The present invention pertains to the art of cooking appliances and, more particularly, to a convection cooking system for an appliance having a small oven cavity.
Conventional cooking appliances generally perform cooking operations through radiant heating developed from bake and/or broil elements. Such types of cooking appliances can take various forms, mainly ranges and wall ovens. While conventional or radiant heat cooking is suitable to a wide assortment of food types, the overall cooking process, especially baking, can be quite slow. The pre-heat time, combined with the cook time, is longer than most consumers desire.
Some radiant cooking appliances incorporate internal fans which can be used during certain cooking operations in order to generate an air flow within an oven cavity to enhance even cooking. Forced air convection allows for cooking at lower temperatures as compared to conventional radiant cooking processes. In addition, the forced air streams serve to disrupt a thermal insulation layer about the food item which increases the heat transfer rate between the food item and its surroundings, thereby reducing required cooking times.
In convection cooking appliances, the air flow can be designed to recirculate within the oven cavity, flow through the oven cavity and be exhausted, or a combination of both of these configurations. For obvious reasons, it is desirable to enhance the efficiency of any air flow system in order to reduce associated operating costs and minimize the required fan size, while still producing an effective air flow pattern and rate. Most convection systems employ a fan which draws cooking cavity air into a central intake portion and directs the air radially outward across a heating unit for re-introduction back into the oven cavity through plural, spaced exhaust outlets. Most often, the outlets are arranged either directly adjacent the side walls of the cooking cavity or the outlets are simply arranged in a generally circular configuration about the air inlet and angled toward the side walls. In either case, the air is exhausted along the side walls, flows forward towards a door for the oven cavity and then is re-directed into a central oven cavity region back to the fan intake.
With relatively large oven cavities, such as oven cavities of 4.0 cubic feet or more, the above-described air flow arrangement is quite effective. However, with smaller oven cavities in the order of 2.5 cubic feet or less, special spacial and air flow considerations are encountered. For instance, from just a dimensional standpoint, utilizing a conventional convection arrangement in a small oven cavity would result in the inlet and outlet portions being in close proximity which would tend to reduce the amount of air turnover inside the oven cavity. Therefore, regardless of the existence of numerous convection systems in the art, there exists a need for an enhanced convection air flow system for use in a cooking appliance, particularly a cooking appliance having a small oven cavity.
The present invention is directed to a cooking appliance including a convection system employing a convection cover used to establish a circular air flow pattern in an oven cavity, preferably a relatively small oven cavity. In accordance with the invention, a fan of the convection system is mounted behind the convection cover directly adjacent one side wall of the oven cavity. The convection cover has a first end portion formed with an air intake exposed to an inlet of the fan and tapers across a rear wall of the oven cavity, preferably through multiple, progressively tapering sections, to a second end portion directly adjacent an opposing side wall. At the second end portion, the convection cover is provided with a plurality of spaced air outlets or exhausts.
The cover is mounted to a rear wall oven the oven cavity, while also being spaced from the rear wall to define, in combination with the rear wall, a duct extending across the rear wall from the intake to the exhausts. The cover is constructed such that the intake is defined by at least one opening arranged to draw air into the fan at only one side of the oven cavity, while a plurality of small exhaust openings are provided at the other side of the oven cavity. With this arrangement, the air is forced to follow a circular air flow pattern or loop around the interior of the oven cavity.
Additional objects, features and advantages of the present invention will become more readily apparent from the following detailed description of a preferred embodiment when taken in conjunction with the drawings wherein like reference numerals refer to corresponding parts in the several views.
With initial reference to
Cabinet 5 is also provided with an associated range top 18 which supports various spaced surface heating elements 20-23 in a manner known in the art. At an upper rear portion, cabinet 5 includes an upstanding portion 26 which is provided with a control panel 28. At this point, it should be realized that the arrangement and location of control panel 28 could vary in accordance with the present invention. For example, control panel 28 could be located along an upper face panel 32 of cabinet 5. In any event, upstanding portion 26 includes a plurality of knobs 36-39 for use in selectively activating and deactivating surface heating elements 20-23 respectively. Control panel 28 is preferably arranged between knobs 36-39 and is shown to include a substantially central display 44, such as an LED, LCD or VFD display unit. Furthermore, control panel 28 is provided with a number pad generally indicated at 46 that has an associated button 48 for use in setting a clock arranged either within display 44 or in another portion of control panel 28.
