Cooking ovens capable of steam cooking are known in the art. Existing steam ovens typically include a powered steam generator outside of the cooking cavity that delivers steam into the cooking cavity. This requires a system of pipes and valves to conduct the steam into the oven cavity. It would be desirable to generate steam directly in the oven cavity where it will be used.
A cooking oven that includes a cooking cavity and a steam generation system is disclosed. The steam generation system includes a reservoir rack configured to support a water reservoir, a water reservoir configured to be supported by the reservoir rack, and a heater. The heater is arranged within the cooking cavity so that it is in conductive thermal communication with the water reservoir when the water reservoir is supported by the reservoir rack and the reservoir rack is in a cooking position within the oven cavity.
A cooking oven can include a cooking cavity accessible via an oven door and a steam generation system capable of generating steam for cooking food via steam cooking.
The steam generation system includes a water reservoir for holding water that can be heated into steam. The water reservoir has an inner volume for containing water and an opening that allows water to be filled into the inner volume and steam to escape into the cooking cavity. The water reservoir can be generally in the shape of a rectangular cuboid, including a bottom wall, side walls, and an open upper surface constituting the opening. The bottom wall and side walls define the inner volume that can contain water. Alternatively, the water reservoir can have a water filling section at a front end and a thermal contact section at the opposite, rear end connected by a sloped section for guiding waster from the water filling section to the thermal contact section via gravity. In some embodiments, the sloped bottom also serves as the water pouring section. For example, the water reservoir can have a general triangular prism shape with a sloped bottom wall section spanning the water pouring section and the thermal contact section.
In the disclosed embodiments, the water reservoir is configured such that it can be received and supported by a water-reservoir rack held by oven rack guides in the cooking cavity. The rack can be slid into and out of the cooking cavity supported by the rack guides like a conventional oven rack. Specifically, the reservoir rack is movable between a cooking position, where it is fully inserted in the cooking cavity, and a loading position, where it is fully withdrawn from the cooking cavity. The reservoir rack can also be removed from the cooking cavity so that it can be cleaned or the cooking cavity can be utilized in a way that the reservoir rack might otherwise impede.
Preferably, the water reservoir is configured such that is securely received and supported by the reservoir rack in use. For example, the water reservoir is preferably configured such that when received and supported by the reservoir rack, it is constrained in 5 of 6 directions (i.e. up, down, left, right, front, rear) of movement. As a result of this constriction, the water reservoir is preferably only able to be removed in the vertical direction. In this regard, the water reservoir does not move substantially with respect to the reservoir rack when the reservoir rack is slid into and out of the cooking oven. Because the water reservoir does not move substantially with respect to the reservoir rack, water spillage is reduced.
In a first embodiment the reservoir rack defines a water reservoir-receiving space that is designed to receive and support the water reservoir when in use within the cooking cavity. Preferably, the reservoir rack is designed as an otherwise conventional oven rack but for the receiving space. Thus, the reservoir rack can be in the form of a cooking grid made of metal bars arranged in a grid-like manner. A food item can be placed on the cooking grid to be cooked in the cooking cavity. The receiving space is preferably defined by the bars that form the rack to yield a shape that substantially corresponds to the shape of the water reservoir such that the reservoir can be received within the receiving space. The receiving space can be formed as a cutout in the grid of the reservoir rack. Alternatively, it can be located partially or fully outside that grid. The receiving space is preferably positioned in the reservoir rack such that it is adjacent the rear wall of the cooking cavity when the reservoir rack is fully inserted in the cooking position. In this regard, the cooking grid can receive a food item to be cooked without interfering with the water reservoir also supported on that rack. Thus, steam can emanate from the water reservoir to permeate the cooking cavity without being impeded by a cooking item on the reservoir rack. Moreover, the reservoir rack can be utilized in any manner as a conventional oven rack is utilized because the water reservoir-receiving space is largely out of the way at the rear of the rack.
The water reservoir preferably penetrates the receiving space in the water-reservoir rack when installed according to the present embodiment, such that it protrudes from an underside of that rack. For example, the water reservoir can be shaped such that its side walls are slanted to have a greater than 90° angle with the bottom wall such that the width of the water reservoir increases from the bottom wall to its opening at the top. The water reservoir can be inserted into the reservoir-receiving space until the perimeter of the reservoir matches the perimeter of the reservoir-receiving space such that the receiving space supports the reservoir. Alternatively, a perimeter flange can be attached or formed to the outer sides of the side walls of the water reservoir, or as a lip extending about the opening of the reservoir. The perimeter flange can engage the perimeter of the reservoir-receiving space such that the reservoir is supported thereby.
The water reservoir is preferably received and supported in the reservoir-receiving space such that when the reservoir rack is fully slid into the cooking oven, an outer surface of the water reservoir is in conductive thermal communication with a heater that is capable of generating thermal energy for converting water in the reservoir to steam. The thermal communication is preferably facilitated by intimate contact between an outer surface of the water reservoir and the heater. Preferably, the heater intimately contacts a lower portion of the water reservoir (i.e., a bottom outer wall surface or a bottom portion of an outer side wall surface). In this regard, as water is heated and converted to steam and the water volume in the reservoir decreases, liquid water remains in the vicinity of where the heater transmits thermal energy to the reservoir.
