NL8400322A - FORMALDEHYD BINDING AGENTS, METHODS FOR PREPARING THE SAME, METHODS FOR MANUFACTURING BOARD, AND MANUFACTURE MADE BY THESE METHODS. - Google Patents

Description

: N.0. 32274 1

Formaldehyde binder, methods of preparation thereof, methods of board manufacture, as well as board made by these methods »__

Board such as particle board, chip board and the like are made of lignocellulosic materials using adhesives. The preferred adhesives (or adhesives) are based on formaldehyde, such as urea-formaldehyde, melamine-form-5-aldehyde, phenol-formaldehyde and resorcinol-formaldehyde resins or mixtures thereof. It is a known fact that board made using these adhesives has a formaldehyde odor which is both harmful and unpleasant. Formaldehyde is emitted both during the manufacture of such a board and during its storage and end use.

Many methods of avoiding formaldehyde emission have been proposed, but all are either ineffective or reduce the properties of the board or require complex application methods. Some of these methods involve spraying or spreading the warm board exiting the press with various solutions, such as solutions of urea and / or ammonia or ammonium salts. In general, these types of methods are not desirable for industrial application because they require additional process steps and in any case are not very efficient.

Other methods involve the use of very complex mixtures of a wide variety of ingredients, some of which are natural adhesives. These products are therefore also not very efficient. One disability is the fact that the properties of natural products are not constant.

Another way of reducing the content of free formaldehyde involves the use of an aqueous suspension of urea granules coated with a special wax. This method also requires a separate supply line, because the product is not added to the adhesive formulation itself.

An object of the present invention is to provide a formaldehyde binder, which effectively reduces the formaldehyde odor without reducing the properties of the board, without changing the reactivity of the adhesive formulations and without requiring additional steps in the manufacture of particle boards , consisting of three or more layers of wood or furniture board.

The invention provides a formaldehyde binder, which contains 8400322? Use in a board made of lignocellulosic materials using formaldehyde-based adhesives, a solution containing (a) at least one organic hydroxyl compound with the exception of 5 ^ 1-4 monovalent aliphatic alcohols and (b) at least one amide in water. The formaldehyde binder may also contain (c) an organic compound, which acts as a solvent for (a) and (b) and also reacts with formaldehyde and / or (d) a water-soluble inorganic compound. The organic compound (c) is preferably a monovalent aliphatic alcohol. The inorganic compound (d) is preferably a halide salt. Even if the individual components are not water soluble, they can dissolve in water when a mixture thereof is heated to 70 ° C in water.

Preferably, the organic hydroxyl compounds [component (a)] are soluble in water or in small monovalent aliphatic alcohols. Preferred examples of such hydroxyl compounds are the divalent, trivalent and pentavalent alcohols containing up to 6 carbon atoms, the monosaccharides containing up to 6 carbon atoms, the disaccharides containing up to 12 carbon atoms and the polysaccharides having a Ostwald viscosity up to 200 mPas at 25 ° C and a concentration corresponding to a refraction of 37%. Other preferred examples of hydroxyl compounds are the aromatic alcohols and phenols, which are preferably alone or in combination with one or more of the above divalent, trivalent and / or pentavalent alcohols and / or monosaccharides, disaccharides and / or polysaccharides being used.

The phenols and aromatic alcohols can be monovalent or polyvalent phenols or monovalent or polyvalent aromatic alcohols containing one benzene ring.

Specific examples of suitable organic hydroxyl compounds are monoethylene glycol, diethylene glycol, glycerol, pentaerytriotol, fructose, mannose, sorbitol, dextrose, sucrose, maltose, lactose, dextrin, phenol, resorcinol, hydroquinone and the like.

Preferably, the amides [component (b)] used in the formaldehyde binder of the invention are also soluble in water or small monovalent alcohols. Especially preferred are the aliphatic amides containing up to 6 carbon atoms and the aromatic amides containing one benzene ring.

Suitable examples of amides are urea, thiourea, formamide, 8400322 acetamide, benzamide, oxamide, succinamide, malonamide and the like.

