DE3346679A1 - Preparation of urea-formaldehyde condensates, and the use thereof - Google Patents

Abstract

The invention relates to a process for the preparation of water-dilutable, low-formaldehyde urea-formaldehyde condensates which have a low viscosity and a long shelf life by condensing urea and formaldehyde in a molar ratio of from 1:2.0 to 2.25 in the presence of alkali metal sulphite at a pH of from 9.0 to 10.5 and a temperature of from 80 DEG C to the reflux temperature, and subsequently continuing the condensation at a pH of from 4.0 to 6.0 and at from 70 to 95 DEG C, where from 0.01 to 0.03 mol of alkali metal sulphite are employed per mol of formaldehyde, the condensation at pH 4.0 to 6.0 is carried out with addition of from 0 to 0.2 mol of a water-soluble alkanol per mol of formaldehyde until infinite water-dilutability is just achieved, urea is subsequently added until the overall urea:formaldehyde molar ratio is from 1:1.60 to 1.95, and then from 0.01 to 0.04 mol of glyoxal are added per mol of formaldehyde, and to the use of the urea-formaldehyde condensates as binders for fibre nonwovens made from organic and/or mineral fibres.

Description

Production of urea-formaldehyde condensates and their use

For many coating, impregnating and binding agents based on thermoplastic resins, mainly in the case of urea-formaldehyde condensates, in practice it is good to unlimited water dilutability required Among other things, mineral fiber fleeces, such as fiberglass webs solidified to a large extent with aminoplast resins, with urea-formaldehyde condensates have a large share. For this purpose there is almost unlimited water dilutability required. Storage-stable urea-formaldehyde resins have this property generally a urea: formaldehyde molar ratio of 1: greater than 2.0. Aqueous resin solutions of this type also have a low resin concentration relatively high content of free formaldehyde, which interferes with use, especially e.g. considerable amounts during the hardening of the glass fiber fleece bonded with it Formaldehyde are released. In many areas of application, therefore, is used today with Urea-formaldehyde resins worked that have a urea-formaldehyde molar ratio 1: less than 2.0. However, resins of this composition are generally only stable in storage in a relatively highly condensed state. Such condensates can then only be mixed with small amounts of water without phase separation the solution enters with the settling of sticky resin components; they are thus e.g.

useless for binding mineral fiber fleeces. The preservation the water dilutability can only be achieved by condensing in a relatively greater amount Proportions of modifiers through the water-solubilizing groups to be built in. Fiberglass fleece with binders modified in this way but are sensitive to moisture.

The object of the present invention is therefore to provide liquid, readily water-dilutable, Low-formaldehyde and storage-stable urea-formaldehyde condensates with a high solids content at low viscosity to make available, the reactivity of which is comparable Curing speeds result and comparable mechanical properties e.g. of glass fiber fleece as when using urea-formaldehyde condensates of the state of the art.

Water-soluble or water-thinnable modified urea-formaldehyde condensates, which are stable in storage can e.g. by polycondensation of urea with formaldehyde with the addition of sulfites or bisulfites of the alkali or alkaline earth metals or other salts releasing sulfite ions are produced. As further anions, which improve the solubility of the condensates in water come, for example, the salts of Amidosulfonic acid or aminoalkylsulfonic acids into consideration. Corresponding Suifit-Modifi- graced Resins with 0.05 to 0.4, or 0.05 to 1, or 0.05 to 0.6 mol sulfite groups each Moles of formaldehyde at mole ratios of urea to formaldehyde from 1: 2 to 3 are known in U.S. Patents 2,407,599, 2,412,855 and 2,559,578, respectively. According to the Information in DE-PS 889 225 contain such resins 0.04, better than 0.1 Moles of sulfite groups per mole of urea and according to the information in DE-OS 23 24 440 there should be 0.0576 to 0.202 moles of sulfite groups for 1 mole of urea.

