DE2539850A1 - Triamino-propyl-amino polyoxyalkylated tensides - contg. random or block copolymer gps. propylene oxide, ethylene oxide and butylene oxide - Google Patents

Abstract

New surfactant tri-aminopropylamino polyoxyalkylated cpds. have formula N(CH2CH2CH2NZ2)3 (I). In (I) Z is a random copolymer or block copolymer built up o m mol propylene oxide, n mol. ethylene oxide or p mol butylene oxide; where m = 0-50 (0-35); n = 1-100 (1-85) and p=0-35 (0-25); m and p are different and ratio C2H4O:C3H6O C4H8O = 1 : (0-10): (0-10)). (I) are used as tensides in cleansing agents and detergents. (I) are mainly colourless to yellow liquids and are partic. suitable for liquid compsns. contg. acid builders, e.g. citric acid. Presence of 4 active base centres renders (I) more strongly kryptocationactive (I) have good solubility in acid media. In examples, (I) were prepd. by mixing 1 mol. triaminopropylamine with 1-10 wt.% water and reacting with 6 mol C3H6O, for 3 hrs, 3-8 atmos. excess press. 100-110 degrees C. Prod. was dehydrated at 90-100 degrees C/15 mm Hg. Prod. +1-3 wt.% KOH was mixed and treated with C3H6O at 130-135 degrees C, followed by C2H4O at 120-125 degrees C.

Description

Trisaminopropylaminopolyoxalkylate The invention relates to new surface-active polyoxyalkylated compounds that have excellent surface activity, high Washing and cleaning power and low foaming tendency are.

From DT-AS 1 081 226 compounds are known which are obtained from polyalkylene polyamines, primarily ethylene diamine or diethylene triamine, propylene oxide and then ethylene oxide. These are compounds of the formula, for example where x and y are about 10 to 50 and more.

These are compounds that make excellent cleaning surfactants find use with low foaming power. You have towards other nonionics the advantage that they have even less tendency to precipitate in the acidic medium, since they contain basic centers (N atoms). But there is still a certain disadvantage in theirs Property of becoming pasty or solid at molecular weights of about 4,000, what naturally complicates their use in various areas of application. There on the other hand the cleaning power of the number of alkylene oxide groups and the ratio of ethylene oxide Depending on propylene oxide, one is often forced to take the less great option to compensate for the increase in the molecular weight by a more precise choice of the EO / PO ratio. This is especially true for liquid formulations, e.g. dishwashing detergents.

This led to the task of looking for similarly structured oxyalkylates, which no longer have these disadvantages, and we have a new class of compounds found that does justice to this task.

Another object of the invention was the method of manufacture of connections.

The new compounds obey the formula I N (CH2CH2CH2NZ2) 3 in the Z a) the remainder of one of m moles of propylene oxide, n moles of ethylene oxide and p moles of butylene oxide built-up random copolymer or b) the remainder of one of m moles of propylene oxide, n moles of ethylene oxide and p moles of butylene oxide denotes a block copolymer, where in cases a) and b) m is 0 to 50, n is 0.1 to 100 and p is 0 to 35, and m and p are different and the ratio of ethylene oxide: propylene oxide: butylene oxide = 1: (O to 10): (O to 10).

For the sake of simplicity, in the following ethylene oxide with EO, propylene oxide with Fo and -butylene oxide are designated with BuO.

The creation of the new connections is easy and plays out in such a way that, for example, 1 mole of trisaminopropylamine with a mixture oxalkylated from PO and / or-Bu0 and EO-directly in an alkaline medium (case a).

But you can also, and this more often, trisaminopropylamine initially Oxpropylieren or oxbutylieren, or both in succession and then oxäthylieren or vice versa, i.e.

first oxethylate (case b). In general, however, it is more advantageous carry out the step of oxethylation at the end.

Finally, according to a particularly advantageous variant of the If b the amine is initially bisoxalkylated with PO or BuO to the N atoms React compound and then alkoxylate further.

Starting compound for the preparation of the compounds according to the invention is trisaminopropylamine, which is made in a known manner, for example from acrylonitrile and NH3 and subsequent hydrogenation can be produced (see i.a.