If desired, to increase solubility, the formaldehyde binder of the invention may additionally contain additives [component (c)] which are small monovalent aliphatic alcohols such as methanol, ethanol, isopropanol and the like.

A cheaper and more effective formaldehyde binder is obtained when inorganic compounds [component (d)], which are preferably halide salts, more preferably halides of alkali or alkaline earth metals, such as sodium chloride, potassium chloride and calcium chloride.

The ratio of organic hydroxyl compound [component (a) and component (c), if any] and inorganic compound [component (d), if any] to amide [component (b)] is preferably 10: 100 to 400: 100, in especially 10: 100 to 200: 100, based on 15 weight. The formaldehyde binder of the invention can be added to the conventional adhesive formulations in amounts ranging from 1 to 10%, preferably 3 to 7 Z, solids of the formaldehyde binder, based on the weight of the liquid resin, which are 65 wt. .% solids of the resin.

20. The formaldehyde binder of the invention may contain 20 to 80% by weight, preferably 50 to 70% by weight, of active ingredients [components (a) and (b) and components (c) and / or (d), if present]. The water content of the formaldehyde binder depends on the solubility of the active ingredients and the amount of water that can be admitted into the adhesive formulations.

The formaldehyde binder of the invention can be prepared by simply adding the active ingredients and water to a mixer and mixing until the active ingredients are dissolved.

This can be performed at room temperature or at an elevated temperature of up to 70 ° C.

The formaldehyde binder of the invention can be used whenever manufactured from lignocellulosic materials using formaldehyde-based adhesives such as urea-formaldehyde, melamine-formaldehyde, phenol-formaldehyde or resorcinol-formaldehyde resins or mixtures thereof is becoming.

When using the formaldehyde binder of the invention, it is possible to produce board which actually contains less than 10 mg of free formaldehyde per 100 g of dry board as determined by F.E.S.Y.P. (Fédération Europêenne des Syndicate des Fabricants de 40 Panneaux de Particules) perforator method No. EN 120.

8400322 4 ï * ♦

The amount of free formaldehyde reduction depends on many factors and can therefore vary widely. When the emission of free formaldehyde is large (greater than 50 mg of formaldehyde per 100 grams of dry board), the reduction can be 60 to 85%. When the emission of free formaldehyde is relatively low, i.e. 20 to 50 mg of free formaldehyde per 100 dry board, the maximum reduction is usually 50 to 60%. The amount of reduction obtained also depends on the amount of formaldehyde binder used: the more formaldehyde binder used, the lower the amount of free formaldehyde.

When the active ingredients of the formaldehyde binder are used together, the reduction of free formaldehyde is surprisingly much higher than the sum of the effects of the individual ingredients and they do not adversely affect the reactivity of the adhesive formulation or the properties of the board.

The following examples illustrate the invention. Parts and percentages are by weight.

Example I

In this example, the organic compound containing hydroxyl groups is glycerol and the amide is urea. Herein, the synergistic behavior of these two compounds is explained. Different adhesive formulations are prepared and each is then used to make particle board.

The control did not contain all the components of the formaldehyde binder of the invention. Sample 1 contains both glycerol and urea, Sample 2 contains only glycerol, and Sample 3 contains only urea.

It can be seen from the tables below that glycerol, when used alone (sample 2), is a highly effective formaldehyde binder, but urea (sample 3) gives poorer formaldehyde reduction and lower mechanical values and resistance to water when using urea-30 urea. in combination with glycerol (sample 1), it gives values equal to those of glycerol alone.

We can therefore use a cheaper and less active product (urea) and make it react as effectively as a more expensive and more effective product (glycerol). Efficiency relates to form aldehyde absorbing capabilities as well as maintaining good mechanical properties and water resistance without changing the reactivity of the adhesive formulation and without the need to introduce special equipment for its use.

The formaldehyde reduction in this case is actually 46%.