From DE-PS 889 225 and DE-OS 23 24 440 it can be seen that in low sulphite content, the viscosity increases relatively quickly during storage, Amounts of sulphite or water-solubilizing agents, such as amidosulphonate, in the specified proportions, however, cause the hardened ones to be highly susceptible Glass fiber fleece against moisture. This occurs more or less strongly pronounced loss of the desired properties, e.g. Tear strength on, the further processing of the glass fiber fleece is difficult. Furthermore can condensed Urea-formaldehyde resin in connection with adsorbed water on the fleece can be broken down with catalyst residues. The same applies to other substrates, e.g. textile fiber nonwovens, which with urea-formaldehyde condensates, e.g. mechanical Strength or water resistance is to be imparted.

Furthermore, US Pat. No. 2,242,484 discloses storage stability of urea-formaldehyde condensates by adding alcohols with the formation of Increase alkoxymethyl groups. This requires depending on the molar ratio of urea : Formaldehyde and degree of condensation of the resins considerable amounts of alcohol each introduced alkylol group and thus costly removal of converted alcohol or high residual alcohol content in the resin. This is off at high curing temperatures Fire protection reasons as well as disadvantageous because of high pollutant emissions.

The stabilization with aldehydes, dialdehydes and ketones is according to US Pat. No. 3,962,166 in high-quality textile finishing with the formation of products which 4.5-Dihydroxi (alkoxy) -imidazolidin-2-one and its N-methylol or

N-alkylol derivatives contain, but must be used in proportion high proportions of such expensive compounds, e.g. glyoxal, can be used. aside from that result in the products obtained when tested as binders for glass fiber fleeces become, poor tensile strength values.

It has now been found that water-thinnable, low-formaldehyde products can be obtained and storage-stable urea-formaldehyde condensates of low viscosity through 10 Condensation of urea and formaldehyde in the Molar ratio 1: 2.0 to 2.25 in the presence of alkali sulfite at pH values from 9.0 to 10.5 and Temperatures from 800C to reflux temperature and subsequent further condensation at pH values of 4.0 to 6.0 at 70 to 950C, if one mole of formaldehyde 0.01 to 0.03 mol of alkali metal sulfite is used in the condensation at pH 4.0 to 6.0 per mole of formaldehyde with the addition of 0 to 0.2 moles of a water-soluble alkanol condensed until there is still unlimited water dilutability, then Urea is added until the total molar ratio of urea to formaldehyde is 1 1.60 to 1.95 and also adds 0.01 to 0.04 moles of glyoxal per mole of formaldehyde.

Surprisingly, the good storage stability of the condensates remains also obtained when a very low free formaldehyde content of for example 0.1 to 0.2 wt. X is set in a 60% strength resin solution. Comparable Storage stability and formaldehyde content were previously not achievable with condensates, gave the nonwoven glass fiber fabrics with equivalent properties when used to consolidate them were used.

With the new process, formaldehyde can, for example, be commercially available as an aqueous solution Concentration, in the form of its solid oligomers, such as paraformaldehyde and the corresponding Amount of water, in particular as a 40 to 55% aqueous urea-containing formaldehyde solution, (as is commercially available as FORMOL (R)) can be used. Urea can e.g.

in solid form or as a concentrated e.g. 68.5% aqueous solution can be used. Powdered, essentially single-core ones can also be used N-methylol compounds of urea, e.g. technical grade dimethylol urea.

The sulfite groups can be introduced in the form of water-soluble salts which release sulfite anions in an approximately neutral pH range, preferably than sodium disulfite, which can be of technical quality. The addition can be to one take place at any time before setting the alkaline pH, advantageous is the addition at the beginning, e.g. to a concentrated aqueous solution. Urea-formaldehyde solution before the reaction mixture is heated up.

To adjust the alkaline pH value, alkali or alkaline earth hydroxides, are used, the amount of which is generally less than 0.006 mol of hydroxyl groups is chosen per mole of formaldehyde. Mixtures of alkali or alkali are also suitable Alkaline earth hydroxide and mines, preferably tertiary amines with at least one Hydroxialkyl group, for example diethylethanolamine, dimethylethanolamine and dimethyl-4-butanolamine, with the help of which you can adjust the alkaline pH range given above. at the reaction taking place in the alkaline pR range is stabilizing in a small amount active formate formed from the formaldehyde. A corresponding stabilization cannot, however, by adding a small amount of, for example, sodium formate to a urea - formaldehyde condensate can be obtained. Do you work outside the pH, temperature, time and alkali sulfite limits according to the invention, so obtained one products that in any case have poorer results in terms of formaldehyde balance and / or show storage stability.

