DE3803966A1 - PROCESS FOR INCREASING THE DENSITY OF DRY DETERGENTS - Google Patents

Description

Spray-dried detergents of conventional composition have, depending by composition and method of operation, in general bulk densities from 250 to 450 g / l (grams per liter) and only in exceptional cases of 480 g / l. More recently, powders have higher levels Bulk weights, for example, from 550 to 750 g / l in increasing Measures found in interest, as they have less packaging material require and thus a raw material savings and a reduction in waste enable.

There are also spray-dried detergents with bulk weights between 550 and 900 g / l and process for their preparation known, for. B. from EP 1 20 492 (US 45 52 681), but is these are special compositions rich in nonionic surfactants. An additive to anionic surfactants, especially soaps, causes a strong decrease of the bulk density to values below 500 g / l. Also a granulation of detergent ingredients with the addition of granulating liquids, such as water or nonionic Surfactants, favors high bulk densities. The granulation with water but usually requires the presence larger proportions of crystal water-binding salts, mostly of Phosphates such as tripolyphosphate or soda. This means, however likewise a restriction with regard to the absence of recipes and complicates the production of p-free or p-poor detergent. The On the other hand, spraying nonionic surfactants increases the  Bulk density only slightly, if not greater proportions thereof which in turn is the production of specially compounded Basic powder with high absorbency requires.

DE-A-25 48 639 teaches a method for bulk density increase granulated or spray-dried detergents in one Device known in the art under the name "Marumerzier" is known and usually used for To round off extruded particles of irregular shape. This Device consists of a vertical cylinder with smooth Side walls and a superficially roughened turntable, the rotated in the lower part of the cylinder. The device is in intended primarily for intermittent operation. The biggest available plants of this type with a diameter of Turntables of approx. 1 m can only handle a maximum of 45 to To receive 50 kg of tower powder. At a residence time of about 10 minutes of the powder in the device according to Example 3 of the cited DE-A is the throughput, based on an average Hourly output of a medium spray tower from 5 to 25 t (tons) much too low, or it would be a very large Number of constantly operating "Marumerizers" to work with to keep up with the tower's performance. On the other hand it is uneconomical, the tower including the elaborate heating system only to operate intermittently and thus to the low Adjust the performance of the granulator. It is also not appropriate the spire only sporadically for the production of pregranules use this to stockpile this and the tower in the meantime otherwise use. DE-A-25 48 639 teaches that the Pre-granulate or spray powder at short notice, d. H. within less Minutes, in the "Marumerizer" must be further processed to one to achieve significant powder compaction.

It was therefore the task of avoiding the disadvantages described and to develop a process that works continuously, higher throughputs and shorter residence times allowed, maximum flexibility in terms of quantity, physical Nature and composition of the spray powder guaranteed as well as the production time and a lower Investment and energy required.

Object of the invention with which these objects are achieved is a method of increasing the density of the spray-dried Detergent without the use of liquid granulation aids, thereby characterized in that the spray-dried, a bulk density of at least 400 g / l having powder continuously in a cylindrical, horizontally arranged or slightly against the Horizontal inclined cylindrical mixing drum with smooth inner wall in which axially rotates a shaft with equipped radially arranged striking tools, whose length (calculated from the central axis) 80% to 98% of the inner radius of the Drum is, and that the rotational speed of Wave regulated so that at a mean residence time of the powder in the drum from 10 to 60 sec. and constant powder throughput the Froude number is between 50 and 1000.

The spray-dried, the drying tower leaving powder (hereinafter short referred to as "tower powder") is in the interest of a desired high final density an initial density (liter weight) of at least 350 g / l. Preferably, the density of the Tower powder at least 400 g / l. Specific light tower powder, for example, those containing zeolite, can be more compact than those already higher  Have initial density, but they achieve a lower overall Final weight as a relatively heavy tower powder.

