A roasting and glazing apparatus includes a roaster, an agitator mounted within the roaster bowl for mixing a mixture of nuts and sugar during a roasting or glazing operation, a heater controlled to heat the roaster bowl during the roasting or glazing operation, and a cover removably mounted to the roaster bowl. The cover includes a reservoir for receiving water from a user and restricting water flow from the reservoir into the mixture of nuts and sugar in the roaster bowl. The cover and the roaster bowl together define a vent on a side of the cover opposite the reservoir. The vent is configured to direct steam out of the roaster bowl in a direction away from the reservoir.

Processes for producing roasted nuts are described herein. The processes include mixing bare nuts with maple syrup to coat the bare nuts with the maple syrup and form coated nuts, placing the coated nuts into a cooking apparatus set at a first temperature for a period of time to form roasted nuts, while the coated nuts are roasting in the cooking apparatus, agitating the coated nuts and removing the roasted nuts from the cooking apparatus.

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.

Disclosed herein are a roasting apparatus and a method of controlling a roasting apparatus, and more particularly, are a roasting apparatus in which an object is stirred and roasted in a roasting chamber, and a method of controlling the roasting apparatus.

The roasting apparatus for heating an object includes a roasting chamber part which includes a cylindrical roasting chamber, in which an object is stirred and which extends in a vertical direction, and a rotary stirring part rotated to stir the object accommodated in the roasting chamber, wherein the rotary stirring part is rotated about a stirring axis formed in the vertical direction; a casing unit configured to surround the roasting chamber part; a heat source part including a first heat source part configured to provide radiant heat to the roasting chamber part; and a radiant temperature measurement unit configured to measure a temperature of the roasting chamber or the object and a chamber outer space temperature of a chamber outer space between the casing unit and the roasting chamber part on the basis of infrared rays emitted from an inner surface of the roasting chamber part or a surface of the object, which is heated by the heat source part, wherein a preheating operation is performed until the chamber inner temperature of the roasting chamber and the chamber outer space temperature reach a preset reference chamber inner temperature and a preset reference chamber outer space temperature.

A bean roasting system includes a roasting drum, an air handling system, a bean cooler, and an air exit subsystem. The air exit subsystem is configured to receive and treat a first fluid stream from the air handling system and a second fluid stream from the bean cooler. The air exit subsystem includes a heat sink and a filter. The heat sink defines two parallel fluid paths including a first fluid path and a second fluid path. The air exit subsystem includes a metal body configured to receive heat from the first fluid path and the second fluid path. The first fluid path is fluidically coupled to receive the first fluid stream from the air handling system. The second fluid path is fluidically coupled to receive the second fluid stream from the bean cooler. The filter is fluidically coupled to the first and second air flow paths.

A bean roasting system includes a roasting subsystem and an air handling subsystem. The roasting subsystem includes a housing, an agitator actuator, an agitator, a bearing and a door. The housing has an inner surface defining an inner chamber for holding a batch of beans during a thermal roasting process. The agitator is coupled to the agitator actuator and includes a central shaft and a blade set mounted to the central shaft. The bearing supports the central shaft and is configured to prevent the blade set from contacting the inner surface of the housing. The door has a transparent window to allow viewing of the thermal roasting process. The air handling system is coupled to the roasting subsystem, includes a blower and heater, and is configured to circulate heated air through the roasting subsystem during the thermal roasting process.

Apparatus for roasting coffee beans, the apparatus comprising: a casing that defines an internal void, a baffle for dividing the internal void into first and second zones that are in fluid communication with one another; a heater for heating air to temperatures suitable for roasting coffee beans, the heater being located in the second zone; a control system for controlling the apparatus; the control system being located in the first zone; and a fan operable to draw ambient air into the first zone and drive the air from the first zone past the baffle into the second zone for heating by the heater, the arrangement being such that in use the first zone is cooler than the second zone.

A roasting and grinding system (100) for preparing and delivering on demand roast and ground coffee, the system having: one or more raw containers (10, 10′, 10″, etc.) having green coffee beans of the same or of different types; a roasting unit (20) receiving green coffee beans from one or more of the raw containers (10, 10′, 10″, etc.) at the time, the roasting unit (20) adapting automatically the roasting parameters to the type of green coffee beans to roast; a conservation area (30) where the roasted coffee is stored at appropriate atmosphere until it is grinded; a grinding area (40) having one or more grinding units (41, 41′, 41″, etc.) one per type of coffee to be ground, adapting automatically the grinding parameters to the type of coffee or coffee mix to be ground. The invention further relates to a raw container (10, 10′, 10″, etc.) having green coffee beans detachably connectable to a roasting and grinding system (100), and to a method for roasting and grinding coffee blends on demand using such a system.

A fluidized electric coffee roaster includes a housing; a fluidizing chamber having a predetermined volume into which raw coffee beans are introduced, discharged, and roasted; a heating unit communicating with a lower end of the fluidizing chamber; an air supply unit connected to the heating unit and supplying external air inside the housing to the heating unit; a raw coffee bean injecting unit connected to an upper end of the fluidizing chamber and allowing raw coffee beans to be injected into the fluidizing chamber from an outside; and a coffee discharging unit connected to a lower end of the fluidizing chamber and allowing roasted coffee to be discharged, wherein air heated by the heating unit is supplied to the lower end of the fluidizing chamber and is discharged to an upper end of the fluidizing chamber so that the raw coffee beans are circulated from a lower part of the fluidizing chamber to an upper part of the fluidizing chamber and roasted.

An intelligent separation device has gas explosion, stirring, drying and negative pressure adsorption devices. The gas explosion device receives conveyed peanut materials with red coats to be removed, and the materials are subjected to gas explosion, so that the peanut kernels and the peanut red coats are preliminarily separated. The stirring device shifts the preliminarily separated peanut kernels and peanut red coats into the drying device. The drying device compresses and heating external air, transfers heat through hot air, and heats and dries the preliminarily separated peanut kernels and peanut red coats, so that the peanut red coats and the peanut kernels are fully separated. The negative pressure adsorption device collects the fully separated peanut kernels and red coats with different densities and masses in a negative pressure adsorption mode.