A flameless cooking apparatus for use with liquid fuels and for indoor or outdoor use under field operations. The burner exhibits low CO and hydrocarbon emissions and meets standards for burner thermal efficiency when used with JP-8 fuel. The apparatus employs a catalytic burner having among its parts (i) a combustion catalyst; (ii) a conductive surface, e.g., cooking surface; and (iii) in between the catalyst and the conductive surface and in direct physical contact with both surfaces, a heat spreader for conductively transferring heat of combustion from the catalyst to the conductive surface. Also claimed are a method of heat flux and a method of cooking.

A heater or article of cookware is formed of a metal sheet with a first and second surface. A metal oxide layer is formed on the first surface of the sheet and a combustion catalyst is impregnated into the metal oxide layer. Fuel and air is then supplied to the first side of the metal sheet resulting in flameless catalytic combustion which heats the metal sheet.

A heater or article of cookware is formed of a metal sheet with a first and second surface. A metal oxide layer is formed on the first surface of the sheet and a combustion catalyst is impregnated into the metal oxide layer. Fuel and air is then supplied to the first side of the metal sheet resulting in flameless catalytic combustion which heats the metal sheet.

A heater or article of cookware is formed of a metal sheet with a first and second surface. A metal oxide layer is formed on the first surface of the sheet and a combustion catalyst is impregnated into the metal oxide layer. Fuel and air is then supplied to the first side of the metal sheet resulting in flameless catalytic combustion which heats the metal sheet.

A heater or article of cookware is formed of a metal sheet with a first and second surface. A metal oxide layer is formed on the first surface of the sheet and a combustion catalyst is impregnated into the metal oxide layer. Fuel and air is then supplied to the first side of the metal sheet resulting in flameless catalytic combustion which heats the metal sheet.

A burner system for a cooking device has at least one burner surface wherein the at least one burner surface is designed in such a way that the burner system has a low minimum power density with homogeneous temperature distribution at the same time. In a first aspect, the burner system includes a fuel supply and a first burner surface for burning the fuel that is provided downstream of the fuel supply. The burner system includes a second burner surface for afterburning that is separate from the first burner surface and is provided downstream from the first burner surface. Moreover, a method for operating the burner system is shown.

A burner system for a cooking device has at least one burner surface wherein the at least one burner surface is designed in such a way that the burner system has a low minimum power density with homogeneous temperature distribution at the same time. In a first aspect, the burner system includes a fuel supply and a first burner surface for burning the fuel that is provided downstream of the fuel supply. The burner system includes a second burner surface for afterburning that is separate from the first burner surface and is provided downstream from the first burner surface. Moreover, a method for operating the burner system is shown.

The present invention provides a carbon dioxide supplier capable of forming a swirl flow of a mixture gas and evenly distributing the mixture gas through porous grating hole of a catalyst for catalyst combustion to maintain uniform temperature throughout the entire volume of the catalyst to maintain stable combustion of carbon. The carbon dioxide supplier comprises: a mixture gas supply unit supplying a mixture gas of air and fuel; a combustion unit combusting the mixture gas supplied from the mixture gas supply unit; and a swirl forming unit 40 extending between the mixture gas supply unit 30 and the combustion unit 50 in anteroposterior direction, the swirl forming unit 40 swirl-flowing the mixture gas introduced into a rear portion thereof from the mixture gas supply unit 30 to the combustion unit 50 provided at a front portion thereof.

The present invention provides a carbon dioxide supplier capable of forming a swirl flow of a mixture gas and evenly distributing the mixture gas through porous grating hole of a catalyst for catalyst combustion to maintain uniform temperature throughout the entire volume of the catalyst to maintain stable combustion of carbon. The carbon dioxide supplier comprises: a mixture gas supply unit supplying a mixture gas of air and fuel; a combustion unit combusting the mixture gas supplied from the mixture gas supply unit; and a swirl forming unit 40 extending between the mixture gas supply unit 30 and the combustion unit 50 in anteroposterior direction, the swirl forming unit 40 swirl-flowing the mixture gas introduced into a rear portion thereof from the mixture gas supply unit 30 to the combustion unit 50 provided at a front portion thereof.

A system and method for controlling a porous medium burner of medium-high temperature heating field, the control system includes a local control system and a remote control system; the local control system is configured for acquisition and feedback of data, and execution of an action; and the remote control system communicates with the local control system in real time and is configured for storage and analysis of data and transmission of an instruction. A system and method for controlling a porous medium burner of medium-high temperature heating field, which can effectively perform prediction and prevention of flashback, be adapted to combustion of gases with different calorific values, monitor and diagnose, in real time, a usage status of a porous medium material, and be suitable for the functions such as real-time monitoring of preheating of air and a fuel gas.