J. Amer. Chem. Soc. 67, 1994-96).

If you want to prepare compounds according to case a), a mixture is left from 6 m moles of PO, 6 n moles of EO and 6 p moles of BuO in the context of the definition above Act amine. Here, m should be 0 to 50, preferably 0 to 35, n 1 to 100, preferably 1 to 85, and p 0 to 35, preferably 0 to 25-.

Here, 0 to 10 mol PO and / or 0 to 10 mol BuO come, but the number of moles of PO and BuO are fundamentally different is, i.e. m and p cannot be 0 at the same time. One of the most preferred choices is here mixed aeration with EO and PO alone (p = O). In this case, preference is given to choosing molar ratios such that there are 0.1 to 10 moles of PO for 1 mole of EO.

The oxalkylation is preferably carried out in an alkaline medium, i.e. it runs off after the addition of alkaline substances.

Substances with an alkaline reaction are understood in the invention Sense such as are generally known for oxyalkylations. These are inorganic Bases, such as alkali hydroxides, for example LiOH, NaOH, KOH, Na2CO3, K2C03, NaOOCCH3, alkaline earth hydroxides, for example Ca (OH) 2, Sr (OH) 2, Ba (OH) 2, CaC03, SrC03, BaC03, then alkali and alkaline earth alcoholates, which are from C1 to C4 alcohols preferably derived, for example NaOCH3, NaOC2H5, K-OC4Hg, Ca (OCH3) 2 and the like. Further Organic bases can also be used, especially amines, unless they are themselves the oxyalkylation reaction are accessible, for example trimethylamine, triethylamine or triisopropylamine and corresponding quaternary ammonium hydroxides. In the oxalkylation It is expedient to use 0.1 to 3, preferably, based on the amount of alkylene oxide 1 to 2 total% of alkaline substances.

The oxyalkylation generally takes place at about 80 to 1400C Pressures between 3 and 11 bar in closed vessels under inert gas, such as N2 best results.

The more preferred procedure is that of the block copolymer derivatives (case b).

Here you can add EO first and then PO and / or BuO or prefer to proceed in reverse.

Usually one works under the same reaction conditions and with the same proportions as specified for mixed aeration.

Preferably because they are particularly valuable from an application point of view Products leads, one chooses the order oxpropylation and / or oxbutylation - oxethylation. Here is a pure oxpropylation and subsequent oxethylation the most technically valuable way of working.

You can proceed in such a way that you first use the full amount above definition oxpropylated to PO and then oxethylated. But to the danger to suppress the formation of pure polyglycol ethers (polymerization of PO) one prefers initially in the context of a technically particularly valuable way of working that completely on the nitrogen atoms (bis or. hexa-) oxpropylated Trisaminopropylamine, then oxpropylated with the remaining amount of PO and oxethylated afterward.

The same molar amounts of alkylene oxides are chosen for all variants and the same molar ratios as mentioned for mixed aeration.

The particularly preferred mode of operation already mentioned is described below: For example, 6 to 10, preferably 6, mol, or a slight excess, of 1,2-propylene oxide are initially added onto one mole of amine. This addition takes place thermally, preferably analogously to the information in US Pat. No. 2,697,118, in the presence of 0.5 to 10% by weight, based on amine, of water at 80 to 120 ° C. under an inert gas, such as N2, at 4 to 11 bar within 2 to 6 hours. This creates the simply oxopropylated aminopropanols with the residues This mixture of isomers also occurs in the further oxopropylation described below, as well as in the oxpropylation according to the other variants described.

The aminopropanols are then dehydrated under reduced pressure, mixed with 0.1 to 3 wt.% alkali and then with 6m-6 mol propylene oxide implemented. The term alkali should be understood to mean the same catalysts as they are defined for mixed aeration. m gives the above number of moles Propylene oxide again, preferably m should be 2 to 35. The oxpropylation will carried out at 120 - 1400C at 4 to 9 bar within 4 to 15 hours. It It goes without saying that here, too, under inert gas in one Pressure vessel is being worked on. Then 6n moles of ethylene oxide, preferably 6 to 510 Mol, normally oxethylated at 120 to 1300C within 3 to 10 hours, with the same pressure conditions are maintained as in the oxpropylation.

