This application relates to Pseudomonas fluorescens N1, and usage therefor in solid waste recycling based on full bionic simulation combined with a microorganism. Light, temperature, gas and heat conditions in cyclic transformation of organic carbon in soil are simulated, and solid waste is mixed and stacked in the soil or between hills, wherein the solid waste is basically blended according to the carbon-nitrogen ratio, alkalinity or acidity, and water content of the solid waste, and no turning is performed according to the principle of anaerobic fermentation. By introducing high-carbon, high-salt, alkaline or acidic liquid waste using a bionic head cover during stacking, the anaerobic fermentation process is controlled to stop at an acid production stage so that organic acids produced are fully mixed with the solid waste, and the nutrients in the solid waste are released by using acidic materials and thus become nutritional elements for acidic material chelation.

This application relates to Pseudomonas fluorescens N1, and usage therefor in solid waste recycling based on full bionic simulation combined with a microorganism. Light, temperature, gas and heat conditions in cyclic transformation of organic carbon in soil are simulated, and solid waste is mixed and stacked in the soil or between hills, wherein the solid waste is basically blended according to the carbon-nitrogen ratio, alkalinity or acidity, and water content of the solid waste, and no turning is performed according to the principle of anaerobic fermentation. By introducing high-carbon, high-salt, alkaline or acidic liquid waste using a bionic head cover during stacking, the anaerobic fermentation process is controlled to stop at an acid production stage so that organic acids produced are fully mixed with the solid waste, and the nutrients in the solid waste are released by using acidic materials and thus become nutritional elements for acidic material chelation.

This application relates to Pseudomonas fluorescens N1, and usage therefor in solid waste recycling based on full bionic simulation combined with a microorganism. Light, temperature, gas and heat conditions in cyclic transformation of organic carbon in soil are simulated, and solid waste is mixed and stacked in the soil or between hills, wherein the solid waste is basically blended according to the carbon-nitrogen ratio, alkalinity or acidity, and water content of the solid waste, and no turning is performed according to the principle of anaerobic fermentation. By introducing high-carbon, high-salt, alkaline or acidic liquid waste using a bionic head cover during stacking, the anaerobic fermentation process is controlled to stop at an acid production stage so that organic acids produced are fully mixed with the solid waste, and the nutrients in the solid waste are released by using acidic materials and thus become nutritional elements for acidic material chelation.

This application relates to Pseudomonas fluorescens N1, and usage therefor in solid waste recycling based on full bionic simulation combined with a microorganism. Light, temperature, gas and heat conditions in cyclic transformation of organic carbon in soil are simulated, and solid waste is mixed and stacked in the soil or between hills, wherein the solid waste is basically blended according to the carbon-nitrogen ratio, alkalinity or acidity, and water content of the solid waste, and no turning is performed according to the principle of anaerobic fermentation. By introducing high-carbon, high-salt, alkaline or acidic liquid waste using a bionic head cover during stacking, the anaerobic fermentation process is controlled to stop at an acid production stage so that organic acids produced are fully mixed with the solid waste, and the nutrients in the solid waste are released by using acidic materials and thus become nutritional elements for acidic material chelation.