance depends on the temperature and is mostly measured at 20 ° C.

Storage stability or shelf life of a resin solution is to be understood here as the time in which the Solution remains clear and no noticeable change in properties, e.g. B. shows an increase in viscosity.

Resin solutions with a storage stability of a maximum of three weeks can only be produced with the above-described method. This optimal shelf life of 21 days can only be achieved with a condensation up to one exactly realize a certain degree of condensation at a certain pH. The difficulty with this is the response just to finish at the right moment, so that the ultimately accumulating, cooled resin solution just has the desired degree of condensation.

A storage stability of 2 to 3 weeks is for the resin manufacturing companies that produce the resin themselves do not process, but send on to their customers, too little.

A known measure to avoid this difficulty is spray drying of the Resin solution; However, this is associated with the disadvantage that the manufacturer and customer must take special precautions have to meet. It is also known to add one or more modifiers to the resin solution, which increase the storage stability. Various compounds are already used as modifiers have been proposed e.g. B. cyclic lactams (Belgian patent 707485), alkanolamines (Belgian Patent 683104), aliphatic alcohols with less than 6 carbon atoms, together with a sulfamic acid salt (German patent specification 1158705), N-methylolsulfonamide with α-alkyl-D-glucoside (American patent 3082180).

For certain applications, however, it is less desirable that such "non-resinous" modifiers are present in the resin solution. In the manufacture of high pressure laminates with a made of phenolic resin Soaked soda kraft paper core, for example, may have the presence of such a modifier bring about a reduction in surface hardness, while the presence of a photosensitive Modifier can lead to the fact that using a very light colored decorative paper Laminates produced show yellowing on aging. It also increases the addition of modifiers mostly the cost price.

The object of the invention is to provide a process for the production of resin solutions with good storage stability without using substances as modifiers that are "alien to the resin".

This object is achieved by the method characterized in the patent claims.

To obtain a highly condensed resin suitable as a modifier, formaldehyde is left in

so and melamine, e.g. B. in a molar ratio of 2: 1, react in a basic aqueous medium until a water compatibility between 40% solids, measured at 20 ° C, and 53% solids, measured at 100 ° C, has been achieved. This is a 30 weight percent Formaldehyde solution in water, which contains about 1.5 wt .-% methanol, first with a Lye or soda solution to a pH value between 8.5 and 9.5, preferably to a pH value brought from 9.2. Then the desired amount of melamine is added and the solids content of the Reaction mixture brought to 50 to 53% by adding demineralized water. Afterward the reaction mixture is heated until the desired degree of condensation has been achieved.

The highly condensed resin obtained in this way is used in an amount of 5 to 20% by weight of the The resin present in the final phase is mixed with the reaction mixture from the main batch and on

also condensed.

This addition can be made before the start of the condensation of the main batch or during this condensation take place and then preferably within 30 minutes after the start of the reaction. It is also possible, first produce a small amount of highly condensed resin in the reactor, then the reactants for the main batch and then to initiate the condensation of the main batch.

A resin solution prepared in this way has a water compatibility between 38 and 36% solids, measured at 20 ° C, a storage stability of four to five weeks.

With the method according to the invention, it is therefore possible to produce resin solutions that are very durable can be produced, even without the addition of known "non-resin" modifiers.

It also appears that the condensation reaction is now less critical. Has a resin solution namely in general their optimal storage stability, in combination with good processing properties, at a certain degree of condensation (expressed as water tolerance) or in an area between water tolerances of a certain size, hereinafter referred to as the area of technical to designate usable water tolerances.

In normal melamine / formaldehyde resin production this area becomes, if the reaction takes place at a temperature of about 95 ° C, run through quickly. In this case, it is difficult to stop the reaction at the right moment. Will the reaction is carried out at 85 ° C, then the area is run through more slowly, the whole reaction However, it takes too much time.

When using the measure according to the invention and a reaction temperature of 95.degree the area of technically feasible water tolerances is traversed much more slowly, while the whole reaction does not take more time than with the normal procedure.

There is also the fact that the area in question is considerably broader with the new process, at least with respect to the water compatibilities at which stable resin solutions are obtained.

A further improvement in storage stability can be made in cases where the processing properties are not adversely affected, can be achieved by also adding a small amount of one known modifier, e.g. B. a mixture of o- so and p-toluenesulfonamide or butanol, adds. This Addition can e.g. B. take place 15 minutes after admixture of the highly condensed resin, in an amount of about 2% by weight of the main batch. However, both the time of addition and the amount used are not very critical.