The reaction can also be carried out in aprotic organic solvents, such as dioxane, tetrahydrofuran, DMF etc. are carried out, which are then removed again Need to become; however, such a variant has no additional advantages.

In many cases, the end products are colorless to yellow-colored liquids, which only become pasty in the highest molecular weight ranges within the scope of the definition. The products can be determined, among other things, by their molecular weights, nitrogen content and their cloud points be characterized.

They are excellent surfactants, especially for liquid formulations, such as machine dishwashing detergents or liquid cleaners and laundry detergents, which are mainly acidic Builders such as citric acid and the like. contain. They are basic because of their 4 active ones Centers noticeably more cryptocationally active than the oxyalkylates mentioned at the beginning according to the state of the art, which makes them significantly more soluble in acidic media. Their mostly liquid consistency allows for a wide range of molecular weights previously unachieved multitude of special applications tailor-made products to manufacture.

The following examples illustrate the invention. Parts are if not otherwise specified, parts by weight.

A: Stage I (therm.) 188 parts (1 molar part) of trisaminopropylamine and 1 - 10% by weight (based on the amine) of water are placed together in the V2A stirred autoclave, then 348 parts (6 molar parts) of propylene oxide (optionally with a 20% excess) pressed in portions.

3 hours pressing time, pressure: 3 - 8 atm, temperature 100 - 110OC: 3 Hours of stirring time.

The product is then dewatered at 90-1000/15 mm Hg.

B: catalytic. Stage product A and 1-3% by weight (based on product A) KOH . Powders are placed in a V2A stirred autoclave, then the desired amount of propylene oxide is added (minus the PO constraints contained in product A) at 130 - 1350C, then the The intended amount of ethylene oxide is pressed in portions at 120 - 1250C.

Pressing time, depending on the amount of oxide, 3 - 10 hours.

The individual connections can be seen from the following table. Molecular weights indicate mean molecular weights.

Otherwise the table contains the measurement data of the most important properties of the new products.

Determination of the cloud point (s): DIN 93 917 Surface tension: DIN 93 914 Foam height: DIN 53 902, sheet 1 Wetting effect: DIN 53 901 Explanation of the Abbreviations: MG = molecular weight PO = propylene oxide EO = ethylene oxide n.l.St. = after a long time Standing KW = no effect w.S. = active substance STP = sodium tripolyphosphate as Washer used a launder-o-meter.

