A cooling system (12) for a cooking oven (10) is provided. The cooling system (12) has a first air path including a first suction area (28), at least one first fan (20) and a first air guidance (48) of a blowing-out area (30) connected in series. The cooling system (12) has a second air path including a second suction area, at least one second fan (22) and a second air guidance (50) of the blowing-out area (30) connected in series. The first suction area (28) is connected to an oven cavity (14) of the cooking oven (10) via an vapour outlet (32), so that the first air path is provided for conveying moist air. The second suction area is connected to the environment of the cooking oven (10), so that the second air path is provided for conveying dry air.

A cover apparatus operable to at least partially cover an appliance is disclosed. The cover apparatus may include a front side, a left side coupled to the front side, and a right side coupled to the front side. The front side, the left side, and the right side may at least partially form an enclosure. The cover apparatus may also include one or more actuators operable to be mounted to a fixture situated above the appliance. The one or more actuators may be coupled to an underneath surface of the front side via one or more connectors that extend between the one or more actuators and the underneath surface of the front side. The cover apparatus may be operable to move between an open position and a closed position. The appliance may at least partially occupy the enclosure when the cover apparatus is in the closed position.

A microwave appliance, as provided herein, may include a cabinet, a door, and an air handler. The cabinet may extend in a lateral direction between a first side end and a second side end. The door may be movably mounted to the cabinet at the first side end or the second side end to move between an open position permitting access to a cooking chamber and a closed position restricting access to the cooking chamber. The door may include a peripheral frame and a front window bounded by the peripheral frame. The peripheral frame may define an air inlet and an air outlet downstream from the air inlet. The air outlet may be defined below the front window. The air handler may be mounted within the door in fluid communication between the air inlet and the air outlet to motivate an airflow therethrough.

A microwave appliance, as provided herein, may include an outer casing, an inner liner, a door, and an air handler. The outer casing may define an air inlet above a cooktop appliance. The outer casing may extend in a lateral direction between a first side end and a second side end. The inner casing may define a cooking chamber. The door may include a peripheral frame and a front window bounded by the peripheral frame. The peripheral frame may define an air outlet downstream from the air inlet and below the front window along the vertical direction. The air handler may be mounted within the outer casing in fluid communication between the air inlet and the air outlet to motivate an airflow therethrough. The air outlet may define an airflow curtain path extending outward from the outer casing in front of the door.

A microwave oven avoids being upsized. The microwave oven includes a housing including a cooking chamber inside the housing, a component chamber inside the housing, a first opening in a front portion of the housing and communicating with the cooking chamber, and an outlet in a rear portion of the housing and allowing air to be discharged from the component chamber to flow through the outlet. The microwave oven also includes a heat-generating component in the component chamber, a door at a front portion of the housing to cover and uncover the first opening, and a battery mount at a rear portion of the housing to detachably receive a battery pack.

The present application discloses a cooking device, which includes a cabinet; the cabinet includes an inner cavity, a first heating assembly and a second heating assembly; the inner cavity is provided with a cooking chamber, as well as a first side wall and a second side wall that are arranged opposite to each other, the first side wall is provided with a first ventilation structure, and the second side wall is provided with a second ventilation structure; the first heating assembly is arranged outside the inner cavity and arranged corresponding to the first ventilation structure, and is configured to circularly heat air in the cooking chamber; the second heating assembly is arranged outside the inner cavity and arranged corresponding to the second ventilation structure, and is configured to circularly heat the air in the cooking chamber.

A combination lifting mechanism for a microwave oven, or other appliance, and a cooking range ventilating hood. The lifting mechanism lifts the microwave within the open bottom portion of the hood and lowers the microwave oven for user access into the microwave oven. The lifting mechanism includes a support plate for the microwave oven and a lifting belt attached to the support plate. A motor wraps or unwraps a lifting belt onto a spool to either raise or lower the support plate. An isolation chamber is located in the open lower portion of the hood and is sized and configured to receive the microwave over therein to protect the microwave oven from cooking gas and grease when the range below is used during cooking.

The present disclosure relates to a drawer-type microwave oven comprising a cooker body, a door, a front plate, a first slide rail, a second slide rail, a driving motor and a flow directing assembly. An air inlet end of the flow directing assembly is in communication with an air outlet mesh, and an air outlet end of the flow directing assembly is arranged at the bottom of a first spacing region. When the above drawer-type microwave oven works, the high-temperature water vapor inside the cooking cavity is discharged into the flow directing assembly through the air outlet mesh, and is directed and discharged to the bottom of the first spacing region by the flow directing assembly, and then flows along a bottom of the cooking cavity, and is discharged to the outside of the cooker body through a front side air outlet hole, which can prevent the high-temperature water vapor from contacting and damaging the first slide rail, and the high-temperature water vapor will not contact the second slide rail and the driving motor. Thus, the erosion effect of the high-temperature water vapor on the slide rails and the driving motor can be greatly reduced, thereby allowing the slide rails and the driving motor of the drawer-type microwave oven to be not prone to damage and to realize normal long-term operation.

A microwave hood system includes an outer wrapper with a top portion including a cooling air inlet, a cooling air outlet, an outside vent outlet, and a recirculation vent outlet, a first side portion, and a second side portion. A bottom portion includes a vent inlet and is operably coupled to the outer wrapper. A cooking cavity is disposed between the top portion and the bottom portion. A cooking component area is laterally adjacent one of the first side portion and the second side portion. A hood assembly includes a first hood fan disposed between the first side portion and the cooking cavity and a second hood fan disposed between the second side portion and the cooking cavity. A cooling fan is disposed in the cooking component area proximate the second side portion. The cooling fan is in fluid communication with the cooling air inlet.

The present disclosure relates to an exhaust device. The exhaust gas according to the present disclosure includes a base plate and a swirler. The base plate includes a swirler installation part, an auxiliary intake part, a suction port opened in the swirler installation part, and an auxiliary suction port opened in the auxiliary intake part. In this case, air flows through the base plate via the suction port and the auxiliary suction port.