The invention will now be explained using the following examples.

It turns out that a resin solution prepared without any modifier (comparative experiment 1) has a shelf life of 2 to 3 weeks and a resin solution prepared with a known modifier (comparative experiment 2, with n-butanol as modifier) can be stored for 3 to 4 weeks. In both examples, the time in which the reaction passes through the area of technically feasible water tolerances is 15 minutes.
It can be seen from the examples that resin solutions which have been prepared according to the invention using highly condensed resin as a modifier have a shelf life of 4 to 5 weeks if no other known modifier has been added (Example 1), and a shelf life of 4 to even 8 weeks if, in addition to the highly condensed resin, another modifier, e.g. B. n-butanol (Examples 2 and 3) or toluenesulfonamides (Examples 4 and 5) has been added. The field of technically useful water tolerances is covered in these examples in 30 minutes.

Comparative experiment 1

Preparation of a melamine / formaldehyde resin solution without any modifier.

In a reactor equipped with a stirrer, reflux condenser, heating mantle and thermometer, 200 parts of a 30 percent strength by weight aqueous formaldehyde solution are brought to a pH of 9.0 with the aid of 1.57N sodium carbonate solution. 126 parts of melamine and 26 parts of water are then added so that the solids content of the mixture is 53%. The mixture is allowed to react at 95.degree. The resin solution formed has reached its maximum shelf life of 21 days after a reaction time of 115 minutes »; the water compatibility measured at 20 ° C. (a measure of the degree of condensation) is then 27.1%, expressed as percent by weight of solids to which the resin solution has to be diluted with water to bring about permanent phase separation. A shelf life of 14 days is possible through at a Wasserverträgiichkeit 23.5 to 29.8% solids as measured at 2O ⁰ C. This range 23.5 to 29.8% during the reaction in 14 minutes.

Comparative experiment 2

Production of a resin solution modified exclusively with butanol.

200 parts of 30 percent strength by weight commercial aqueous formaldehyde solution are placed in a reactor mixed with a pH of 9.0, 126 parts of melamine, 12 parts of water and 6 parts of n-butanol. One lets the mixture react at a temperature of 95 ° C until a water tolerance between 24 and 30% solids, measured at 20 ° C, has been reached.

The range between 24 and 30% is run through in 15 minutes.

The storage stability of the resulting resin solution is 3 to 4 weeks.

Example 1 ■

Production of a melamine / formaldehyde resin solution modified with highly condensed resin.

In a reactor described in Comparative Experiment 1, 200 parts are 30 percent by weight The formaldehyde solution was brought to a pH of about 8.7 with the help of 1.57N soda solution. Afterward 126 parts of melamine and 12 parts of demineralized water are added and the temperature is increased to the boiling point of the mixture. The condensation continues until water compatibility, measured at 100 ° C, reached 55% has been. During the cooling phase, a phase separation occurs with about 30% liquid and 70% of the substance behaving as a solid was obtained

will. This solid can be used as a modifier for several weeks.

The main batch is made from 200 parts of 30 weight percent formaldehyde solution with a pH of 9.2.126 parts of melamine and 26 parts of demineralized water. The condensation reaction takes place at 95 ° C. About 15 minutes after the start of this condensation, 14 parts of the first Part of this example described, far through condensation resin is added (only the solid substance is used). The whole thing is condensed further until a water tolerance of 36-38% solids, measured at 20 ° C, has been reached. This area between 36 and 38% will be within 30 minutes run through. The shelf life of the resulting resin solution is 4 to 5 weeks.

Example 2

Production of a melamine-formaldehyde resin solution modified with highly condensed resin and butanol.

In a reactor, as described in comparative experiment 1, 200 parts of 30 weight percent formaldehyde solution, which has been brought to a pH of 9.0 _{with 1.57-H-Na 2} -CO _{3 solution, are placed.} Then 126 parts of melamine and 25 parts of demineralized water are added. The mixture is condensed at the boiling point until a water compatibility of 41% solids, measured at 20 ° C., has been reached.

