The present invention relates to a continuous on-board drying method for Antarctic krill and a continuous on-board processing method of shelled Antarctic krill. The drying method includes the following steps: 1) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen; 2) rapidly heating the krill to the temperature of up to 70? C. using infra-red rays; 3) hot-air drying; 4) impurity removal by vacuum; 5) cooling to obtain dried krill. The processing method includes the following steps: a) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen; b) rapidly heating the krill to the temperature of up to 70? C. using infra-red rays; c) hot-air drying; d) subjecting the dried krill to shelling treatment to separate shell from meat, to obtain shelled krill; e) impurity removal by vacuum to obtain shelled krill product. The methods in the present invention are highly efficient, energy saving, green and environmental protection, and the krill products have high quality and safety.

The present invention relates to a continuous on-board drying method for Antarctic krill and a continuous on-board processing method of shelled Antarctic krill. The drying method includes the following steps: 1) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen, 2) rapidly heating the krill to the temperature of up to 70? C. using infra-red rays; 3) hot-air drying; 4) impurity removal by vacuum; 5) cooling to obtain dried krill. The processing method includes the following steps: a) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen; b) rapidly heating the krill to the temperature of up to 70? C. using infra-red rays; c) hot-air drying; d) subjecting the dried krill to shelling treatment to separate shell from meat, to obtain shelled krill; e) impurity removal by vacuum to obtain shelled krill product. The methods in the present invention are highly efficient, energy saving, green and environmental protection, and the krill products have high quality and safety.

The present invention relates to a continuous on-board drying method for Antarctic krill and a continuous on-board processing method of shelled Antarctic krill. The drying method includes the following steps: 1) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen; 2) rapidly heating the krill to the temperature of up to 70? C. using infra-red rays; 3) hot-air drying; 4) impurity removal by vacuum; 5) cooling to obtain dried krill. The processing method includes the following steps: a) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen; b) rapidly heating the krill to the temperature of up to 70? C. using infra-red rays; c) hot-air drying; d) subjecting the dried krill to shelling treatment to separate shell from meat, to obtain shelled krill; e) impurity removal by vacuum to obtain shelled krill product. The methods in the present invention are highly efficient, energy saving, green and environmental protection, and the krill products have high quality and safety.

The invention relates to a method and a bioreactor for drying biogenic residues to a dry mass comprising filling the residues into a bioreactor filled with spheres and mixing the spheres and the residues so that films of the residues form on the surfaces of the spheres, drying the films of residues with the formation of crusts of dry mass with a residual water content on the surfaces of the spheres by feeding a drying medium into the bioreactor,

grinding and further drying the dry mass by mixing and grinding off powdery dry mass from the spheres.

An algae dryer defines an insulated and heated stationary drum within which is positioned a rotating arm extending an axial sprayer to spray a coat of algae on the inside of the drum with a second integrated opposing arm axially extending an offset scraper which engages the inner perimeter of the drum surface and removes the algae from the interior of the drum, depositing the dry algae scrapings into the bottom of the drum through a slot, further directing the harvested algae through an auger to a packaging or processing location.

Disclosed is a spray-freeze drying (SFD) apparatus for continuous drying of microalgae. The apparatus includes a main chamber connected to a collector chamber and a compressor, designed to freeze fine droplets of microalgae and collect frozen particles. A drying chamber, positioned downstream of the main chamber, is coupled with a vacuum pump and an electromagnetic radiation source to remove moisture from the frozen microalgae, resulting in dried particles. The dried microalgae are then collected in a designated collection chamber. Additionally, a method is disclosed for continuous drying of microalgae using the SFD apparatus. The method involves spraying microalgae suspension as fine droplets towards a cold surface particle collector in the main chamber, freezing and collecting the particles, transferring them to the drying chamber, and removing moisture through the activation of the electromagnetic radiation source and vacuum pump, followed by collecting the dried microalgae in the collection chamber.