40 The formulation used for the different samples is as 8400322 * 1 5 follows: 1 2 3 parts by weight parts by weight parts by weight 5 glycerol (100%) 270 590 urea (100%) 320 - 590 water 410 410 410 1000 1000 1000% solids 59 59 59 10

The adhesive formulations used are as follows: control 123 number gram gram gram gram - urea-formaldehyde-resin 65% (mol ratio 3077 3077 3077 3077 thing F: U 1.27: 1) hardener 400 400 400 400 (ammonium chloride 15%) paraffin emulsion 50% 250 250 250 250 2Φ ammonia 25 ° Baumé 5 5 5 5 sample 1 - 308 - - sample 2 - - 308 - sample 3 - - - 308 water 268 2 1 1 total 4000 4040 * 4040 4040 25 gel time in sec. 68 68 71 62

One-layer board is manufactured in the laboratory by spraying each of these formulations on 25 kg of wood chips. The board is pressed together for 10, 9 and 8 sec / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the pressure is 3500 kPa.

The dimensions of the manufactured board are 40 x 56 cm.

The results obtained are shown in the following table and are mean values.

8400322 fv 6 control 1_2_3_ density (kg / m ^) 683 669 663 657 flexural strength (N / mm ^) 19.9 18.1 17.3 16.3 5 tensile strength (N / mm ^) 0.73 0.72 0 .71 0.63 thickness swelling in 2 h (%) 5.2 4.9 4.5 5.4 thickness swelling in 24 h (%) 51.4 49.9 47.4 53.1 free formaldehyde 15.8 8, 5 8.7 11.7 (mg / 100 g dry board) 10

Example II

This is another example, which illustrates the synergistic behavior of glycerol and urea in reducing free formaldehyde of board from particles while maintaining the mechanical properties of the board as well as water resistance.

The control does not contain all components of the formaldehyde binder according to the invention. Sample 1 contains both components of the formaldehyde binder according to the invention and sample 2 contains only one of the two components (the most effective of the two components).

It is again noted that only Sample 1 releases free formaldehyde, which is less than 10 mg / 100 g dry board (which is the desired level for class El) and is the only one that has absolutely equivalent mechanical properties and water resistance. The formaldehyde-25 reduction is actually 34%.

The formulations used for the different samples are as follows: 1 2 30 parts by weight parts by weight glycerol (100%) 128 128 urea (100%) 424 - water 448 872 1000 1000 35% solids 55.2 12.8

The adhesive formulations used are as follows: 3400322 * i '-i 7 control 1 2 grams gram grams urea-formaldehyde resin 65% (mol ratio 3077 3077 3077 5 thing F: U 1.27: 1) curing agent 400 400 400 ( ammonium chloride 15%) paraffin emulsion 50% 250 250 250 ammonia 25 ° Baumê 5 55 sample 1 - 268 sample 2 - 268 water 268 2 1 total 4000 4000 4000 gel time in sec. 66 67 69 15

One-layer board is manufactured in the laboratory by spraying each of these formulations onto 25 kg of wood chips. The board is compressed for 10, 9 and 8 see / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the pressure is 2Q 3500 kPa. The dimensions of the manufactured board are 40 x 56 cm.

The results obtained are shown in the following table and are mean values.

control 1_2 22 density (kg / m ^) 685 684 687 flexural strength (N / mm ^) 20.7 20.6 19.4 tensile strength (N / mm ^) 0.74 0.73 0.67 thickness swelling in 2 h ( %) 11.0 7.9 8.6 thickness swelling in 24 h (%) 23.5 23.2 23.7 free formaldehyde 14.3 9.5 12.3 (mg / 100 g dry board)

Example III

This example illustrates the effectiveness of monoethylene glycol together with urea as a formaldehyde binder.

Two formulations are prepared: the control without all components of the formaldehyde binder of the invention and sample 1, which contains both monoethylene glycol and urea.

Board is manufactured from these two adhesive formulations and it also appears here that with the formaldehyde binder according to the invention 40 8400322

r S

8 is obtained with a urea-formaldehyde resin board, classified as E 2 (control), classified as E 1 (sample 1).

The formaldehyde reduction in this case is 37%.

