Particulate materials, particularly fine particles of clay animal litter, are agglomerated using a reticulated cellulose product formed by growing Acetobacter. Treatment with such reticulated cellulose also enhances the liquid absorbency of particulate materials.
The purpose of the present invention is to provide a convenient method for restoring the various properties of BC even after it is once dried. The present invention relates to a method for processing a bacterial cellulose comprising dehydrating and drying under tension the bacterial cellulose produced in an agitated culture followed by homogenization, and to a method for processing a bacterial cellulose comprising dehydrating and drying the bacterial cellulose produced in an agitated culture under such conditions that a degree of planar orientation (h1/h2) (wherein h1 and h2 mean the height of a peak originating in the crystallographic plane (110) and the crystallographic plane (110), respectively, in a diffraction curve obtained with X-ray diffractometry by a reflection method) will be 2 or more, followed by homogenization. An excellent retention aid for fillers and sheet with a high strength may be prepared by using the bacterial cellulose obtained by the above methods.
Rheologically modified compositions, and rheologically modified fluid compositions prepared therefrom, containing reticulated bacterial cellulose in a polyol base fluid, are disclosed. The amount of reticulated bacterial cellulose present in the composition is an amount effective to viscosify the polyol base fluid.
A method for producing high-alumina bodies with superior chemical properties at reduced sintering temperatures, including the steps of providing an alumina powder precursor, adding about 4 weight percent magnesia powder precursor, homogenizing the resultant green powder precursor, pressing a green body from the green powder precursor, removing residual moisture and organic material from the green body, and firing the green body to about cone 13, wherein the resulting high-alumina body is substantially non-vitreous, has a substantially uniformly sized grain structure, is very resistant to dissolution in molten aluminum, and has superior resistance to chemical attack over substantially the entire pH range.
