A coffee roasting apparatus is disclosed comprising a compartment for holding coffee beans, a heating arrangement for heating the coffee beans in the compartment during a roasting process of the coffee beans, a volatile organic compound sensor for determining a total concentration of volatile organic compounds residing in the compartment, and a controller for controlling the heating arrangement. The controller is adapted to determine whether a rate of change in the total concentration of volatile organic compounds exceeds a predefined threshold and control the heating arrangement based on a determination that the rate of change in the total concentration of volatile organic compounds exceeds the predefined threshold. A coffee brewing apparatus including such a coffee roasting apparatus and a coffee roasting method are also disclosed.

A bean roasting system includes a roasting chamber, a blower, a variable diverter and a controller. The roasting chamber, the blower and the variable diverter each is disposed at least partially within a recirculating gas flow path. The blower is configured to provide a flow stream of gas through the recirculating gas flow path. The variable diverter is configured to split the gas flow path into at least two flow paths including a treated flow path and a bypass flow path. The treated flow path includes a series arrangement of a gas heater and a catalytic converter. The variable diverter is configured to control a percentage of a flow stream of gas that is diverted into the bypass flow path. The controller is configured to activate different predetermined operating modes for the bean roasting system by controlling a state of the variable diverter and a state of the heater.

A bean roasting system includes a roasting chamber, a blower, a variable diverter and a controller. The roasting chamber, the blower and the variable diverter each is disposed at least partially within a recirculating gas flow path. The blower is configured to provide a flow stream of gas through the recirculating gas flow path. The variable diverter is configured to split the gas flow path into at least two flow paths including a treated flow path and a bypass flow path. The treated flow path includes a series arrangement of a gas heater and a catalytic converter. The variable diverter is configured to control a percentage of a flow stream of gas that is diverted into the bypass flow path. The controller is configured to activate different predetermined operating modes for the bean roasting system by controlling a state of the variable diverter and a state of the heater.

A coffee roasting apparatus is disclosed that comprises a compartment for holding coffee beans, a heating arrangement for directing a heated air flow through the compartment during a roasting process of the coffee beans, a particulate matter sensor for detecting a peak amount of particulate matter released by the coffee beans, a timer for determining an amount of time lapsed from a start of the roasting process until the detection of the peak amount, and a controller arranged to control the heating arrangement. The controller is adapted to select a defined control time as a function of the lapsed amount of time and apply the defined control time to the heating arrangement after first cracking of the coffee beans to complete the roasting process. A coffee brewing apparatus including such a coffee roasting apparatus and a method of controlling such a coffee roasting apparatus are also disclosed.

A coffee roasting apparatus is disclosed that comprises a compartment for holding coffee beans, a heating arrangement for directing a heated air flow through the compartment during a roasting process of the coffee beans, a particulate matter sensor for detecting a peak amount of particulate matter released by the coffee beans, a timer for determining an amount of time lapsed from a start of the roasting process until the detection of the peak amount, and a controller arranged to control the heating arrangement. The controller is adapted to select a defined control time as a function of the lapsed amount of time and apply the defined control time to the heating arrangement after first cracking of the coffee beans to complete the roasting process. A coffee brewing apparatus including such a coffee roasting apparatus and a method of controlling such a coffee roasting apparatus are also disclosed.

A coffee degassing device is disclosed and method. The coffee degassing device comprises a coffee bin and a hollow tree within the bin. The hollow tree has an opening in communication with the interior of the coffee bin. The tree provides an exit path for carbon dioxide off-gassing from the coffee. The device may have a diffusion gas supply conduit. The diffusion gas supply conduit is in communication with the hollow tree and is configured to supply nitrogen, or another diffusion gas, to the degassing tree for accelerating the degassing of coffee.

A coffee degassing device is disclosed and method. The coffee degassing device comprises a coffee bin and a hollow tree within the bin. The hollow tree has an opening in communication with the interior of the coffee bin. The tree provides an exit path for carbon dioxide off-gassing from the coffee. The device may have a diffusion gas supply conduit. The diffusion gas supply conduit is in communication with the hollow tree and is configured to supply nitrogen, or another diffusion gas, to the degassing tree for accelerating the degassing of coffee.

A bean roasting system includes a roasting drum, an agitator, and a door. The roasting drum has an inside surface extending from a back end to a front end. The agitator has blades mounted to an axial shaft. The axial shaft has an anterior end portion. The door is mounted rotationally relative to the roasting drum and includes a glass plate and a bearing assembly. The glass plate provides visual access to contents inside the roasting drum when the door is closed. The bearing assembly includes an outer housing and an inner bearing. The outer housing is mounted to the glass plate. The inner bearing defines a receiving hole that receives and supports the anterior end portion of the axial shaft when the door closed.

A bean roasting system includes a roasting drum, an agitator, and a door. The roasting drum has an inside surface extending from a back end to a front end. The agitator has blades mounted to an axial shaft. The axial shaft has an anterior end portion. The door is mounted rotationally relative to the roasting drum and includes a glass plate and a bearing assembly. The glass plate provides visual access to contents inside the roasting drum when the door is closed. The bearing assembly includes an outer housing and an inner bearing. The outer housing is mounted to the glass plate. The inner bearing defines a receiving hole that receives and supports the anterior end portion of the axial shaft when the door closed.

An apparatus for roasting coffee beans comprises a roasting chamber for containing coffee beans. The roasting chamber is positioned within a resonant cavity of a waveguide. A microwave emitter produces microwave energy within the waveguide with one or more stable high intensity microwave regions within the roasting chamber to heat the coffee beans in the roasting chamber to a temperature sufficient to roast the coffee beans. A device configured to move the coffee beans within the one or more high intensity microwave regions is coupled to the roasting chamber.