The formulation of Sample 1 used is as follows: 5 Sample 1 parts by weight of monoethylene glycol 100% 360 urea 100% 365 10 water 275 1000% solids 72.5

The adhesive formulations used are as follows: 15 control 1 gram grams of urea-formaldehyde resin 65% (mol ratio 3077 3077 F: U 1.27: 1) 20 hardener 400 400 (ammonium chloride 15%) paraffin emulsion 50% 250 250 ammonia 25 ° Baumê 5 5 sample 1 - 268 water 268 - 25 - - total 4000 4000 gelling time in sec. 66 60

Single layer board is manufactured in the laboratory by spraying each of these formulations onto 25 kg of wood chips. The board is pressed together for 10, 9 and 8 sec / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the pressure is 35 kPa. The dimensions of the manufactured board are 40 x 56 cm.

The results obtained are shown in the following table and are 35 mean values.

8400322> -i 9 control 1_ density (kg / m ^) 685 684 flexural strength (N / mm ^) 20.7 20.2 5 tensile strength (N / mm ^) 0.74 0.74 thickness swelling in 2 h (%) 11.0 8.6 thickness swelling in 24 h (%) 23.5 22.6 free formaldehyde 14.3 9.0 (mg / 100 g dry board) 10

Example IV

This example illustrates the synergistic behavior of monoethylene glycol and urea.

Board is prepared from three different formulations: the control, in which no components of the formaldehyde binder of the invention are used, sample 1, in which both components of the formaldehyde binder of the present invention are used, and sample 2, in which only one component used.

It appears from the results obtained and reported below that Sample 1, containing both components, is much more effective than Sample 2, which contains only one component (the most effective of the two components).

The formaldehyde reduction obtained in this case is 32%

The formulations used of the different samples are as follows: 1 2 parts by weight parts by weight of monoethylene glycol 100% 230 580 30 urea 100% 350 - water 420 420 1000 1000% solids 58 58 35 The adhesive formulations used are as follows: 8400322 10 ¢ ->

V

control 1 2 number gram gram gram urea-formaldehyde resin 65% (mol ratio 3077 3077 3077 5 thing F: U 1.27: 1) hardener 400 400 400 (ammonium chloride 15%) paraffin emulsion 50% 250 250 250 ammonia 25 ° Baumê 5 55 10 sample 1 - 268 - sample 2 - 268 water 268 - - total 4000 4000 4000 gel time in sec. 70 71 76 15

One-layer board is manufactured in the laboratory by spraying each of these formulations onto 25 kg of wood chips. The board is pressed together for 10, 9 and 8 sec / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the pressure is 35 2o kPa. The dimensions of the manufactured board are 40 x 56 cm.

The results obtained are shown in the following table and are mean values.

control 1_2 25 density (kg / m ^) 688 688 687 flexural strength (N / mm ^) 17.6 17.6 17.5 tensile strength (N / mm ^) 0.55 0.60 0.56 thickness swelling in 2 h ( %) 6.7 4.9 4.7 thickness swelling in 24 h (%) 20.1 20.1 19.5 30 free formaldehyde 15.0 10.3 12.3 (mg / 100 g dry board)

Example V

This example illustrates the use of a resin of different 33 molar ratio as well as different levels of addition of the formaldehyde binder itself.

The formaldehyde binder used has the following formulation: 8400322

* A

Λ 11 parts by weight glycerol 100% 270 urea 100% 318 5 water 412 1000% solids 58.8

The adhesive formulations used in the various samples are as follows: Control 1 23 Number grams Grams Grams Grams of urea-formaldehyde resin 65% (mol ratio 3077 3077 3077 3077 15 thing F: U 1.27: 1) curing agent 293 380 380 380 (ammonium chloride 15%) paraffin emulsion 50% 250 250 250 250 ammonia 25 ° Baumê 5 5 5 5 2Q formaldehyde binder - 154 215 375 water 375 134 73 - total 4000 4000 4000 4087 gel time in sec. 73 73 72 75

Board existing tilt single layer is used in the laboratory,

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prepared by spraying each of these formulations onto 25 kg of wood chips. The board is pressed together for 10, 9 and 8 sec / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the pressure is 3500 kPa. The dimensions of the manufactured board are 40 x 56 cm.