Condensation is carried out in the acidic pH range, advantageously with the addition of monovalent water-soluble alkanols, such as methanol in particular, to just unlimited water dilutability given is. The duration of this manufacturing phase is known per se Way from the pair of values pH / temperature in the claimed ranges. The setting the acidic pH value for condensation can be achieved with mineral acids, e.g. sulfuric acid, or strong organic acids, formic acid is preferred.

Glyoxal and, if necessary, additional urea are added at any time after termination of the condensation reaction, preferably immediately after leaving the acidic pH range while cooling the resin solution to room temperature. With alkanol contents at the upper limit of the claimed range it is advisable to cool the condensate under reduced pressure.

The condensates fall as 50 to 70%, preferably 55 to 60% water-clear products in the viscosity range from 50 to 500 mPas. The viscosity of the 50% condensate solutions are in the range from 50 to 120 mPas. The received Condensate solutions become slightly cloudy over the course of weeks when stored (room temperature), without their water dilutability or viscosity changing significantly. Strong Dilute, even cloudy, aqueous condensate solutions show up after a long period of standing no excretions.

The condensates produced according to the invention are compatible with weakly cationic, neutral or anionic water-soluble or water-dispersible Amino and / or phenoplast condensates, especially with urea and melamine-formaldehyde condensates. You can therefore, for example, with any desired amounts of suitable melamine-formaldehyde resins be mixed in a stable manner or used for stretching melamine-formaldehyde resins will. The condensates produced according to the invention are also compatible with other coating, impregnating and binding agents, e.g.

weakly cationic to anionic water-soluble or water-dispersible Polymers based on polyvinyl alcohol, polyvinyl acetate, polyacrylic acid and polyacrylic acid ester, Polymethacrylic acid and polymethacrylic acid esters, polyacrylamide and polymethacrylamide furthermore native binders, such as starch and their modification products, as well commonly used auxiliaries, such as emulsifiers, wetting agents and adhesion promoters, as they are especially in the production of mineral fiber fleeces, e.g. glass fiber fleeces, be used when consolidating the nonwovens.

The condensates produced according to the invention are used in a conventional manner, preferably in the form of an aqueous bath, with additives a suitable acidic catalyst, for example metal salts of strong acids, preferably magnesium chloride, or acids, preferably mineral acids such as phosphoric acid. The application on the mineral fiber fleece, e.g. the glass fiber fleece, as well as the dosage the proportion of condensate based on the weight of the fleece takes place in the usual way.

The hardening of the with the condensates and possibly additionally with water-dilutable or water-dispersed amino and / or phenoplast condensates impregnated nonwovens takes place in the usual way in the temperature range of mostly 240 to 2800C, often 10 to 30 sec.

Dwell time in the drying tunnel is sufficient.

Due to their very low free formaldehyde content, the condensates according to the invention can be regarded as practically odorless. she For this reason, they also have a significantly reduced emission of formaldehyde during the application and the hardening process, e.g. when bonding the fleece on.

The parts and percentages given in the following examples relate focus on the weight. Parts by weight relate to parts by volume like that Kilogram to liter.

Example 1 7500 parts of an aqueous solution obtained in a conventional manner Urea-formaldehyde precondensate solution of a molar urea to formaldehyde ratio of 1: 4 (solids content approx. 75% by weight) are presented, 2600 parts of a 68.5 % strength aqueous urea solution, 350 parts of water and 310 parts of sodium disulfite were added and the mixture is heated to 80 ° C. with stirring. After adding 97 parts by volume 25% strength aqueous sodium hydroxide solution is stirred for 15 minutes at 850.degree. Then with 85% formic acid was adjusted to pH 5.05 and stirred for 37 minutes at 850C.

After adding 925 parts of water, 17 parts by volume of 25% sodium hydroxide solution, 431 Parts of 40% aqueous glyoxal solution and 1505 parts of urea solution are obtained one 13810 parts of a 55% lÇondensat solution containing 0.1% free formaldehyde and a viscosity of 38 sec. according to DIN 53211.