With regard to the grain size or the grain spectrum of the tower powder There are no special requirements. Rather, it can be after the method powder with a broad as with a narrow grain spectrum to process. It is also not necessary to previously gross shares sift out the tower powder, as in conventional powders is required. Rather, the process causes that coarse Shreds fractions, compacts loose voluminous components, irregularly shaped rounded and finest particles compacted become. Overall, the method causes a reduction in medium grain size.

The leaving the tower powder can immediately in the inventive Be processed. The temperature of the powder is not critical, especially if it's good has dried through, d. H. if its water content is theoretical Water binding capacity is equal to or lower. at plastic, especially water-rich powders, it should 50 ° C, preferably 40 ° C, do not exceed, as they are generally sets when the powder pneumatically promotes. The powder can also be stored for any length of time, but generally only in case of production interruptions Role play. It is always advantageous to have a continuous flow of material, why the inventive method due to the continuous operation is particularly suitable.

The powder should be pourable and not sticky. However, too the processing of slightly sticky powder possible, if one simultaneously water-soluble, moisture adsorbing salts or  Introduces a finely divided adsorption material in the mixer. suitable Salts are z. As sodium sulfate, soda or phosphates or Polyphosphates, in proportions up to 20 wt .-%, preferably to can be mixed to 10 wt .-%. Suitable adsorbents are zeolite and finely divided silica. Preference is given to finely divided, d. H. having a particle size of at most 10 microns Zeolite NaA in proportions up to 4% by weight, preferably 0.5 to 3% by weight added.

The mixing device used for the practice of the method consists of an elongated mixing drum of substantially cylindrical Shape, which is horizontal or moderately descending against the horizontal is stored and with at least one filler neck or-funnel and a discharge opening equipped is. Inside, a central, rotatable shaft is arranged carries several radially aligned impact tools. These should when rotating a certain distance from the smooth inner wall of the Drum have. The length of the striking tools should be 80% to 98%, preferably 85% to 95% of the inner radius of the mixing drum be.

The shape of the striking tools can be arbitrary, d. H. you can straight or angled, of uniform cross-section or of theirs Ends pointed, rounded or broadened. Your cross section may be circular or angular with rounded edges. Also different shaped tools can be combined. proven have such with teardrop to wedge-shaped cross-section, a flat or rounded surface in the direction of rotation points, as compared with such tools, the compression effect outweighs the crushing effect. The tools can in order Avoiding imbalances diametrically in pairs or in a star shape  be attached to the shaft. As advantageous has a spiral Arrangement proved. The number of tools is not critical, but it is recommended in the interest of high efficiency to arrange them at a distance of 5 to 25 cm. Furthermore is it is advantageous to mount them rotatably on the shaft, whereby one has the possibility of the horizontal conveyance of the mixed material To influence that one has a flat side surface of the Tools at an oblique angle in the direction of material flow established. The shape of the tools does not need either rather, it is possible to have tools with more to arrange condensing and more promoting effects alternately.

The conveyance of the mix in the mixer can also by additional Conveyor blades or be accomplished or accelerated. These buckets can be used individually or in pairs between the Be arranged mixing tools. The degree of promotion can be through the angle of attack of the blades are regulated.

The inner radius of the mixer is, depending on the desired Throughput, suitably 10 to 60, preferably 15 to 50 cm, its internal length 70 to 400 cm, preferably 80 to 300 cm and the ratio of inner length to inner radius 4: 1 to 15: 1, preferably 5: 1 to 10: 1. With these dimensions is the number of impact tools usually 10 to 100, mostly 20 to 80. The inner wall of the cylinder should be blank to a to avoid unwanted sticking of the powder. For smaller dimensions the speed of rotation of the shaft is below the Considering the Froude number above 800 rpm (revolutions per Minute), usually between 1000 and 3000 rpm. For larger mixers it can be reduced accordingly.  