30

The results obtained are summarized in the following table and are mean values.

8400322

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12 control 1_2_3_ density (kg / m ^) 680 687 685 688 flexural strength (N / mm ^) 22.0 22.5 22.3 21.6 5 tensile strength (N / mm ^) 0.61 0.63 0.66 0.64 thickness swelling in 2 h (%) 10.1 9.3 8.8 9.5 thickness swelling in 24 h (%) 20.6 21.8 21.0 21.5 free formaldehyde 22.2 13.0 10 , 1 9.5 (mg / 100 g dry board) 10

It is noted that the mechanical properties and water resistance of the board are equivalent and the formaldhyd reduction in the case of sample 1 is 41%, in the case of sample 2 55% and in the case of sample 3 57 %.

Example VI

In this example, six different types of polyalcohols, two different types of amides, an additive and a variation in the alcohol to amide ratio covering the range of 57.5 / 100 to 385/100 are illustrated.

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8400322 15

One-layer board is manufactured in the laboratory by spraying each of these formulations onto 25 kg of wood chips. The board is pressed for 10, 9 and 8 sec / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the pressure is 3500 kPa. The dimensions of the manufactured board are 40 x 56 cm.

The results obtained are shown in the following table and are mean values.

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The above results show that all samples used have values equivalent to the control and that the formaldehyde reduction is on the order of 32 to 47%.

Example VII

In this example, three different types of organic compounds containing hydroxyl groups are exemplified, namely dextrin, phenol and resorcinol.

A monovalent alcohol, which functions as an additive other than methanol, is also explained, namely ethanol.

10 The different types of formaldehyde binder used are as follows: 12 3 4 monoethylene glycol 230 - - - 15 dextrin - 140 - - phenol - - 130 - resorcinol - - 130 methanol - 140 130 130 ethanol 80 - - 20 urea 350 350 370 370 water 340 370 370 370 1000 1000 1000 1000% solids 66 63 63 63 25 All the above figures are in parts by weight. The formaldehyde binder samples are used in this example to replace some of the resin used.

The actual adhesive formulations used are as follows: 8400322 · 18 Control 1 234 Grams Grams Grams Grams Grams of Urea Formaldehyde Resin (Mole Ratio 3077 2770 2770 2770 2770 5 F: U 1.27: 1) Curing Agent 400 500 400 450 400 ( ammonium chloride 15% solution) paraffin emulsion 50% 250 250 250 250 250 ammonia 25 ° Baumé 5 - - - 10 formaldehyde binder sample 1 - 307 - - - sample 2 - 307 sample 3 - 307 sample 4 - - - 307 ^ water 268 - - - - Total 4000 3827 3727 3777 3727 Gel time in sec. 65 64 62 63 63

One layer board is manufactured in the laboratory by spraying each of these formulations onto 25 kg of wood chips. The board is pressed together for 10, 9 and 8 sec / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the pressure is 3500 kPa. The dimensions of the compressed board are 40 x 56 cm.

The results obtained are shown in the following table and are 25 average values.

control 1_2_3_4_ density (kg / m3) 702 698 695 705 710 flexural strength (N / mm ^) 20.1 19.5 19.7 20.0 20.8 ^ tensile strength (N / mm3) 0.75 0.70 0, 75 0.73 0.72 thickness swelling in 2 h (%) 7.1 6.8 6.5 6.3 6.6 thickness swelling in 24 h (%) 20.3 21.5 21.3 21.8 21. 3 free formaldehyde 13.1 9.6 9.2 8.2 10 (mg / 100 g dry board) 33 formaldehyde reduction (%) - 27 30 37 24

The above results show that all samples have values equivalent to the control sample, which does not contain a formaldehyde binder, even though the latter replaces an equivalent amount of urea-formaldehyde resin in the formulation. The formaldehyde reduction in this example ranges from 24 to 37 Z.

