A metallic wick includes at least one mesh member having first and second ends disposed opposite to each other, first and second surfaces respectively extended from the first end to the second end thereof and arranged opposite to each other, a plurality of meshes penetrating the first and second surfaces between the first and second ends thereof; and a transport channel extending from the first end to the second end thereof and drawing fuel by capillary action.

The present disclosure relates to a flame producing assembly. The flame producing assembly may comprise a fuel reservoir, a flame wick and a fuel wick in fluid communication with the fuel reservoir. The flame producing assembly may further comprise a translation mechanism, wherein the translation mechanism may be configured to switch the fuel wick between a first position and a second position. Further, the flame wick may be in fluid communication with the fuel wick when the fuel wick is in the first position and not in fluid communication with the fuel wick when the fuel wick is in the second position.

The present disclosure relates to a flame producing assembly. The flame producing assembly may comprise a fuel reservoir, a flame wick and a fuel wick in fluid communication with the fuel reservoir. The flame producing assembly may further comprise a translation mechanism, wherein the translation mechanism may be configured to switch the fuel wick between a first position and a second position. Further, the flame wick may be in fluid communication with the fuel wick when the fuel wick is in the first position and not in fluid communication with the fuel wick when the fuel wick is in the second position.

A wax burning system is disclosed. The system has a melted wax reservoir, a solid wax, a melting grate, a hollow core wick, and a wick sheath. The solid wax has a priming section. The melting grate is configured to receive the solid wax. The melting grate is located above at least a portion of the melted wax reservoir so that the solid wax melted on the melting grate is received into the melted wax reservoir. The melting grate has one or more apertures to allow a melted wax to flow through the melting grate and into the melted wax reservoir. The hollow-core wick extends above the melting grate and is configured to receive fuel from the melted wax reservoir. The priming section is located above a top of the hollow-core wick to prime the hollow-core wick for ignition. The wick sheath surrounds the hollow-core wick.

A wax burning system is disclosed. The system has a melted wax reservoir, a solid wax, a melting grate, a hollow core wick, and a wick sheath. The solid wax has a priming section. The melting grate is configured to receive the solid wax. The melting grate is located above at least a portion of the melted wax reservoir so that the solid wax melted on the melting grate is received into the melted wax reservoir. The melting grate has one or more apertures to allow a melted wax to flow through the melting grate and into the melted wax reservoir. The hollow-core wick extends above the melting grate and is configured to receive fuel from the melted wax reservoir. The priming section is located above a top of the hollow-core wick to prime the hollow-core wick for ignition. The wick sheath surrounds the hollow-core wick.

A metallic wick includes at least one mesh member having first and second ends disposed opposite to each other, first and second surfaces respectively extended from the first end to the second end thereof and arranged opposite to each other, a plurality of meshes penetrating the first and second surfaces between the first and second ends thereof, and a transport channel extending from the first end to the second end thereof and drawing fuel by capillary action.

A metallic wick includes at least one mesh member having first and second ends disposed opposite to each other, first and second surfaces respectively extended from the first end to the second end thereof and arranged opposite to each other, a plurality of meshes penetrating the first and second surfaces between the first and second ends thereof, and a transport channel extending from the first end to the second end thereof and drawing fuel by capillary action.

A method of fueling a flame, a fuel, and a fuel burning system is provided. The system has a melted wax reservoir, a fuel, a melting grate, and a wick. The fuel has a body, a priming section, a front wall, and a bottom surface. The priming section is vertically spaced from the bottom surface and extending from the front wall to create an overhang. The priming section extends along less than the entire length of the front wall. The melting grate is configured to support the fuel. The melting grate extends above the melted wax reservoir so that fuel melted on the melting grate can be received into the melted wax reservoir. The wick has an at least partially hollow core forming a burn chamber extending above the melting grate. The fuel is configured to be positioned so the overhang is located over or adjacent to the wick.

A method of fueling a flame, a fuel, and a fuel burning system is provided. The system has a melted wax reservoir, a fuel, a melting grate, and a wick. The fuel has a body, a priming section, a front wall, and a bottom surface. The priming section is vertically spaced from the bottom surface and extending from the front wall to create an overhang. The priming section extends along less than the entire length of the front wall. The melting grate is configured to support the fuel. The melting grate extends above the melted wax reservoir so that fuel melted on the melting grate can be received into the melted wax reservoir. The wick has an at least partially hollow core forming a burn chamber extending above the melting grate. The fuel is configured to be positioned so the overhang is located over or adjacent to the wick.

A method of preventing clogging of a reusable wick, a method of fueling a reusable wick, and a fuel burning system are provided. The fuel burning system has a melted fuel reservoir, a melting grate, and at least one wick. The melted fuel reservoir is configured to receive a solid fuel. The melting grate is located above at least a portion of the melted fuel reservoir so that fuel melted on the melting grate can be received into the melted fuel reservoir. The at least one wick has an at least partially hollow core forming a burn chamber extending above the melting grate. The wick is spaced from the reservoir so that melted fuel in the reservoir is spaced apart from a bottom of the wick.