The residence time of the powder in the mixer depends on the power ability of the plant and according to the size of the target Effect. It should not be less than 10 seconds and not more than 60 seconds be. Preferably, it is 20 to 50 seconds. It leaves by the inclination of the mixer, by the shape and arrangement the striking and conveying tools and to some extent also by affect the amount of powder supplied and removed. So can be reduced by a reduction of the output cross section certain backwater and thus an extension of the residence time in effect the mixer. The mixer should be operated so that after the start-up time a constant powder throughput takes place, d. H. that the amount of the supplied and the removed powder at any time is the same size and constant.

An essential measure for the operation of the mixer is the Froude Number, a dimensionless number, determined by the relationship

is given (w = angular velocity, r = length of the tools from the central axis, g = acceleration due to gravity). The Froude number should be 50 to 1200, preferably 100 to 1000 and in particular 150 to 800.

As a result of the mechanical processing, the powder may be slightly heat. However, additional cooling is generally dispensable or only required if the supplied Powder at elevated temperature tends to stick. This problem However, can be advantageous by a previous sufficient  Cooling of the tower powder, for example in the pneumatic Promotion, solve.

If the above conditions are met, a continuous, trouble-free process execution with high throughputs possible. In the mixer, a process takes place, the like can be described.

The registered powder is from the rotating impact tools taken and tifft on the mixer inner wall, without at this however, to stick. At best, it is formed at short notice a thin powder coating, but constantly renewed and always again the bare inner surface of the mixer come to light leaves. The powder particles thus describe a spiral movement from the mixer input to the mixer output. Unless the powder adheres to the inner wall for a long time, so that a powder layer which scrapes off the rotating tools must be, the powder is too moist, or too sticky, or too too warm. This non-stationary state causes the Mixture warmed excessively and the mixer is full. One can the emergence of such coverings by the described Counteract the addition of adsorbents.

The products obtained have opposite to the tower powder used an increased by 100 to 200 g / l bulk density, are excellent flowable and require no after-treatment, especially no drying and no screening enlarged or lumpy agglomerates. You can therefore immediately after leaving the mixer, if necessary after admixing another Powder ingredients such as bleaches (eg, sodium perborate as Monohydrate or tetrahydrate), bleach activators (e.g.  granulated tetraacetylethylenediamine), enzyme granules, defoamer (for example, silicone or paraffin applied to a carrier material). Defoamer), filled directly into the shipping container become. Of course it is also possible to have two or more separately prepared tower powder of different composition to treat together in the mixer or just one of them compact and a second subsequently add.

Examples

It was used a horizontally arranged mixer whose cylindrical interior has a radius of 15 cm and an inside length of 125 cm. In the inlet area (length 30 cm) were at the Inner shaft several conveyor blades arranged spirally. In the subsequent mixing section between inlet and outlet were on the inner shaft first 5 pointed, angled at their ends and then 25 other mixing tools mounted spirally, the latter having a wedge-shaped cross-section with rounded edges Have corners. The distance of the tools to the inner wall of the cylinder was 0.5 cm, resulting in a ratio of tool length from central axis to the inner wall of the mixer of 96.7% of Inner radius resulted. To support the promotion effect were between the mixing tools inclined conveyor blades (Total number 10) in a spiral arrangement. The size of the Outflow opening could be regulated by means of a slide. In In the following examples 1 to 3, this slider was set to that in continuous operation a slight backwater and thus a uniform filling state in the mixer formed. In In Examples 1 to 3, the rotational speed was 1500 rpm and the average residence time was 20 to 60 sec. in the average 30 to 40 sec. The mixer was spray-dried  Powder fed, after leaving the Turmaustrags on a pneumatic conveyor was transported and a temperature of 30 ± 2 ° C had.

The composition of the powder and the throughput in tons per Hour (t / h) and the liter weight before and after the treatment are shown in Table I. The ingredients a-m as well as the Water and most of the sodium sulfate (component n) accounted for the tower spray powder. The remaining portion of sodium sulfate and the minor components served as a granulation basis and as encasing substances for those listed under p to r Ingredients. These were together with the perborate (the was sprayed with the perfume) subsequently treated Powder mixed. The resulting bulk density of the respective Finished Mixture A is also indicated (each in g / liter).

