Abstract: A 3D printing consumables drying machine is disclosed. The top of the base is provided with a accommodation cavity. The rolling mechanism, heating mechanism and drive mechanism are installed in the accommodating cavity. The rolling mechanism is used to carry the reel. The heating mechanism is installed in the accommodating cavity. The driving mechanism is installed in the accommodating cavity. The driving mechanism is used to drive the rolling mechanism to rotate and to drive the reel on the rolling mechanism to rotate. The problem with many 3D printing consumables dryers on the market is that the internal reel remains static during drying. This causes uneven heating of the consumables. Which resulting in inconsistent drying across the consumables. Moreover, the consumables close to the heating device are prone to deformation, melting, and other undesirable effects due to excessive heat.

Abstract: A drying oven for 3D printing materials includes a base, an upper cover, a rotating shaft assembly and a drying assembly. The drying assembly includes a heating plate and a fan. An air outlet end of the fan faces upward, and the heating plate is arranged above the air outlet end of the fan. An accommodating cavity is provided at a middle of the base, and an air inlet communicating with outside is provided at a bottom of the accommodating cavity. The fan and the heating plate are arranged in the accommodating cavity. The rotating shaft assembly is arranged on a top surface of the base. An air outlet is arranged at an upper end of the upper cover, and the upper cover is configured to cover the base.

Abstract: A drying oven for 3D printing materials includes a base, an upper cover, a rotating shaft assembly and a drying assembly. The drying assembly includes a heating plate and a fan. An air outlet end of the fan faces upward, and the heating plate is arranged above the air outlet end of the fan. An accommodating cavity is provided at a middle of the base, and an air inlet communicating with outside is provided at a bottom of the accommodating cavity. The fan and the heating plate are arranged in the accommodating cavity. The rotating shaft assembly is arranged on a top surface of the base. An air outlet is arranged at an upper end of the upper cover, and the upper cover is configured to cover the base.

Abstract: The present invention provides a method and system for preparing fuel gas by utilizing an organic waste with high water content. The method comprises the following steps: 1) providing an organic waste with high water content; 2) performing hydrothermal reaction by using the organic waste with high water content as a reactant to obtain a hydrothermal reaction product; 3) enabling the hydrothermal reaction product to generate steam, and separating a solid product and an oily liquid product in the hydrothermal reaction product; 4) performing gasification reaction by using the solid product, the oily liquid product and the steam as reactants to obtain a gasification reaction product; and 5) purifying the gasification reaction product to obtain clean fuel gas. The present invention further provides a system for preparing fuel gas. The method can be used for preparing clean fuel gas from the organic waste with water content of 60% or more.

Abstract: The present invention provides a method and system for preparing fuel gas by utilizing an organic waste with high water content. The method comprises the following steps: 1) providing an organic waste with high water content; 2) performing hydrothermal reaction by using the organic waste with high water content as a reactant to obtain a hydrothermal reaction product; 3) enabling the hydrothermal reaction product to generate steam, and separating a solid product and an oily liquid product in the hydrothermal reaction product; 4) performing gasification reaction by using the solid product, the oily liquid product and the steam as reactants to obtain a gasification reaction product; and 5) purifying the gasification reaction product to obtain clean fuel gas. The present invention further provides a system for preparing fuel gas. The method can be used for preparing clean fuel gas from the organic waste with water content of 60% or more.

Abstract: A system for hydrothermal reaction comprises a heater (3) including a circulating component for fluid flowing across and a heat source for heating fluid, and a reactor (4, 5) including a heat preserving container in communication with the circulating component via pipes. A method for hydrothermal reaction comprises heating the fluid including the reactant and water for hydrothermal reaction, and feeding the heated fluid to the heat preserving container to perform the hydrothermal reaction.

Abstract: A treatment process of persistent organic pollutants contained in particles is provided. Said process includes reacting persistent organic pollutant in particles under hydrothermal conditions in the presence of Fe2+ and Fe3+. Several beneficial effects can be achieved, including 1) no other additive is needed during the reaction process; 2) Fe2+ and Fe3+ are safe, cheap and extensive sources; 3) because Fe2+ and Fe3+ are dissolved, they can fully disperse into particles, and fully contact can be achieved, thus obtaining a decomposition rate no less than 70% of the persistent organic pollutants is under subcritical conditions.

Abstract: A system for hydrothermal reaction comprises a heater (3) including a circulating component for fluid flowing across and a heat source for heating fluid, and a reactor (4, 5) including a heat preserving container in communication with the circulating component via pipes. A method for hydrothermal reaction comprises heating the fluid including the reactant and water for hydrothermal reaction, and feeding the heated fluid to the heat preserving container to perform the hydrothermal reaction.

Abstract: A treatment process of persistent organic pollutants contained in particles is provided. Said process includes reacting persistent organic pollutant in particles under hydrothermal conditions in the presence of Fe2+ and Fe3+. Several beneficial effects can be achieved, including 1) no other additive is needed during the reaction process; 2) Fe2+ and Fe3+ are safe, cheap and extensive sources; 3) because Fe2+ and Fe3+ are dissolved, they can fully disperse into particles, and fully contact can be achieved, thus obtaining a decomposition rate no less than 70% of the persistent organic pollutants is under subcritical conditions.