In the main reactor 960 parts are 30 weight percent Formaldehyde solution with a pH of 9.0, 750 parts of melamine and 224 parts of demineralized Water introduced. 39 parts of n-butanol are added as a modifier. The condensation reaction takes place at 95 ° C. About 15 minutes after the start of the reaction the condensate obtained in the first part of this example is pumped into the main reactor. The whole condensation is continued until a water compatibility of 24.5-28% solids, measured at 20 ° C., is reached has been. This area between 24.5 and 28% is traversed within 30 minutes. the The resulting resin solution has a shelf life of 4 to 5 weeks.

Example 3

Production of a resin solution modified with highly condensed resin and butanol.

In a small reactor, 100 parts of 30 weight percent commercial aqueous formaldehyde solution are added with a pH of 9.0, 63 parts of melamine and 12.5 parts of water mixed. The mixture is left react at boiling point until a water tolerance of 53% solids, measured at 20 ° C has been reached.

960 parts of 30 percent by weight are mixed in the main reactor Commercial aqueous formaldehyde solution with a pH of 9.0, 756 parts of melamine, 224 parts of water and 40 parts of n-butanol. The mixture is allowed to react at 95 ° C. and 15 minutes are added after the start of the reaction, add the resin solution prepared in the small reactor.

The reaction is continued until a resin solution is obtained which, after cooling, is water-tolerant between 23.5 and 26.5% solids, measured at 20 ° C. This area between 23.5 and 26.5% is run through in 30 minutes. The storage stability of the resulting resin solution is 5

ίο up to 6 weeks.

Example 4

Production of a resin solution modified with highly condensed resin and toluenesulfonamide.

200 parts of 30% strength by weight commercial aqueous formaldehyde solution are added to the reactor a pH of 9.0, 126 parts of melamine and 25 parts of demineralized water. the Temperature is brought to 95 ° C .; the reaction is continued until a water tolerance of 53%, measured at 20 ° C, has been reached.

1000 parts of 30% strength by weight commercially available aqueous formaldehyde solution with a pH of 9.0, 630 parts of melamine and 125 parts of water are then metered in. The reaction is continued at 95 ° C. and 39 parts of a mixture of ortho- and paratoluoisulfonamide are added to the reaction mixture 15 minutes after the main batch has been added.
The reaction is ended when a water compatibility between 36.5 and 40% (at 20 ° C.) is reached. This range between 36.5 and 40% is passed through within 20 minutes. The storage stability of the resulting resin solution is 5 to 6 weeks.

Example 5

Production of a resin solution modified with highly condensed resin and toluenesulfonamide.
In a small reactor, 100 parts of 30 weight percent commercially available aqueous formaldehyde solution with a pH of 9.0, 63 parts of melamine and 12.5 parts of water are mixed. This mixture is allowed to react at a temperature of 95.degree. C. until a water compatibility of 46% solids, measured at 20.degree. C., has been reached.

In the main reactor, 960 parts of 30 weight percent commercial aqueous formaldehyde solution are mixed with a pH of 9.0, 756 parts of melamine and 224 parts of demineralized water. You leave that Mixture react at 95 ° C and 15 minutes after the start of the reaction adds the one obtained in the small reactor Resin solution too. About 30 minutes after the start of the reaction, 39 parts of a mixture are added from ortho- and paratoluoisuifonamide. The reaction is continued until the resin solution after cooling has a water compatibility between 31 and 35% solids, measured at 20 ° C. This area between 31 and 35% solids is run through in 30 minutes. The storage stability of the accruing Resin solution is 5 to 8 weeks.

Claims (3)

Patent claims: 1. Process for the production of melamine / formaldehyde resin solutions with good storage stability, characterized in that before or during the in the usual way at a pH between 7.5 and 9.5 performed resin condensation the reaction mixture a highly condensed Melamine / formaldehyde resin, which has a degree of condensation - expressed as the percentage by weight of solid, to which the resin solution has to be diluted with water to bring about a phase separation - which has between 40% solids, measured at 20 ° C, and 53% solids, measured at 100 ° C, and that by condensing a lye or soda solution to a pH value between 8.5 and 9.5 adjusted 30% by weight aqueous formaldehyde solution containing about 1.5% by weight of methanol has been made with melamine, in an amount of 5 to 20 wt .-% of that in the End phase resin present, and optionally a small amount of butanol or a mixture of ortho- and paratoluenesulfonamide is added. 2. The method according to claim 1, characterized in that the highly condensed resin within 30 minutes after the start of the main condensation reaction to the reaction mixture is added. 3. Melamine / formaldehyde resin solutions according to the method according to any one of the preceding claims.