A method for the disintegration and fluid drying of sugar beet material which prevents the material's degradation reaction from taking place and which includes the steps of disintegrating the sugar beet material to particles with a particle surface area of at least 2.0 cm.sup.2, and subsequent immediate exposure of the disintegrated material to a drying gas(es) at a temperature of 25° C. to 160° C. and a flow rate of 5 m.s.sup.31 1 to 40 m.s.sup.−1, where the relative humidity of the drying gas(es) at the inlet to the drying space is at most 85%; and subsequent mixing of the disintegrated material with a flow of drying gas(es) until attaining a value of dry matter of at least 70% by weight.

A method for the disintegration and fluid drying of sugar beet material which prevents the material's degradation reaction from taking place and which includes the steps of disintegrating the sugar beet material to particles with a particle surface area of at least 2.0 cm.sup.2, and subsequent immediate exposure of the disintegrated material to a drying gas(es) at a temperature of 25° C. to 160° C. and a flow rate of 5 m.s.sup.31 1 to 40 m.s.sup.−1, where the relative humidity of the drying gas(es) at the inlet to the drying space is at most 85%; and subsequent mixing of the disintegrated material with a flow of drying gas(es) until attaining a value of dry matter of at least 70% by weight.

A method for the qualitative distribution of sugar beet dry matter to products usable in food production, which includes the steps: (a) grinding of sugar beet material with a dry matter content of at least 85% by weight of grist, until at least 1% by weight of the grist attains a particle size of 1 μm to 1000 μm, (b) dividing the grist into fractions based on particle size and/or particle density, to create at least one fraction with a particle size below 500 μm and in the case of at least one fraction with a particle size above 500 μm, (c) or possibly subsequent subjection of the fraction with a particle size exceeding 500 μm to steps (a) and (b) until the desired quantity of the fraction with a particle size below 500 μm has been attained, preferably 1 to 20 times. The present teaching also relates to product produced in this way.

A method for the qualitative distribution of sugar beet dry matter to products usable in food production, which includes the steps: (a) grinding of sugar beet material with a dry matter content of at least 85% by weight of grist, until at least 1% by weight of the grist attains a particle size of 1 μm to 1000 μm, (b) dividing the grist into fractions based on particle size and/or particle density, to create at least one fraction with a particle size below 500 μm and in the case of at least one fraction with a particle size above 500 μm, (c) or possibly subsequent subjection of the fraction with a particle size exceeding 500 μm to steps (a) and (b) until the desired quantity of the fraction with a particle size below 500 μm has been attained, preferably 1 to 20 times. The present teaching also relates to product produced in this way.

Preferred embodiments of the present invention comprise the optional application of concentrations of an aqueous permanganate solution, such as an approximately 0.01% to approximately 50% liquid permanganate solution and preferably comprising approximately 20% sodium permanganate dosed at approximately 1 ppm to approximately 100 ppm to harvested sugar crops, such as sugarcane, sugar beets, and sweet sorghum, at one or more of the sugar processing steps for the crops. The steps where the liquid sodium permanganate may optionally be applied include at a sugar crop cutting step, a sugar crop conveying step, a sugar juice extraction step, a sugar juice clarifying step, and a clarifier muds filtration step. The application of liquid sodium permanganate in the processing of sugar from sugar crops results in reduced equipment fouling, reduced loss in juice purity, reduced scale formation, decreased turbidity in clarified juices, increased sugarcane processing rates, reduced sugar crop production costs, increased sugar product yield, and increased production capacity.

Preferred embodiments of the present invention comprise the optional application of concentrations of an aqueous permanganate solution, such as an approximately 0.01% to approximately 50% liquid permanganate solution and preferably comprising approximately 20% sodium permanganate dosed at approximately 1 ppm to approximately 100 ppm to harvested sugar crops, such as sugarcane, sugar beets, and sweet sorghum, at one or more of the sugar processing steps for the crops. The steps where the liquid sodium permanganate may optionally be applied include at a sugar crop cutting step, a sugar crop conveying step, a sugar juice extraction step, a sugar juice clarifying step, and a clarifier muds filtration step. The application of liquid sodium permanganate in the processing of sugar from sugar crops results in reduced equipment fouling, reduced loss in juice purity, reduced scale formation, decreased turbidity in clarified juices, increased sugarcane processing rates, reduced sugar crop production costs, increased sugar product yield, and increased production capacity.

Preferred embodiments of the present invention comprise the optional application of concentrations of an aqueous permanganate solution, such as an approximately 0.01% A to approximately 50% liquid permanganate solution and preferably comprising approximately 20% sodium permanganate dosed at approximately 1 ppm to approximately 100 ppm to harvested sugar crops, such as sugarcane, sugar beets, and sweet sorghum, at one or more of the sugar processing steps for the crops. The steps where the liquid sodium permanganate may optionally be applied include at a sugar crop cutting step, a sugar crop conveying step, a sugar juice extraction step, a sugar juice clarifying step, and a clarifier muds filtration step. The application of liquid sodium permanganate in the processing of sugar from sugar crops results in reduced equipment fouling, reduced loss in juice purity, reduced scale formation, decreased turbidity in clarified juices, increased sugarcane processing rates, reduced sugar crop production costs, increased sugar product yield, and increased production capacity.

Preferred embodiments of the present invention comprise the optional application of concentrations of an aqueous permanganate solution, such as an approximately 0.01% A to approximately 50% liquid permanganate solution and preferably comprising approximately 20% sodium permanganate dosed at approximately 1 ppm to approximately 100 ppm to harvested sugar crops, such as sugarcane, sugar beets, and sweet sorghum, at one or more of the sugar processing steps for the crops. The steps where the liquid sodium permanganate may optionally be applied include at a sugar crop cutting step, a sugar crop conveying step, a sugar juice extraction step, a sugar juice clarifying step, and a clarifier muds filtration step. The application of liquid sodium permanganate in the processing of sugar from sugar crops results in reduced equipment fouling, reduced loss in juice purity, reduced scale formation, decreased turbidity in clarified juices, increased sugarcane processing rates, reduced sugar crop production costs, increased sugar product yield, and increased production capacity.

Method to extract sugar from a sugar beet, the sugar beet is cut in a cutting device in strips/cossettes with a length and a cross-section, the length of the strips/cossettes is, at least essentially, uniform.

Method to extract sugar from a sugar beet, the sugar beet is cut in a cutting device in strips/cossettes with a length and a cross-section, the length of the strips/cossettes is, at least essentially, uniform.