Example 2 7500 parts of a urea-formaldehyde precondensate according to the details of Example 1, 2600 parts of 68.5% strength aqueous urea solution, 350 parts Water and 310 parts of sodium disulfite are heated to 850 ° C. with stirring. By Addition of 25% aqueous sodium hydroxide solution is adjusted to pH 10.2 and then 15 min. stirred at 850C. Then 41 parts by volume of 85% formic acid are added and stirred for 40 min. at 850C. After adding 925 parts of water, 25% strength is added aqueous sodium hydroxide solution adjusted to pH 9.5, 431 parts of 40% strength aqueous glyoxal solution and 630 parts of 86.5% strength aqueous urea solution were added and brought to room temperature let cool down. 12935 parts of 55% strength condensate solution are obtained free formaldehyde of 0.15% and a viscosity of 49 sec. according to DIN 53211.

Example 3 7500 parts of a urea-formaldehyde precondensate according to the details of Example 1, 2600 parts of 68.5% strength aqueous urea solution, 350 parts Water and 310 parts of sodium disulfite are heated to 80 ° to 850 ° C. with stirring. The pH is adjusted to 10.25 with 25% aqueous sodium hydroxide solution and 15 min. At 850C touched. After adjusting to pH 5.00 with 85% formic acid, at 85 to Stirred 900C, with 1 part resin solution with 1.0 + 0.2 parts of a 25% aqueous Solution of magnesium sulphate at room temperature gives a permanent strong turbidity. With 25% aqueous sodium hydroxide solution, pH 9.5 is now set, 925 parts of water, 431 parts of a 40% strength aqueous glyoxal solution and 425 parts of a 68.5% strength aqueous solution Urea solution added and cooled. 12733 parts of 55% strength condensate solution are obtained a content of free formaldehyde of 0.44% and a viscosity of 60 sec. according to DIN 53211.

Example 4 7276 parts of a urea-formaldehyde precondensate according to the information in Example 1, 2522 parts of 68.5% strength aqueous urea solution, 334 parts Water and 303 parts of sodium disulfite are evenly distributed within 33 minutes 80 ° C heated. After adding 94 parts by volume of 25% strength aqueous sodium hydroxide solution the reaction mixture received for 15 min. at 85 ° C, where- at the pH is lowered to 10.25. The pH is then adjusted to 5.0 with 85% formic acid, 388 parts of methanol were added and the mixture was stirred at 850.degree. C. for 85 minutes. After adding 582 parts Water is adjusted to pH 9.30 with 25% aqueous sodium hydroxide solution, 419 parts of a 40% strength aqueous glyoxal solution and 723 parts of 68.5% strength aqueous urea solution added and cooled. 12700 parts of a condensate solution with a solids content are obtained of 55.2 x and a viscosity of 80 sec. according to DIN 53211. The content of free Formaldehyde is 0.1%.

Example 5 4,200 parts of a urea-formaldehyde precondensate according to the information in Example 1, 1458 parts of 68.5% urea solution, 192 parts of water and 175 parts of sodium disulfite are heated to 850C. With 54 parts by volume 25% aqueous sodium hydroxide solution is adjusted to pH 10.04 and 15 min.

stirred at 900C. After addition of 445 parts of methanol, 85 % formic acid was adjusted to pH 5.00 and stirred for 46 minutes at 88 to 90.degree. With 25% strength aqueous sodium hydroxide solution is adjusted to pH 9.50 and under reduced pressure (100 to 40 mbar) the condensate is cooled to 250C. After adding 242 parts 40 % aqueous glyoxal solution and 416 parts of 68.5% aqueous urea solution a condensate with a solids content of 61% and a viscosity of 62 sec. according to DIN 53211 and a free formaldehyde content of 0.15%. the Yield is 6753 parts.