The abbreviations mean Na-ABS Sodium dodecylbenzenesulfonate (C _10-13 ) FA + x EO Fatty alcohol + x mol of attached ethylene oxide STP Sodium tripolyphosphate (anhydrous) AA-MA Acrylic acid: maleic acid 3: 1 (MW 70,000) phosphonate Ethylenediamine tetramethylene-Na₆ salt NTA Nitrilotriacetic Na₃ salt TAED tetraacetylethylenediamine

The powders proved to be well free-flowing, non-dusting and both dissolved by sprinkling into the wash by hand as even with automatic spraying in household washing machines fast, without lumps and residue-free.  

In a vibration test, with a mechanical load during Transport of the packs was simulated, no segregation occurred the powder components.

In another series of experiments in each case 2% of zeolite from the Tower powder recipe eliminated and instead as a powder during added to the mixing process. It was a finished product B with obtained higher bulk density.  

Example 4

Starting from a composition according to Example 2 was a Tower powder with a zeolite content of 17% by weight without the non- ionic surfactant component (c) and reduced to 1% content on the copolymer (component g). As 2nd powder component was a granules of 55 parts by weight of zeolite, 9 Parts by weight of the copolymer, 19.8 nonionic surfactant according to Component (c), 4.2 parts by weight of sodium sulfate and 12 parts by weight Water used. Both powder components were in the Mixer mixed together, the 2nd powder component in was used in such an amount that the content of the finished product (as in Example 2) total 25 wt .-% was. The mixture tended to stick in the processing process Mixer. The bulk density after compaction was 538 g / l and in the finished product 573 g / l. Were another 2% of the zeolite from the Turpulver eliminated and fed as a powder in the mixing process, no glued on and the bulk weights amounted 570 (compacted) and 650 (finished product).

Example 5

Example 2 was repeated, but the drying in the spray at slightly elevated temperature, which causes the Water content in the tower powder decreased by 1.5%. These powders were taken immediately at the tower discharge and at a temperature processed from 80 to 85 ° C in the manner indicated. There were the following bulk densities are determined:

Tower powder 500 g / l, after compaction 661 g / l,
Finished product A 685 g / l,
Finished product B 729 g / l.

Claims (9)

1. A method for increasing the density of spray-dried detergents without the use of liquid granulating, characterized in that the spray-dried, a bulk density of at least 350 g / liter having powder continuously in a cylindrical, horizontally arranged or slightly inclined to the horizontal cylindrical mixing drum with a smooth inner wall in which axially rotates a shaft equipped with radially arranged striking tools whose length (calculated from the central axis) is 80% to 98% of the inner radius of the drum, and in that the rotational speed of the shaft is regulated so that at a medium Residence time of the powder in the drum of 10 to 60 sec and constant powder throughput the Froude number is between 50 and 1200. 2. The method according to claim 1, characterized in that the Length of rotating tools 85% to 96% of the inner radius the drum is. 3. The method according to claim 1 and 2, characterized in that the bulk density of the supplied tower powder 420 to 550 g / l is. 4. The method according to claim 1 to 3, that the average residence time of the powder is 20 to 50 sec. 5. The method according to claim 1 to 4, characterized in that the Froude number is 100 to 1000.   6. The method according to claim 1 to 5, characterized in that the temperature of the powder does not exceed 50%. 7. The method according to claim 1 to 7, characterized in that to the powder up to 5 wt .-% of finely divided adsorbents admixed. 8. The method according to claim 7, characterized in that the Powder 0.5 to 3 wt .-% of finely divided dry zeolite admixed. 9. The method according to one or more of the preceding Claims, characterized in that one several Powder components processed simultaneously.