In another embodiment the water reservoir can include hooks that are used to suspend the reservoir from and beneath an oven rack. In this embodiment, the aforementioned hooks engage and are supported by bars or other structure of the oven rack in order to suspend the reservoir attached to the hooks. Such a water reservoir is preferably configured to have a water pouring section at a front end and a thermal contact section designed for contacting a heater at the opposite, rear end. The water pouring section and thermal contact section can be connected by a sloped section for guiding water from the water pouring section to the thermal contact section via gravity. In this configuration, the water reservoir can extend across most of the depth of the oven rack such that, when the water reservoir is suspended from an oven rack that is fully inserted within the oven cavity, the water pouring section is near the front and the thermal contact section is near the back for engaging the heater. Water can thus be poured into the water pouring section without the need to remove the reservoir or withdraw the rack, or to reach far into the oven cavity. In this embodiment additional water can be added to the water reservoir during use while minimizing risk of a user injury.
The heater can include a thermal block composed of thermally conductive material in thermal communication with (e.g. having embedded therein) an electric heating element. Alternatively, the heater can include an electric heating element without a thermal block. Preferably, the heating element is a resistance heating element such as a calrod element. The heating element typically includes heating element connectors at either end to establish a connection with a power source to supply power to the heating element. The heating element connectors can be plugged into sockets to complete an electrical heating circuit with the power source. Preferably those sockets are disposed in a rear wall of the cooking cavity, or they can be disposed behind the rear wall. In the latter embodiment, a portion of the heating element extends through openings in the rear wall of the cooking cavity in order to plug its connectors into the associated sockets behind that wall. These openings can be sealed to thermally insulate the cooking cavity and prevent fluids from passing through. Furthermore, the heating element is preferably wired in series with a thermal cut-off switch, or alternatively with a relay that is controlled based on temperature signals sensed by a temperature sensor. In this regard, when a certain temperature threshold is detected by the temperature sensor or is experienced by the thermal cut-off switch, the relay/switch can open the electrical circuit between the element and its power source to cease the generation of thermal energy.
When configured as a thermal block as described above, the heater is configured so that a wall of that block intimately contacts an outer surface of the water reservoir in use to efficiently deliver thermal energy to the reservoir when that reservoir is in reservoir-receiving space of the reservoir rack and the reservoir rack is in the cooking position. Preferably, the thermal block contacts a lower outer surface of the water reservoir. For example, the bottom outer surface of the reservoir can rest on the upper surface of the thermal block. Alternatively, a bottom portion of one or more outer side-wall surfaces of the water reservoir can contact the thermal block in use. Because the thermal block contacts the bottom or other lower surface of the water reservoir, it remains in close proximity to the remaining water throughout the process of steam generation. Among other advantages, this reduces heat loss in the generation of steam. The block is preferably located at the rear of the cooking cavity such that when the reservoir rack is in the cooking position, the water containing space aligns with the thermal block. When configured without a thermal block, the heater is configured so that the heating element itself intimately contacts an outer surface of the water reservoir in use to efficiently deliver thermal energy to the reservoir.
In order to reduce the likelihood that debris or other undesired material will fall into the water reservoir, the steam generation system can include a water-reservoir lid to close the opening of the water reservoir. The reservoir can have inner flanges extending from the inner side walls of the water reservoir for supporting the reservoir lid. Alternatively, the reservoir can close the opening of the reservoir by other conventional means. The reservoir lid itself has steam openings that allow steam produced in the water reservoir to escape into the cooking cavity. The size of the steam openings is preferably such that the steam produced in the water reservoir can easily escape but at the same time most debris produced inside a cooking cavity will not be small enough to fit through. The water reservoir can also have one or more larger openings constituting water filling ports so that the water reservoir can be filled without the need to remove the lid. These water filling ports are preferably large enough that water from common sources such as a faucet or a pitcher can flow through the ports easily. A user can add water to the reservoir through the water filling port in different ways. For example, a user can reach into the cooking cavity and pour water through the filling port using a pitcher. This can be done with the reservoir rack in the cooking position, the loading position, or anywhere in between. Additionally, the reservoir can be removed from the reservoir rack and filled outside of the cooking cavity, for example at a faucet.
The cooking oven can also include a convection fan preferably located at the rear wall of the cooking cavity above the water reservoir in order to circulate steam produced in the water reservoir. In addition to providing heat for the water reservoir, the heating element disclosed herein can also extend to the proximity of the convection fan in order to separately or additionally supply heat as part of a convection-cooking function.
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Illustrative embodiments have been described, hereinabove. It will be apparent to those skilled in the art that the above apparatuses and methods may incorporate changes and modifications without departing from the scope of this disclosure. The invention is therefore not limited to particular details of this disclosure, and covers such modifications thereto as come within the spirit and the scope of the claims.