Example VIII

In this example, one type of formaldehyde binder is used and the resin is based on a phenol-melamine-urea-formaldehyde resin.

The formaldehyde binder used has the following formulation: parts by weight

10 monoethylene glycol 30G

urea 330 water 370 1000 15 The adhesive formulations used are as follows:

control I

number of grams grams of phenol-melamine-urea-formaldehyde resin 63 Z 5600 5600 20 curing agent (aqueous solution of 15.5 Z ammonium chloride) 840 840 paraffin emulsion 50Z 150 150 formaldehyde binder - 560 total 6590 7150 25 gel time in sec. 73 79

One-layer board is manufactured in the laboratory by spraying each of these formulations onto 25 kg of wood chips. The board is pressed together for 10, 9 and 8 sec / mm. The thickness of the 30 board is 17.3 mm. The temperature of the press is 200 C and the pressure is 3500 kPa. The dimensions of the manufactured board are 40 x 56 cm.

The results obtained are shown in the following table and are mean values.

8400322 * 5 »20 control 1_ density (kg / m ^) 705 695 flexural strength (N / mm ^) 26.2 25.9 5 tensile strength (N / mm ^) 0.27 0.26 tensile strength V100 (N / mm ^ ) 2.7 2.6 thickness swelling in 2 h (%) 7.1 6.2 thickness swelling in 24 h (%) 12.0 11 »3 free formaldehyde 10 (mg / 100 g dry board) 12.8 7 formaldehyde reduction ( %) - 45

The above-mentioned results show that the formaldehyde binder of the present invention can also be used for phenol-melamine-urea-formaldehyde resins, which significantly reduce the release of free formaldehyde without adversely affecting the properties of the board.

Example IX

In this example, the formaldehyde binder used contains an inorganic compound [component (d)], exemplified in this case by sodium chloride.

The formaldehyde binder used has the following formulation: 25 parts by weight of monoethylene glycol 100% 270 urea 100% 318 sodium chloride 100% 50 water 362 30 total 1000% solids 63.8 35 The adhesive formulations used in the various examples are as follows: 8400322 «« - ? , 21 t control 1 gram gram urea-formaldehyde resin (mol ratio 3077 2770 F: U 1.27: 1) curing agent (ammonium chloride 15% solution) 400 450 paraffin emulsion 50% 250 250 ammonia 25 ° Baumë 5 - formaldehyde binder - 307 water 268 - total 4000 3777 gelling time in sec. 65 64 15

One-layer board is manufactured in the laboratory by spraying each of these formulations on 25 kg of wood chips. The board is pressed together for 10, 9 and 8 sec / mm. The thickness of the board is 17.3 mm. The temperature of the press is 200 ° C and the 2Q pressure is 3500 kPa. The dimensions of the compressed board are 40 x 56 cm.

The results obtained are shown in the following table and are mean values.

control 1 25, - density (kg / np) 695 699 flexural strength (N / mm.2) 19.9 19.5 tensile strength (N / mm ^) 0.71 0.73 thickness swelling in 2 h (%) 7, 0 6.6 thickness swelling in 24 h (%) 20.5 20.8 free formaldehyde (mg / 100 g dry board) 17 9.5 formaldehyde reduction (%) - 44 ^ The results show that the sample containing formaldehyde binder, has values equivalent to the control sample, despite the fact that the formaldehyde binder replaces part of the urea-formaldehyde resin in the formulation. The formaldehyde reduction is 44%.

8400322

Claims (30)