A standardized fabric from the Laundry Research Institute was used as the standard wash Krefeld ("WFK") is used. T a b e l l e MG MG overall EO appearance Solubility pH value cloud points ° C upper foam, wetting effect, dist. Foam Weisswache The rest of the MG is in (5% w.v.) (5% w.v.) 1% 2% 1% surface-DIN, H2O, + 2 g / l soda in the 40-95 ° C, 45 'dirt-PO- EO- total- in in in span- 10.d.H. 1st line RT crockery WFK fabric strength Anmolekül H2O 15% 10% temperature, 40 ° C, 2nd line 70 ° C, dishwasher-proof. H2O% partly partly% BDG NaCl 20 ° C, 2 g / l sec machine 2 g w.S./l 1 g / l w.S. (Rpm) (mN / m) V2 0.5 1 2 g / l without + 2 g / l VS STP STP 6815 704 7707 9.1 yellow-oak, clear, medium- cold good, strong 10.4 - 15.0 - 37.0 0 132 47 21 92 55.4 74.2 13 highly viscous Liquid cloudy, milky-white, 0 KW KW KW after 1st St. clear, oily sediment 6815 1408 8411 16.7 yellow-oak, clear, medium- cold good, strong 9.9 about 19.0 41.5 - 37.0 0 140 54 21 90 50.1 76.6 11 viscous liquid cloudy, colorless, n.l. 0 KW KW KW St. oily Bottom 6902 1804 8894 20.3 yellow oak, cloudy, high-cold good, clear, 9.8 about 23 52.0 - 34.5 10 106 44 20 76 53.7 74.9 8 viscous liquid colorless 1.4 KW KW KW 6815 2090 9093 23.0 brownish, cloudy, medium- cold good, clear, 10.7 - 53.0 - 39.2 10 136 54 23 76 53.7 74.9 8 viscous liquid colorless 1.3 KW KW KW 6960 2920 10074 29.0 yellowish, cloudy, high - cold good, clear, 10.6 41.5 - - 40.4 40 175 93 42 46 61.3 76.9 viscous liquid colorless 5.3 KW KW KW 6931 3652 10071 33.9 yellowish, cloudy, high - cold good, clear, 10.5 49.0 - - 40.4 190 206 117 50 51 59.5 76.6 viscous Liquid colorless 25 KW KW KW 6815 4202 11205 37.5 yellowish, cloudy, extremely cold good, clear, 10.4 56.5 - - 40.6 170 KW KW 200 41 68.1 75.1 30 viscous liquid colorless 23 KW KW KW 6815 4884 11887 41.1 yellowish, cloudy, high-cold good, clear, 10.3 59.0 - - 43.0 230 KW KW 38 70.8 78.5 viscous liquid colorless 31 KW KW 190 6815 5588 12591 44.4 yellowish, very cloudy, cold good, clear, 10.4 67.5 - - 43.2 320 KW KW KW 37 72.1 79.4 highly viscous liquid colorless 43 KW KW KW 6090 704 6892 10.1 yellowish, clear, medium cold good, (20 ° C) 10.4 approx 28-30 43.0 - 42.9 0 KW KW 170 86 50.7 77.2 viscous liquid precarious, clear, trace 0 KW KW KW yellowish 5974 1188 7350 16.2 yellowish, clear, medium cold good, strong 10.5 about 21 48.5 - 39.1 0 168 68 26 83 49.8 76.4 viscous liquid cloudy, colorless, 0 KW KW KW after 1st St. more oily Sediment 5800 1496 7484 20.0 yellow oak, cloudy, high - cold good, strong 9.9 28.5 50.5 - 36.3 10 142 72 28 91 52.9 75.0 13 viscous liquid, opaque, colorless 1.4 KW KW 164 5974 1804 7966 22.6 yellow oak, clear, medium- cold good, clear, 10.3 about 34-36 59.5 - 43.8 10 KW KW 64 53.3 79.0 viscous liquid trace yellowish 1.5 KW KW KW 5974 2402 8564 28.0 Feel cloudy, yellowish, cold good, clear, 10.4 49.5 65.5 - 42.5 220 KW KW KW 48 65.1 78.4 2 medium viscosity liquid trace yellowish 33 KW KW KW (Tabel Cont.) MG MG Total EO- Outer Solubility pH value Cloud points ° C Upper Foam, wetting effect, dist. Foam whiteness Remainder of the MG stops in (5% w.v.) (5% w.v.) 1% 2% 1% surface DIN, H2O, + 2 g / l soda in the 40-95 ° C, 45 'dirt-PO- EO- total- in in in span- 10.d.H. 1st line RT crockery WFK fabric strengthens ananmolecule H2O 15% 10% voltage, 40 ° C, 2nd line 70 ° C, washing at least. H2O% partly partly% BDG NaCl 20 ° C, 2 g / l sec machine 2 g w.S./l 1 g / l w.S. (Rpm) (mN / m) V2 0.5 1 2 g / l