Comparative Example A (U: F = 1: 2.0) (a) 1000 parts of a urea-formaldehyde precondensate, obtained from 50 parts of formaldehyde, 25 parts of urea and 25 parts of water, 365 Parts of a 68.5% strength aqueous urea solution and 46 parts of water are added 85 to 900C and heated for 15 to 20 minutes at this temperature at pH 7.5 to 9.0 implemented. Then the pH - value is brought to 5.0 to 5.5 and condensed as long as until a sample of the reaction mixture is just infinitely dilutable with water. The pH is adjusted to 8.5 to 9.0 by adding 25% strength aqueous sodium hydroxide solution cooled down.

A clear, water-dilutable resin solution with 60% solids content is obtained, a content of free formaldehyde of 2.0 t 0.2% and a viscosity of 65 sec. according to DIN 53211.

The resin has a viscosity of 107 seconds after 9 days. on and is no longer sufficiently dilutable with water.

(b> If, after the condensation, 0.024 mol of glyoxal is used per mol of used Formaldehyde, a condensate is obtained that is stable for 21 days (storage temperature 20 + 1 "C).

Comparative Example B (U: F - 1: 2.0; modified with sulfite) (a) Man works as indicated in Comparative Example A, but gives at the beginning of the reaction to 1200 parts of the urea-formaldehyde precondensate 76.5 parts of sodium sulfite (corresponds to 0.0403 mol per mol of formaldehyde or 0.0806 mol per mol of urea). A solids content of 55% is set with water.

A condensate with a solids content of 55% is obtained of free formaldehyde of 1.75% and a viscosity of 61 seconds according to DIN 53211.

The storage stability of the condensate with unlimited water dilutability is 12 to 15 days.

(b) 0.024 mol is added to the condensate solution obtained according to (a) Glyoxal per mole of total formaldehyde used. The condensate solution then had a free formaldehyde content of 1.5% and a viscosity of 59 seconds. after DIN 53211. Its dilutability in water was retained for 77 days.

Comparative example C (U: F = 1: 2.0; modified with sulfite and methanol) (a) As indicated in Comparative Example A, 120 parts of urea - formaldehyde precondensate, 437 parts of the urea solution mentioned, 55 parts of water and an additional 51 parts Sodium disulfite implemented.

Before adding formic acid to adjust the weakly acidic Condensation pH range 64 parts of methanol (corresponding to 0.1 mol per mol formaldehyde used) added and condensed, up to 1 part by volume of resin solution with 1.6 parts by volume of a 25% strength aqueous magnesium sulfate solution a permanent one Results in turbidity at room temperature.

After adding 98 parts of water, 1866 parts of a 55% strength Condensate solution with a free formaldehyde content of 1.48% and a viscosity of 41 sec. obtained according to DIN 53211. It was no longer sufficient after 3 days can be diluted with water.

(b) 0.025 mol is added to the condensate solution obtained according to (a) Glyoxal per mole of total formaldehyde used. The condensate solution (b) was after 12 days no longer sufficiently dilutable with water.

Application data (a) What server thinnability To assess the water thinnability the condensate solutions described in the examples becomes an electrolyte-containing one Water of the following defined composition is used: 283 mg CaC12 per 1 H20 142.3 mg MgCl2. 6 H20 11 II 1127 mg Na2S04. 10 H20 "" "II 504 mg NaHC03 T? II II water dilutability is considered sufficient if one with the above-mentioned electrolyte-containing Water condensate solution diluted to 5% by weight solids content for more than 6 hours without Excretion of flakes or the formation of sediment remained stable.

(b) Tear strengths To determine the tear strengths, glass fiber nonwovens are used with a basis weight of 35 to 50 g / m2. The glass fibers it contains are approx. 10 to 15 mm long and have an average diameter of 1211 m. The fleeces were set in a 20% strength aqueous condensate liquor with a pH of 4.0 with phosphoric acid) impregnated to a condensate content of 20% based on the weight of the glass and then dried in a circulation drying cabinet for 2 minutes at 2000 ° C.

The tear strength of the fleece is then determined in the dry state and determined after storage for 15 minutes in water at room temperature.

The tensile strength test is carried out in accordance with DIN 52141.

The values thus obtained are for those according to the examples and comparative examples The resulting condensate solutions are compiled in Tables 1 and 2.