A formaldehyde binder for use in board made of lignocellulosic materials using formaldehyde-based adhesives containing a solution of 5 (a) at least one organic hydroxyl compound with the exception of C 1 -valent aliphatic alcohols and (b) at least one amide in water. A formaldehyde binder according to claim 1, additionally containing (c) an organic compound which acts as a solvent for (a) and (b) and also reacts with formaldehyde. The formaldehyde binder according to claim 2, wherein (c) is a C 1-4 aliphatic monovalent alcohol. Formaldehyde binder according to one or more of claims 1 to 3, which additionally contains (d) an inorganic compound which is soluble in water. The formaldehyde binder of claim 4, wherein (d) is a water-soluble halide salt. 6. The formaldehyde binder of claim 5, wherein (d) is a water-soluble halide of an alkali metal or an alkaline earth metal. A formaldehyde binder according to claim 6, wherein (d) is sodium chloride, potassium chloride or calcium chloride. A formaldehyde binder according to any of claims 1 to 7, wherein component (a) is soluble in water or in a monovalent aliphatic alcohol. The formaldehyde binder of claim 8, wherein component (a) is selected from divalent, trivalent and pentavalent alcohols containing up to 6 carbon atoms, monosaccharides containing up to 6 carbon atoms, disaccharides containing up to 12 carbon atoms and polysaccharides containing a Ostwald viscosity up to 200 mPas at 25 ° C and a concentration corresponding to a refraction of 37%. The formaldehyde binder of claim 8, wherein component 35 (a) is selected from aromatic alcohols and phenols. The formaldehyde binder of claim 10, wherein component (a) is selected from monovalent and polyvalent aromatic alcohols containing a benzene ring and monovalent and polyvalent phenols. The formaldehyde binder according to any of claims 1 8400322 to 11, wherein component (b) is soluble in water or in a C monovalent aliphatic alcohol. The formaldehyde binder of claim 12, wherein component (b) is selected from aliphatic amides containing up to 6 carbon atoms and aromatic amides containing one benzene ring. Formaldehyde binder according to one or more of claims 1 to 13, characterized in that the weight ratio of component (a) plus components (c) and (d), if present, to component (b) 10: 100 to 400: 100. Formaldehyde binder according to one or more of claims 1 to 14, characterized in that it contains 20 to 80% by weight of the active ingredients. A process for preparing the formaldehyde binder according to claim 1, wherein (a) at least one organic hydroxyl compound with the exception of C 1 monovalent aliphatic alcohols, (b) at least one amide and (c) optionally at least one organic compound, which acts as a solvent for (a) and (b) and also reacts with formaldehyde and (d) optionally an inorganic compound soluble in water and water are mixed at a temperature from room temperature to 70 ° C, The method of claim 16, wherein (c) is a monovalent aliphatic alcohol. The method of claim 16 or 17, wherein (d) is a water-soluble halide salt. The method of claim 18, wherein (d) is a water-soluble halide salt of an alkali metal or an alkaline earth metal. The method of claim 19, wherein (d) is sodium chloride, potassium chloride or calcium chloride. 21. A method according to any one of claims 16 to 20, wherein component (a) is soluble in water or in a monovalent aliphatic alcohol. The method of claim 21, wherein component (a) is selected from divalent, trivalent and pentavalent alcohols containing up to 6 carbon atoms, monosaccharides containing up to 6 carbon atoms, disaccharides containing up to 12 carbon atoms and polysaccharides with a viscosity according to Ostwald 8400322 to 200 mPas at 25 ° C and a concentration corresponding to a refraction of 37%. The method of claim 21, wherein component (a) is selected from aromatic alcohols and phenols. The method of claim 23, wherein component (a) is selected from monovalent and polyvalent aromatic alcohols containing a benzene ring and monovalent and polyvalent phenols. 25. A method according to any one of claims 16 to 24, wherein component (b) is soluble in water or in monovalent aliphatic alcohols. The method of claim 25, wherein component (b) is selected from aliphatic amides containing up to 6 carbon atoms and aromatic peptides containing one benzene ring. 27. A method according to any one of claims 16 to 26, characterized in that the weight ratio of component (a) plus components (c) and (d), if present, to component (b) is from 10: 100 to 400: 100 is. 28. Process according to one or more of claims 16 to 27, characterized in that the formaldehyde binder contains 20 to 80% by weight of the 20 active ingredients. A process for the manufacture of board from lignocellulosic materials using a formaldehyde based adhesive, wherein a formaldehyde binder according to any of claims 1 to 16 is added to the adhesive. 30. Board, if manufactured by a method according to claim 29. λ *** λ * λ ** 8400322