Methods and systems for treatment of grain for toxins and/or odor utilize a storage container having a grain storage space and an aeration floor that allows air to flow through the aeration floor into the grain storage space. Ozone (mixed with air) is supplied to the grain through the aeration floor under positive pressure, whereby ozone is forced through the aeration floor into a lower portion of the grain storage space. After an initial treatment time, the initial treatment time allowing for the ozone to reduce toxins and/or odor in a lowermost portion of the initial quantity of grain an effective or desired amount, a lowermost portion or a lower treated portion of the grain in the grain storage space is removed, and new grain is added on top of the grain in the grain storage space, all while continuing to supply ozone through the aeration floor under positive pressure.

Methods and systems for treatment of grain for toxins and/or odor utilize a storage container having a grain storage space and an aeration floor that allows air to flow through the aeration floor into the grain storage space. Ozone (mixed with air) is supplied to the grain through the aeration floor under positive pressure, whereby ozone is forced through the aeration floor into a lower portion of the grain storage space. After an initial treatment time, the initial treatment time allowing for the ozone to reduce toxins and/or odor in a lowermost portion of the initial quantity of grain an effective or desired amount, a lowermost portion or a lower treated portion of the grain in the grain storage space is removed, and new grain is added on top of the grain in the grain storage space, all while continuing to supply ozone through the aeration floor under positive pressure.

Methods are provided which include steeping and/or spraying a harvested cereal grain, such as barley, wheat, rye, millet, corn (maize), rice, or oats, in or with an aqueous solution including an effective amount of chlorine dioxide to provide a treated cereal grain. The treated cereal grain obtained from chlorine-dioxide steeping and/or spraying generally has a reduced microorganism and/or toxin content, and may be subjected to additional malting processes.

Methods are provided which include steeping and/or spraying a harvested cereal grain, such as barley, wheat, rye, millet, corn (maize), rice, or oats, in or with an aqueous solution including an effective amount of chlorine dioxide to provide a treated cereal grain. The treated cereal grain obtained from chlorine-dioxide steeping and/or spraying generally has a reduced microorganism and/or toxin content, and may be subjected to additional malting processes.

An equipment and a method for ozone circulation fumigation in grain depot are provided. The equipment includes a grain storage cavity, an air intake unit, a circulation unit, and a fixed unit. The air intake unit is connected to the grain depot through a fixed unit, the circulation unit is located on the side of the grain depot away from the air intake unit, the circulation unit is connected to the air intake unit through a reflux pipe, the reflux pipe is equipped with an ozone concentration sensor, the transverse diffusion tube of the air intake unit is connected to the grain storage cavity, the grain storage cavity is equipped with a ventilation partition, there are several air vents on the ventilation partition, and a backflow channel is formed between the ventilation partition and the side wall of the grain depot.

An equipment and a method for ozone circulation fumigation in grain depot are provided. The equipment includes a grain storage cavity, an air intake unit, a circulation unit, and a fixed unit. The air intake unit is connected to the grain depot through a fixed unit, the circulation unit is located on the side of the grain depot away from the air intake unit, the circulation unit is connected to the air intake unit through a reflux pipe, the reflux pipe is equipped with an ozone concentration sensor, the transverse diffusion tube of the air intake unit is connected to the grain storage cavity, the grain storage cavity is equipped with a ventilation partition, there are several air vents on the ventilation partition, and a backflow channel is formed between the ventilation partition and the side wall of the grain depot.

The disclosure discloses a method for killing A. Flavus spores by infrared radiation in coordination with essential oil fumigation, and belongs to the technical field of sterilization. The method is to treat A. Flavus spores by medium and short wave infrared radiation in combination with essential oil fumigation. The disclosure provides a method for killing A. Flavus spores by medium and short wave infrared radiation in coordination with essential oil fumigation. On the one hand, air residual heat and energy of medium and short wave infrared radiation are fully used to make a material heated up rapidly, and on the other hand, essential oil on the surface of the material penetrates the cell membrane of A. Flavus spores, and further damages protein on the membrane and internal organelles in combination with the heat effect. The process is easy in operation, low in energy consumption, pollution-free and high in sterilization efficiency, and can be used for purifying bulk grains.

The disclosure discloses a method for killing A. Flavus spores by infrared radiation in coordination with essential oil fumigation, and belongs to the technical field of sterilization. The method is to treat A. Flavus spores by medium and short wave infrared radiation in combination with essential oil fumigation. The disclosure provides a method for killing A. Flavus spores by medium and short wave infrared radiation in coordination with essential oil fumigation. On the one hand, air residual heat and energy of medium and short wave infrared radiation are fully used to make a material heated up rapidly, and on the other hand, essential oil on the surface of the material penetrates the cell membrane of A. Flavus spores, and further damages protein on the membrane and internal organelles in combination with the heat effect. The process is easy in operation, low in energy consumption, pollution-free and high in sterilization efficiency, and can be used for purifying bulk grains.