As also known in the art and shown in this figure, control panel 28 of range 2 includes a first row of control buttons generally indicated at 51 which are generally used to establish an operational mode for upper oven 8. Although not separately labeled, first row 51 preferably includes cancel, bake, broil, convection cooking, cleaning mode, toasting and warming mode control members shown in the form of buttons, such as button 54 for convection cooking. In a generally similar manner, a second row of control buttons 61 are provided for lower oven 9. In the most preferred form of the invention, second row 61 includes cancel, bake, broil, cleaning mode, and light control members, preferably in the form of individual buttons. In the most preferred form of the invention, the user is able to program the operation of at least upper and lower ovens 8 and 9 through the use of the first and second rows of buttons 51 and 61, along with numeric pad 46, timer buttons 70 and 72, cook time and stop time buttons 74 and 76, and an auto set button 78. Since this basic programming arrangement is known in the art as exemplified by U.S. Pat. No. 6,255,630, which is incorporated herein by reference, and not considered part of the present invention, it will not be described further here in detail. Instead, with reference to this illustrative embodiment, the inclusion of a convection mode, either operated alone or in combination with any of the other cooking modes, is of concern with respect to the present invention and, more particularly, the air flow system employed with the convection cooking, including a convection cover as indicated at 100 mounted to a back wall 102 of oven cavity 104 for oven 8 as detailed below.
With reference to
More important to the present invention, as depicted in
At this point, as perhaps best illustrated in
As depicted in
With convection cover 100 mounted in the manner discussed above, fan 209 is arranged behind intake 138 such that activation of motor 193 causes air to be drawn into intake 138 and propelled radially outwardly from fan 209 toward second end portion 147 and outlet openings 153. In accordance with the invention, at a minimum, the configuration of convection cover 100 establishes a duct, in combination with rear wall 102, for this airflow. In the preferred embodiment shown, recessed section 177 accommodates fan 209 and further establishes a portion of this duct. That is, at this point, it should be recognized that the invention can be employed without recessed section 177, thereby establishing the required airflow duct based solely on the construction of convection cover 100 in combination with rear wall 102. However, with the inclusion of recessed section 177, the thickness or depth of convection cover 100 can be reduced without sacrificing the volumetric airflow capacity of the overall system. To this end, recessed section 177 is preferably formed in rear wall 102, such as through a stamping operation. In any case, during operation of the overall convection system, air is drawn into central opening 138 at one side portion of oven cavity 104, forced behind convection cover 100 to outlet openings 153 at a second side portion of the oven cavity 104. Due to these spaced locations, the airflow in the overall oven cavity 104 will be forced to flow forward from adjacent side wall 116 towards door 10, then along door 10 to adjacent second side wall 115 and back toward central opening 138. To this end, convection cover 100 is constructed such that the central intake 138 is arranged to draw air into fan 209 at only one side of oven cavity 104, while the plurality of small exhaust openings 153 are provided at the other side of oven cavity 104 such that the overall arrangement forces the air to follow a single, circular airflow pattern or loop around the interior of oven cavity 104. This overall configuration is seen to be particularly important with the reduced sized oven cavity of the invention which generally has a volume in the order of 2.5 cubic feet or less. By providing one or more tapered sections associated with convection cover 100, particularly tapered sections 140 and 145, the pressure and flow rate of the airflow is optimized in order to ensure an effective circular airflow pattern throughout oven cavity 104 and the airflow rate changes from a first flow rate going into tapered section 140 to a second flow rate leaving tapered section 145 through openings 153 that is greater than the first flow rate.
Although described with reference to a preferred embodiment of the invention, it should be readily understood that various changes and/or modifications can be made to the invention without departing from the spirit thereof. For instance, although the invention has been described with respect to an electric cooking appliance, it should be readily understood that the invention could be readily applied in connection with other heat sources, including natural or propane gas sources. In addition, although the invention has been described with reference to a range having a upper and lower ovens, the invention can also be employed in connection with other types of ovens, including wall ovens having reduced oven cavity sizes which provide for quicker heating and cooking times. Furthermore, although not shown or described, it should be readily recognized that the oven includes bake and broil heating elements which are used in combination with the convection airflow system of the invention. In general, the invention is only intended to be limited by the scope of the following claims.
The present application represents a divisional of U.S. patent application Ser. No. 12/404,581 entitled “Convection Cooking Appliance with Circular Air Flow System” filed Mar. 16, 2009, pending, whose entire content is incorporated herein by reference.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 12404581 | Mar 2009 | US |
Child | 15377015 | US |