Determination of the rondensate characteristics a) Free formaldehyde The determination the content of free formaldehyde was carried out according to DeJong and DeJonge, Receuil Trav. chim. PaysBas 71, 643-660 (1952).

b) Viscosity The determination was carried out in accordance with DIN 53211 by measurement the flow time of the condensate solution sample in the DIN cup 4 at 200C.

c) Solids content 5 g of condensate solution are exactly 1 mg in a Tinplate lid with a diameter of 5 cm weighed in and at 1200C for 2 hours Stored in a drying cabinet at normal pressure. The difference in weight is used to calculate the specified fixed content in% (m / m).

Table 1 Composition, characteristics and storage stability Example Comparative example 1 2 3 4 5 A B C molar ratio formaldehyde / urea beginning 2.05 2.05 2.05 2.05 2.05 2.00 2.00 2.00 End 1.60 1.75 1.90 1.80 1.80 2.00 2.00 2.00 Free formaldehyde (%) 0.1 0.15 0.44 0.15 0.25 2.10 a) 1.75 1.48 b) 1.50 Solids content (%) 55 55 55 55 61 60 a) 55 55 b) 55 Modifying agent sulfite as HSO3 (mol per Mol CH2O total) 0.013 0.013 0.013 0.013 0.013 - 0.0195 0.013 methanol (mol per Moles CH2O total) - - - 0.10 0.10 - - 0.10 glyoxal (moles per mole CH2O total) 0.024 0.024 0.024 0.024 0.024 a) 0.024 a) - a) -b) 0.024 b) 0.025 Storage stability with regard to Water dilutability (days) 40 48 69 90 64 9 a) 12-15 a) 3 a) 21 b) 77 b) 12 Tabel 1 (continued) Composition, characteristics and storage stability Example Comparative example 1 2 3 4 5 A B C Viscosity build-up Dwell time according to DIN 53211 (Sec.) A) a) b) a) b) to 0 38 42 72 24 62 65 59 61 58 41 40 1 44 53 72 28 69 98 62 64 57 - 41 2 46 54 73 30 71 - 64 64 62 - 43 4 49 60 72 34 72 - - - 65 - -6 58 78 102 38 73 - - - 66 - -8 80 112 147 42 76 - - - 72 - -10 - - - 44 80 - - - 82 - -12 weeks after manufacture - - - 55 - - - - - - - Table 2 Application parameters Dry tensile strength Wet tensile strength (N / 5 cm) (N / 5 cm) Example 1 235 135 Example 2 262 146 Example 3 250 136 Example 4 230 140 Example 5 235 135 Comparative example A a) 217 139 comparative example B b) 212 119 comparative example C a) and b) none Measurement because storage stability or water dilutability is too short

Claims (3)

Claims 1. Process for the production of water-dilutable, low-formaldehyde and storage-stable urea-formaldehyde condensates of low viscosity by 10 Condensation of urea and formaldehyde in molar ratio for up to 30 minutes 1: 2.0 to 2.25 in the presence of alkali sulfite at pH values from 9.0 to 10.5 and Temperatures from 80 ° C to reflux temperature and subsequent further condensation at pH values from 4.0 to 6.0 at 70 to 950C, characterized in that each Mol of formaldehyde 0.01 to 0.03 mol of alkali metal sulfite is used in the condensation pH 4.0 to 6.0 per mole of formaldehyde with the addition of 0 to 0.2 moles of a water-soluble one Alkanol condenses until there is still unlimited water dilutability, then urea is added until the total molar ratio of urea to formaldehyde is reached 1: 1.60 to 1.95 and still 0.01 to 0.04 mol of glyoxal per mol of formaldehyde inflicts. 2. Use of the prepared by the method of claim 1 Urea-formaldehyde condensates, optionally mixed with water-thinnable ones or amino and / or phenoplast condensates dispersed in water as coating, Lin impregnation and binding agent for flat substrates. 3. Use of the prepared by the method of claim 1 Urea-formaldehyde condensates, optionally mixed with water-thinnable ones or water-dispersible amino and / or phenoplast condensates as binders for nonwovens made of organic and / or mineral fibers, preferably glass fibers, Basalt fibers, alumina fibers and polyester fibers.