without + 2 g / l VS STP STP 6090 2640 8918 29.6 yellow, slightly cloudy, medium-cold good, clear, 9.2 39.5 - - 38.5 110 KW KW 48 64.9 76.4 2 highly viscous liquid trace yellowish 15 KW KW KW 5974 2992 9154 32.7 cloudy, yellowish, medium-cold good, clear, 10.5 54.5 72.0 - 40.0 200 KW KW KW 43 72.6 78.8 5 viscous liquid trace yellowish 30 KW KW KW 5974 3608 9770 36.9 weak, yellowish, strong cold good, clear, 10.5 about 48-54 70.5 - 39.6 220 KW KW 164 42 70.7 78.4 6 cloudy, medium-viscosity trace yellowish 33 KW KW KW liquid 5974 4202 10364 40.5 yellowish, cloudy, medium-cold good, clear, 10.5 59.0 73.0 - 42.4 240 KW KW KW 41 72.9 78.7 4 viscous liquid trace yellowish 36 KW KW KW 5974 4796 10958 43.8 yellowish, cloudy, medium warm good, clear, 10.4 63.0 76.0 - 41.5 220 KW KW KW 40 75.8 79.1 5 viscous liquid trace yellowish 33 KW KW KW 6206 6402 12796 50.1 light brown, firm paste warm good, clear, 9.0 83.5 84.0 51.0 39.8 350 KW KW KW 42 59.8 72.8 8 Track yellowish 52 KW KW KW 5800 13992 19980 70.1 light brown, waxy warm good, clear, 9.2> 100 - 71.0 44.9 330 KW KW KW 43 58.2 71.4 Product colorless 46 KW KW KW 5017 499 5528 9.0 clear, yellowish, medium cold good, strong 10.4 20.0 30 - 41.3 0 90 53 24 95 60.4 75.9 11 highly viscous, Liquid cloudy, milky - 0 KW KW KW white 4814 550 5364 10.2 yellowish, clear, high-cold good, strong 10.1 approx 18.5 34.5 - 36.9 0 133 46 22 102 51.8 73.8 2 viscous Liquid cloudy, milky - 0 KW KW KW white 5017 1012 6041 16.8 yellowish, clear, high-cold good, strong 10.1 about 25 47.5 - 38.9 0 180 72 32 90 50.0 77.3 12.5 viscous Liquid cloudy, colorless 0 KW KW KW trace, sediment 4814 1232 6234 19.8 yellowish, clear, high-cold good, strong 10.1 about 20 50.5 - 37.4 0 KW 104 43 91 52.0 74.6 2 viscous Liquid cloudy, colorless 0 KW KW 150 5017 1496 6525 22.9 yellowish, clear, medium- cold good, weak 10.2 about 27-30 56.5 - 41.4 10 288 162 80 73 50.3 78.3 17.5 viscous Liquid cloudy, colorless 1.5 KW 280 190 5017 2002 7031 28.5 yellowish, clear, medium cold good, clear, 10.2 41.0 64.5 - 43.2 120 KW KW 152 55 61.0 79.0 15 viscous liquid Trace yellowish 18 KW 280 183 5017 2508 7537 33.3 yellowish, clear, medium cold good, clear, 10.0 53.0 67.5 - 42.9 200 KW KW 237 49 64.6 78.9 viscous liquid trace yellowish 30 KW KW KW 5017 2992 8021 37.3 yellowish, cloudy, fine - cold good, clear, 10.1 54.5 72.0 - 41.4 240 KW KW KW 42 70.3 77.9 disperse, medium-viscosity trace yellowish 36 KW KW KW liquid 5017 3498 8703 40.2 yellowish, very cloudy, cold good, clear, 10.2 60.5 73.5 - 44.0 130 KW KW KW 41 71.2 78.9 19 medium viscosity liquid trace yellowish 20 KW KW KW (discontinues) (Table cont.) MG MG total EO-Ge External solubility pH value Cloud points ° C Upper foam, wetting effect, least. Foam whiteness Remainder of the MG stops in (5% w.v.) (5% w.v.) 1% 2% 1% area- DIN, H2O, + 2 g / l soda in the 40-95 ° C, 45 'dirt-PO- EO- total- in in in chip- 10.d.H. 1st line RT crockery WFK fabric strength ananmolecule H2O 15% 10%, 40 ° C, 2nd line 70 ° C dishwasher minimum. H2O% partly partly% BDG NaCl 20 ° C, 2 g / l sec machine 2 g w.S./l 1 g / l w.S. (Rpm) (mN / m) V2 0.5 1 2 g / l without + 2 g / l VS STP STP 5017 4004 9209 43.5 yellowish, very cloudy, cold good, clear, 10.2 73.0 78.0 - 45.6 240 KW KW KW 40 75.0 78.0 medium viscosity liquid trace yellowish 36 118 77 50 (sets ab) 5220 6600 12008 55.0 brownish, solid paste warm good, clear, 9.1 86.5 83.0 57.5 40.3 350 KW KW KW 40 58.4 72.0 12 Trace