A process for reforming the fly ash, including the heating step that heats a raw fly ash powder containing the unburned carbon at a temperature of 780 to 1000° C. to decrease the amount of the unburned carbon contained in the raw fly ash powder; the classifying step that introduces the heat-treated fly ash containing the unburned carbon in decreased amounts obtained through the heating step into a classifying apparatus in the state of being heated at a high temperature so as to separate the fly ash into a coarse powder and a fine powder; the fine powder recovering step that recovers the fine powder of the heat-treated fly ash obtained through the classifying step by using a dust-collecting apparatus; and the milling step that mills the coarse powder of the heat-treated fly ash obtained through the classifying step until a 45 μm sieve residue becomes not more than 34% by mass, and then recovers the milled powder.

To provide a burner that makes it possible to reduce error displacement of the distal end position of a burner main body when the burner main body is inserted. A burner (161) includes: a burner main body (162); a plurality of driving cylinders (163) that are disposed parallel to a direction of an axis line in which the burner main body (162) moves, and drive movement of the burner main body (162); a connecting member that connects the burner main body (162) and the plurality of driving cylinders (163); and a fitting member (170) that is provided between the burner main body (162) and the connecting member, and constrains relative movement in the direction of the axis line (X) and permits relative movement in a direction perpendicular to the direction of the axis line (X).

A solid pellet fueled apparatus having a duel auger system and multi/high speed auger motor is disclosed. The duel auger may include first and second auger blades mounted on a single auger shaft having blade pitches configured to convey solid fuel in opposite directions towards a central burn pot. Each auger blade may service a separate solid fuel compartment provided in a single hopper. The auger motor may have a high-speed setting that may be selected for solid fuel clean out.

In this application is disclosed a novel equipment for solid waste treatment in general, whose state of the art foresees various types of reactors for thermal processing of solid waste, it is constituted by a reactor that has the combustion processed under a thermal cyclone effect produced by air nozzles.

A crematorium ashes transfer container made of paper and/or cardboard comprises: one or more sides and/or walls defining a cavity to receive the ashes; an outlet in one of the sides and/or walls allowing exit of ashes in the cavity from the container, the outlet comprising a nozzle and a removeable cap that closes the nozzle, the nozzle being capable of sealing engagement with a long term storage container, whereby ashes within the cavity of the container can be transferred to the long term storage container without being visible during transfer and without leakage of ashes during transfer. A method of transferring cremation ashes into a long term ashes storage container, comprises:— a. providing ashes from a cremation, b. providing a long term ashes storage container having an inlet and providing a crematorium ashes transfer container made of paper and/or cardboard that comprises a nozzle capable of sealing engagement with the inlet on the long term storage container, c. transferring the ashes into the crematorium ashes transfer container, d. sealing the crematorium ashes transfer container, e. opening the nozzle, f. connecting the nozzle with the inlet of the long term storage container so as to be in sealing engagement therewith, and g. transferring the ashes into the long term storage container. A kit comprises the transfer container and the long term storage container.

To provide a burner that makes it possible to reduce error displacement of the distal end position of a burner main body when the burner main body is inserted. A burner (161) includes: a burner main body (162); a plurality of driving cylinders (163) that are disposed parallel to a direction of an axis line in which the burner main body (162) moves, and drive movement of the burner main body (162); a connecting member that connects the burner main body (162) and the plurality of driving cylinders (163); and a fitting member (170) that is provided between the burner main body (162) and the connecting member, and constrains relative movement in the direction of the axis line (X) and permits relative movement in a direction perpendicular to the direction of the axis line (X).

A cooking apparatus, having a body defining an interior cooking chamber for cooking food, a pellet supply portion coupled to the body and including a hopper for storing fuel, a combustion chamber for burning the fuel and heating the cooking chamber, a feeding mechanism for supplying fuel from the hopper to the combustion chamber, and a removable collection receptacle located below the combustion chamber. The apparatus also includes an ash-shaker located between the collection receptacle and the combustion chamber, the ash-shaker including an external actuator that controls one or more moving elements located in the combustion chamber, wherein movement of the moving elements encourages unburned debris in the combustion chamber to fall into the receptacle, after which the collection receptacle can be removed and the unburned debris discarded.

Disclosed is a combustion machine, including: a hopper, a drying mechanism and a combustion mechanism. The hopper is configured for storing materials and conveying the materials to the drying mechanism. The drying mechanism includes a conveying mechanism and a drying chamber, and the conveying mechanism is connected with the hopper and conveys the materials in the hopper to the drying chamber. The combustion mechanism includes a combustion chamber connected with the drying chamber via a material conveying pipeline, and a fire outlet pipe arranged in the combustion chamber and used for outputting flame. A hot air pipeline is connected between the combustion chamber and the drying chamber, and a first exhaust fan is arranged in the hot air pipeline.

Disclosed is a combustion mechanism including a combustion chamber, an inner container arranged in the combustion chamber, the inner container is internally provided with a first igniter, a fire outlet pipe extending from an inner cavity of the inner container to outside of the combustion chamber, an ash discharge pipe above the inner container and extending to outside of the combustion chamber. The combustion mechanism further includes a feeding pipe extending into the inner container for feeding materials into the inner container; a nozzle in the inner container for blowing air to cause accumulated ash into the ash discharge pipe, and a first suction fan being arranged in the ash discharge pipe; a gas driving mechanism connected with the nozzle for outputting jet gas to the nozzle; and an air supply mechanism outside the combustion chamber for supplying air to the inner container and the gas driving mechanism.

Disclosed is a combustion mechanism including a combustion chamber, an inner container arranged in the combustion chamber, the inner container is internally provided with a first igniter, a fire outlet pipe extending from an inner cavity of the inner container to outside of the combustion chamber, an ash discharge pipe above the inner container and extending to outside of the combustion chamber. The combustion mechanism further includes a feeding pipe extending into the inner container for feeding materials into the inner container; a nozzle in the inner container for blowing air to cause accumulated ash into the ash discharge pipe, and a first suction fan being arranged in the ash discharge pipe; a gas driving mechanism connected with the nozzle for outputting jet gas to the nozzle; and an air supply mechanism outside the combustion chamber for supplying air to the inner container and the gas driving mechanism.