A smoke generating assembly for an indoor smoker includes a smoke barrel having a rotating auger positioned therein. The smoke barrel may be supplied with combustible material at a first end of the smoke barrel and the auger may be intermittently rotated to advance the combustible material toward a second end of the smoke barrel and over a smoldering heater to generate a flow of smoke. The smoldering heater may be spaced apart from the smoke barrel by an insulating spacer to regulate a temperature of the smoke barrel independent of the smoldering heater.

A smoke generating assembly for an indoor smoker includes a smoke barrel having a rotating auger positioned therein. The smoke barrel may be supplied with combustible material at a first end of the smoke barrel and the auger may be intermittently rotated to advance the combustible material toward a second end of the smoke barrel and over a smoldering heater to generate a flow of smoke. The smoldering heater may be spaced apart from the smoke barrel by an insulating spacer to regulate a temperature of the smoke barrel independent of the smoldering heater.

The disclosed embodiments provide a kamado-style grill and smoker having one or more air-intake openings and one or more exhaust openings. Like conventional kamado-style grills and smokers, a user may manually adjust the air-intake opening(s) and/or exhaust opening(s) to manually control the air flow, and thus the temperature, within the cooking chamber. However, unlike the prior art, the kamado-style grill and smoker includes an integrated fan unit that provides a completely different and alternative air-intake pathway for drawing air into the cooking chamber and controlling the cooking or smoking temperature using a fan. By providing this alternative mechanism for controlling the temperature in the cooking chamber, the kamado-style grill and smoker disclosed herein can be operated using either manual or automated temperature control, making it accessible to both novice and experienced users alike.

The disclosed embodiments provide a kamado-style grill and smoker having one or more air-intake openings and one or more exhaust openings. Like conventional kamado-style grills and smokers, a user may manually adjust the air-intake opening(s) and/or exhaust opening(s) to manually control the air flow, and thus the temperature, within the cooking chamber. However, unlike the prior art, the kamado-style grill and smoker includes an integrated fan unit that provides a completely different and alternative air-intake pathway for drawing air into the cooking chamber and controlling the cooking or smoking temperature using a fan. By providing this alternative mechanism for controlling the temperature in the cooking chamber, the kamado-style grill and smoker disclosed herein can be operated using either manual or automated temperature control, making it accessible to both novice and experienced users alike.

Embodiments are directed to smoking food in an outdoor grill using a customized smoking routine. In one scenario, an electronic controller of an outdoor grill receives an input to initiate smoke generation according to a specified smoke generation pattern, including: adding a specified amount of combustible pellets to a combustion area within the outdoor grill, such that the combustible pellets begin to burn, measuring a current internal temperature of the outdoor grill and, if below a threshold value, adding a specified amount of additional combustible pellets to the combustion area sufficient to raise the temperature to another threshold value, allowing the internal temperature to cool a temperature below the first threshold value and, upon determining that the temperature of the outdoor grill has cooled below the first specified threshold value, adding additional combustible pellets to the combustion area sufficient to raise the temperature to at least the second threshold value.

Embodiments are directed to smoking food in an outdoor grill using a customized smoking routine. In one scenario, an electronic controller of an outdoor grill receives an input to initiate smoke generation according to a specified smoke generation pattern, including: adding a specified amount of combustible pellets to a combustion area within the outdoor grill, such that the combustible pellets begin to burn, measuring a current internal temperature of the outdoor grill and, if below a threshold value, adding a specified amount of additional combustible pellets to the combustion area sufficient to raise the temperature to another threshold value, allowing the internal temperature to cool a temperature below the first threshold value and, upon determining that the temperature of the outdoor grill has cooled below the first specified threshold value, adding additional combustible pellets to the combustion area sufficient to raise the temperature to at least the second threshold value.

The disclosed embodiments provide a kamado-style grill and smoker having one or more air-intake openings and one or more exhaust openings. Like conventional kamado-style grills and smokers, a user may manually adjust the air-intake opening(s) and/or exhaust opening(s) to manually control the air flow, and thus the temperature, within the cooking chamber. However, unlike the prior art, the kamado-style grill and smoker includes an integrated fan unit that provides a completely different and alternative air-intake pathway for drawing air into the cooking chamber and controlling the cooking or smoking temperature using a fan. By providing this alternative mechanism for controlling the temperature in the cooking chamber, the kamado-style grill and smoker disclosed herein can be operated using either manual or automated temperature control, making it accessible to both novice and experienced users alike.

The disclosed embodiments provide a kamado-style grill and smoker having one or more air-intake openings and one or more exhaust openings. Like conventional kamado-style grills and smokers, a user may manually adjust the air-intake opening(s) and/or exhaust opening(s) to manually control the air flow, and thus the temperature, within the cooking chamber. However, unlike the prior art, the kamado-style grill and smoker includes an integrated fan unit that provides a completely different and alternative air-intake pathway for drawing air into the cooking chamber and controlling the cooking or smoking temperature using a fan. By providing this alternative mechanism for controlling the temperature in the cooking chamber, the kamado-style grill and smoker disclosed herein can be operated using either manual or automated temperature control, making it accessible to both novice and experienced users alike.

In an aspect, data characterizing an instruction for an activation of an igniter and an operating mode of a smoke generator that includes the igniter can be received. A first amount of energy required for an ignition of a fuel source by the igniter can be determined based on the operating mode characterized by the received data. The igniter can be caused to activate based on the received data. A second amount of energy, output by the igniter over a period of time during which the igniter is activated, can be determined. A determination of whether the second amount of energy exceeds the first amount of energy can be made. The igniter can be caused to deactivate in response to a determination that the second amount of energy exceeds the first amount of energy. Related systems, apparatus, techniques, and articles are also described.

In an aspect, data characterizing an instruction for an activation of an igniter and an operating mode of a smoke generator that includes the igniter can be received. A first amount of energy required for an ignition of a fuel source by the igniter can be determined based on the operating mode characterized by the received data. The igniter can be caused to activate based on the received data. A second amount of energy, output by the igniter over a period of time during which the igniter is activated, can be determined. A determination of whether the second amount of energy exceeds the first amount of energy can be made. The igniter can be caused to deactivate in response to a determination that the second amount of energy exceeds the first amount of energy. Related systems, apparatus, techniques, and articles are also described.