yellowish 52 KW KW 166 4814 11572 16574 69.8 light brown, waxy - warm good, clear, 9.3> 100 - 71.0 43.8 240 KW KW KW 43 57.9 70.4 total product colorless 34 KW KW KW 4002 400 4590 8.7 clear, bleached, high- cold good, strong 10.4 19.5 29.5 - 41.0 0 130 60 30 90 62.2 77.1 10 viscous liquid cloudy, milky - 0 KW KW KW white 4002 801 4991 16.0 clear, yellowish, high - cold good, strong 10.35 about 24 47.5 - 42.1 0 250 107 40 84 60.0 78.1 13 viscous liquid cloudy, colorless 0 KW KW KW 4002 1002 5192 19.3 clear, yellowish, high-cold good, cloudy 10.6 approx. 29 60.0 - 43.2 0 KW KW 120 75 63.9 78.2 6 viscous liquid trace yellowish 0 KW KW KW 4002 1593 5783 27.5 clear, yellowish, high-cold good, clear, 10.4 30.5 62.0 - 43.0 0 KW KW 216 63 62.4 78.5 11 viscous liquid trace yellowish 0 KW KW 170 4014 2000 6202 32.2 clear, yellowish, high-cold good, clear, 10.25 58.0 75.0 - 43.2 140 KW KW KW 42 70.2 77.2 viscous liquid trace yellowish 29 KW 300 100 4106 2552 6846 37.3 cloudy, slightly yellow - cold good, clear, 10.25 58.0 75.0 - 43.2 140 KW KW KW 42 70.2 77.2 lichen, highly viscous trace of yellowish 29 KW 300 100 liquid 4124 2864 7176 39.3 cloudy, yellowish, high - cold good, clear, 10.25 59.0 73.5 - 42.4 180 KW KW KW 42 69.8 76.8 viscous liquid trace yellowish 37 300 200 87 4002 3203 7393 43.3 cloudy, yellowish, high - cold good, clear, 10.4 66.5 78.5 - 43.7 50 KW KW KW 36 71.4 77.3 viscous liquid trace yellowish 10 96 75 50 4014 7801 12003 65.1 Brownish, solid paste warm, good, clear, 9.5 95.0 85.5 64.0 41.8 380 KW KW KW 39 58.1 70.0 59 trace yellowish 56 270 190 140 4770 14784 18742 78.9 brown, waxy warm good, clear, 9.4> 100 - 72.0 47.5 320 KW KW KW 50 57.3 70.7 Product colorless 45 KW KW KW 3039 339 3566 9.5 yellow, clear, highly viscous cold good, cloudy 9.1 25.0 42.5 - 39.7 0 KW 220 63 85 51.9 73.8 4 kose liquid colorless 0 KW KW KW 2999 598 3785 15.8 yellow, clear, highly viscous, good, cloudy, 9.1 27.0 50.0 - 39.5 0 KW KW 145 79 51.2 71.1 14 clear liquid colorless 0 KW KW KW 2909 900 4087 22.0 clear, yellowish, medium-cold good, clear, 10.7 about 30 59.5 - 43.2 0 KW KW KW 78 62.2 79.1 15 highly viscous Liquid trace yellowish 0 KW KW KW 4039 1236 4463 27.7 trace cloudy, yellowish, cold good, clear, 10.6 about 31 66.0 - 44.5 0 KW KW KW 62 66.6 79.2 18 medium-high viscosity Trace yellowish 0 KW KW 105 liquid (Table cont.) MG MG total EO-Ge External solubility pH value Cloud points ° C Upper foam, wetting effect, least. Foam whiteness Remainder of the MG stops in (5% w.v.) (5% w.v.) 1% 2% 1% area- DIN, H2O, + 2 g / l soda in the 40-95 ° C, 45 'dirt-PO- EO- total- in in in chip- 10.d.H. 1st line RT crockery WFK fabric strength anmolecule H2O 15% 10%, 40 ° C, 2nd line 70 ° C dishwasher minimum. H2O% partly partly% BDG NaCl 20 ° C, 2 g / l sec machine 2 g w.S./l 1 g / l w.S. (Rpm) (mN / m) V2 0.5 1 2 g / l without + 2 g / l VS STP STP 3045 1540 4773 32.3 slightly cloudy, yellowish, cold good, clear, 10.35 44.5 70.0 - 43.6 10 KW KW KW 50 67.9 78.6 19 highly viscous liquid trace yellowish 36 KW KW 114 2999 1800 4987 36.1 slightly cloudy, yellowish, cold good, clear, 10.4 54.5 73.0 - 44.3 10 KW KW KW 41 66.5 79.0 highly viscous liquid trace yellowish 2 KW KW KW 2999 2099 5286 39.7 cloudy, yellowish, high - cold good, clear, 10.55 63.5 78.5 - 45.4 130 KW KW KW 41 70.5 76.7 viscous liquid trace yellowish 27 163 94 58 2999 2398 5585 42.9 cloudy, yellowish, high-cold good, clear, 10.6 66.5 79.0 - 44.4 20 KW KW