Systems and methods for an oven include a housing, a heating chamber positioned within the housing, an external nesting rack coupled to the housing, the external nesting rack is stationary while coupled to the housing, and a movable cook surface, the movable cook surface movable between a position completely within the heating chamber and a position at least partially external to the heating chamber, such that when the movable cook surface is in the position at least partially external to the heating chamber, the movable cook surface is positioned at least partially recessed below a top surface of the external nesting rack.

The present disclosure relates to an oven cavity having a dielectrically coated glass or glass-ceramic substrate that absorbs electromagnetic radiation thereby increasing the temperature of the substrate and the dielectric coating composition, and emits heat radiation into the oven cavity.

The present disclosure relates to an oven cavity having a dielectrically coated glass or glass-ceramic substrate that absorbs electromagnetic radiation thereby increasing the temperature of the substrate and the dielectric coating composition, and emits heat radiation into the oven cavity.

A system and method to control the power supplied to heating elements of a conveyor oven. The conveyor oven includes a plurality of heating elements to evenly distribute heat in an oven compartment. During peak-loads, the current draw of the heating elements may exceed available power of a power supply. Therefore, a system and method to reduce the total current draw of the plurality of heating elements is provided. The system includes a controller configured to perform the methods disclosed herein. The methods effectively lower the total current draw by rapidly cycling a plurality of relays connected to each of the plurality of heating elements to achieve even distribution of heat and reduced current draw during peak-loads.

A system and method to control the power supplied to heating elements of a conveyor oven. The conveyor oven includes a plurality of heating elements to evenly distribute heat in an oven compartment. During peak-loads, the current draw of the heating elements may exceed available power of a power supply. Therefore, a system and method to reduce the total current draw of the plurality of heating elements is provided. The system includes a controller configured to perform the methods disclosed herein. The methods effectively lower the total current draw by rapidly cycling a plurality of relays connected to each of the plurality of heating elements to achieve even distribution of heat and reduced current draw during peak-loads.

There is disclosed a cooking appliance (2010) including: a body (2014) providing a floor (2016), a ceiling (2018) and an intermediate wall (2020) locating between the floor (2016) and ceiling (2018), the floor (2016), ceiling (2018), and wall (2020) at least partly surrounding a cooking cavity (2022), the body (2014) having an opening (2024) via which product to be cooked can be moved relative to the cavity (2022); at least one upper heating element (2030) located in an upper portion (2032) of the cavity (2022) to deliver radiant energy to cook the product; and at least one shield (2034) positioned relative to the element (2030) to shield a portion of the product from the radiant energy.

There is disclosed a cooking appliance (2010) including: a body (2014) providing a floor (2016), a ceiling (2018) and an intermediate wall (2020) locating between the floor (2016) and ceiling (2018), the floor (2016), ceiling (2018), and wall (2020) at least partly surrounding a cooking cavity (2022), the body (2014) having an opening (2024) via which product to be cooked can be moved relative to the cavity (2022); at least one upper heating element (2030) located in an upper portion (2032) of the cavity (2022) to deliver radiant energy to cook the product; and at least one shield (2034) positioned relative to the element (2030) to shield a portion of the product from the radiant energy.

A system and method to control the power supplied to heating elements of a conveyor oven. The conveyor oven includes a plurality of heating elements to evenly distribute heat in an oven compartment. During peak-loads, the current draw of the heating elements may exceed available power of a power supply. Therefore, a system and method to reduce the total current draw of the plurality of heating elements is provided. The system includes a controller configured to perform the methods disclosed herein. The methods effectively lower the total current draw by rapidly cycling a plurality of relays connected to each of the plurality of heating elements to achieve even distribution of heat and reduced current draw during peak-loads.

A system and method to control the power supplied to heating elements of a conveyor oven. The conveyor oven includes a plurality of heating elements to evenly distribute heat in an oven compartment. During peak-loads, the current draw of the heating elements may exceed available power of a power supply. Therefore, a system and method to reduce the total current draw of the plurality of heating elements is provided. The system includes a controller configured to perform the methods disclosed herein. The methods effectively lower the total current draw by rapidly cycling a plurality of relays connected to each of the plurality of heating elements to achieve even distribution of heat and reduced current draw during peak-loads.

Disclosed is a mesh heating system including: two or more electrodes configured to supply a current to the wire mesh heating element; a mesh heating element comprising filaments disposed between the two or more electrodes; and a tensioner to maintain the wire mesh heating element at tension along an axis of tension as the wire mesh heating element is heated, wherein some of the filaments of the mesh heating element are disposed to intersect the axis of tension at a non-orthogonal angle.