Figure 9: Granules in varying capil

Figure 9: Granules in varying capillary state as defined by Rumpf [62].
All these types can be found in detergent granules.

a) Dense granule b) Porous granule c) Agglomerate d) High porosity
Figure 10: Different types of detergent granules containing surfactant [58, 60]
Figure 10 depicts generalised structures as described above. Examples of cross-sections of detergent granules are shown below the four schematic structures in the figure. The dense system in Figure 10a is typical for a high shear mixer granulation process e.g. European non-tower detergent powder (section 4.1). Almost no porosity is found and the coarse solids are not densely packed. Figure 10b shows a sodium LAS adjunct manufactured via dry neutralisation and containing a lot of porosity generated by carbon dioxide released during the neutralisation process. Figure 10c shows an agglomerate of primaries. The primaries may either be pre-granulated material or relatively coarse raw material solids. Here the porosity has become the predominantly continuous phase rather than the solids or the binder phase. Binding of the primaries is the main issue in this type of structure. The given example is a granule bound by a melting-type binder and produced in a fluidised bed [cf. 63]. The last type of granule structure depicted (Figure 10d) is one where the porosity is entrapped by a shell formed by bridging particles, rather than porosity being interstitial space between attached primary particles. This requires some “blowing action” as often found in non-disperse systems such as polymer foams, or products manufactured by the reactive foaming process such as bakery products produced using sodium or ammonium bicarbonate, or citric acid [11, 34, 64]. Here binding between primaries is crucial to retain the high amount of porosity and still form a mechanically strong granule. The low bulk density of the fluidised bed granule based on sodium sulphate generated in-situ is an example of such a granule that shows a high amount of porosity and rapid dissolution [33]. Looking at the variety of granulation processes on offer, it is clear that the granule structure can be varied even further. Figure 10 also schematically depicts the variation in porosity in granules produced via different processes.
The properties of a granule are a direct consequence of the granule structure and the characteristic of the used raw materials. Hence an optimisation process of granule properties needs a systematic approach based on an understanding of granule structure formation.