KW 39 70.9 77.1 viscous liquid trace yellowish 4 136 64 57 2784 6996 9968 70.2 light brown, very firm, warm, clear, 9.5> 100 - 72.0 46.7 350 KW KW KW 46 56.5 71.5 tough Paste (almost wax- colorless 50 KW KW KW-like 2001 196 1992 8.2 yellow, clear, highly vis- cold good, an- 10.6 31.0 47.5 - 40.9 0 KW KW KW 77 51.1 71.2 12.0 cold liquid cloudy, colorless 0 KW KW KW 2030 440 2658 16.5 yellow, clear, highly vis- cold good, clear, 10.8 33.0 57.5 - 42.0 0 KW KW KW 74 52.6 69.9 5.5 smooth liquid colorless 0 KW KW KW 2001 598 2787 21.5 yellow, clear, high vis- cold good, clear, 10.2 37.0 61.5 - 41.6 0 KW KW KW 71 51.6 68.3 5.0 clear liquid colorless 0 KW 170 112 2001 801 2990 26.8 yellowish, practically cold good, clear, 10.1 39.5 78.0 - 42.2 0 KW KW KW 71 51.8 70.6 5.5 clear, highly viscous colorless 0 103 77 47 liquid 2001 1003 3192 31.4 yellow-brown, slightly cold good, clear, 9.4 42.0 73.0 - 42.3 0 KW KW KW 50 52.3 72.2 cloudy, highly viscous colorless 0 96 66 45 liquid 1972 1201 3361 35.7 yellow, slightly cloudy, cold good, clear, 9.4 43.5 75.0 - 42.8 0 KW KW KW 45 52.8 71.5 highly viscous Liquid, colorless 0 KW KW KW 1972 1399 1559 39.3 yellow, clear, highly viscous good, clear, 9.1 46.0 77.0 - 43.4 0 KW KW KW 45 53.6 70.9 viscous liquid, colorless 0 KW KW 55 2013 1615 3816 42.3 yellow, slightly cloudy, cold good, clear, 9.1 59.0 81.0 - 43.6 0 KW KW KW 42 55.4 71.0 highly viscous liquid, colorless 0 74 55 36 1003 198 1389 14.4 yellow, clear, highly viscous cold good, clear, 11.0 55.0 71.0 - 46.6 10 KW KW KW 51 54.7 73.4 Liquid, trace yellowish 1.4 KW KW KW 1002 308 1487 20.5 yellow, clear, highly viscous cold good, clear, 11.1 60.0 76.5 - 46.5 10 KW KW KW 51 56.0 74.4 liquid, trace yellowish 1.4 KW KW KW 1003 502 1693 29.7 yellow, cloudy, high-cold good, clear, 10.9 64.0 81.5 - 46.1 20 KW KW KW 50 55.5 74.3 viscous liquid, Yellowish trace 2.8 KW KW KW (Table cont.) MG MG Total EO-Ge External solubility pH value cloud points ° C upper foam, wetting effect, dist. foam Whiteness rest of the MG stop in (5% w.v.) (5% w.v.) 1% 2% 1% surface- DIN, H2O, + 2 g / l soda in the 40-95 ° C, 45 'dirt-PO- EO- total- in in in span- 10.d.H. 1st line RT crockery WFK fabric strength ananmolecule H2O 15% 10% temperature, 40 ° C, 2nd line 70 ° C dishwasher minimum. H2O% partly partly% BDG NaCl 20 ° C, 2 g / l sec machine 2 g w.S./l 1 g / l w.S. (Rpm) (mN / m) V2 0.5 1 2 g / l without + 2 g / l VS STP STP 1003 704 1895 37.2 yellow, clear, high-cold good, clear, 11.0 78.0 87.0 - 46.7 20 KW KW KW 50 54.9 74.0 viscous liquid, trace yellowish 0 KW KW KW 1003 801 1992 40.2 yellow, cloudy, high- cold good, clear, 10.8 69.5 88.0 - 45.7 10 KW KW KW 62 55.9 73.8 11 viscous liquid, colorless 0 KW KW KW 10440 20504 31132 65.9 slightly brownish, warm good, clear, 9.2 100 - 70.0 44.7 240 KW KW KW 58 58.5 70.5 2 waxy product colorless 34 KW KW KW 6264 17336 23788 72.9 light brown, waxy - warm good, clear, 9.3 100 - 72.0 44.6 350 KW KW KW 44 58.4 70.6 2 total product colorless 50 KW KW KW 4478 7040 11706 60.1 light brown, very firm warm good, clear, 9.3 93.5 85.5 61.0 41.5 370 KW KW KW 40 59.5 73.1 20 Paste trace yellowish 54 290 220 150 812 660 1660 39.8 yellow-brown, clear, hold good, clear, 10.9 79.0 92.0 - 49.6 0 KW KW KW 67 55.6 74.5 5 highly viscous liquid colorless 0 KW KW KW 348 123 647 29.6 yellow, clear, highly viscous cold good, clear, 11.4 53.0 - - 50.5 0 267 108 34 54 - - 18 peculiar liquid trace yellowish 0 KW 230 190

Claims (7)

Claims (1.) Compounds of the formula I N (CH2CH2CH2NZ2) 3 I in Z a) the remainder of one of m moles of propylene oxide, n moles of ethylene oxide and p moles of butylene oxide built-up random copolymer or b) the remainder of one of m moles of propylene oxide, n moles of ethylene oxide and p moles of butylene oxide are block copolymers, where in cases a) and b) m is 0 to 50, n is 1 to 100 and p is 0 to 35, and m and p are different and the ratio of ethylene oxide: propylene oxide: butylene oxide = 1: (0 to 10): (0 to 10) is. 2. Compounds according to claim 1 according to formula I, in which in the case b) the propylene oxide and / or butylene oxide block is bonded to the N atom. 3. Compounds according to claim 1 or 2 according to formula I, in which Z stands for the remainder of a block copolymer of propylene oxide and ethylene oxide, where m is 2 to 35 4. Process for the preparation of compounds of the formula I according to claim 1, characterized in that one mole of trisaminopropylamine a) a mixture of 6m moles of propylene oxide, 6n moles of ethylene oxide and 6p moles of butylene oxide lets act, or b) first m moles of propylene oxide and p moles of butylene oxide and then Allowing n mol of ethylene oxide or vice versa to act, m, n and p according to claim 1 are defined. 5. The method according to claim 4, characterized in that one first Lets propylene oxide act. 6. The method according to claims 4 or 5, characterized in that one first to 1 mole of trisaminopropylamine 6 to 10, preferably h ol propylene oxide The aminopropanol obtained is allowed to act thermally with 6 ml-moles of propylene oxide further oxalkylated and then allowed to act 6n mol of ethylene oxide. 7. Use of compounds according to Claims 1 to 3 as surfactants in cleaning agents and detergents.