Embodiments of the present invention relate generally to integrated aircraft galleys that provide increased storage and counter space by incorporating improved meal heating systems in the galley area, without requiring changes in the existing aircraft catering processes for loading and serving meals.
Aircraft galleys are different from traditional cooking kitchens, in that space is very limited and weight reduction is a high priority. Similar situations exist on private yachts, cruise ships, and other sea-going vessels, as well as motor homes, passenger trains, and other types of passenger transportation vehicles. Nonetheless, there are still instances when food preparation is necessary, and a high quality food product is expected.
In many aircraft (and other passenger transportation vehicle) galleys, it is useful to provide an oven that cooks or heats food products. These ovens may be bun warmers, microwaves, steam ovens, convection ovens, traditional ovens, and/or heating ovens with warming coils or plates, as well as any other types of heating systems, all of which are collectively referred to herein as “heating systems.” Use of such heating systems on-board aircraft or other transportation vehicles provides a quick, safe, and convenient method for cooking, heating, or re-heating various types of food products and meals.
However, providing one or more of these complete heating systems in the limited galley space area takes up valuable countertop space. Particularly if more than one heating system is required or if more than one type of heating system is installed in the galley, then each heating system has its own heat generator (typically at the back thereof), which takes up additional space. The heat generators may also be redundant, pulling additional power from the aircraft. Accordingly, improved heating solutions are needed for small spaces, such as aircraft galleys, where weight and space considerations are important. It is desirable that such solutions provide more integrated and efficient heating solutions.
Embodiments of the present invention provide improved heating systems for aircraft galleys and other passenger transport vehicles, where meals are prepared. The embodiments are particularly designed to save space and in some instances, may lower the weight of the overall vehicle, by moving (and in some instances, consolidating) heat generating components to a position remote from the cooking cavity. In some embodiments, the heat generating components are positioned in or near the cabin galley ceiling; in other embodiments, the heat generating components may be positioned in other locations on the vehicle. The cooking cavity is fluidly connected to one or more of the heating generating components via a ducting system, so that heat and/or steam can be delivered to the cooking cavity.
Embodiments of the invention described herein thus provide a cooking cavity 12 (or cavities) that is (are) positioned remotely from the heat generator portion(s) 16. (The term “cooking cavity” is used herein to refer to an internal portion of an oven or a heating device, and generally includes an insulated liner only, and does not include any of the other heating components that are traditionally associated with an oven or heating unit.) The cooking cavity may be formed as a vacuum insulated stainless steel liner, with an insulating material surrounding the liner, and an outing casing. One example of a cooking cavity is shown in
As shown in
It is possible to provide one or more of a convection heat generator, an induction heater, a steam heat generator, a radiation heat generator, or any other combination of heat generators desired. A single heat generator may be provided (which may be used to deliver heat to a single or multiple cooking cavities) or multiple heat generators may be provided to deliver various different types of heat or additional forms of the same type of heat to one or more cooking cavities. It is also possible to provide one or more universal heat generators designed to create various types of heat desired in a single unit. It is also possible to provide a cooling unit or one or more universal cooling generators designed to create various types of cooled air as well.
Instead of being positioned above the galley cabinet area as shown in
The heat generator 16 is generally associated with heating supply insulated ducting 18 that is used to deliver the generated heat to the cooking cavity 12. Examples of various configurations of heating supply ducting are shown in
Space is also maximized in the current design because the cooking cavity does not need as much clearance around it (for safety reasons and regulations), because the heat is being generated remotely. The remotely-located heat generator 16 may need the appropriate clearances for cooling and air circulation, but this does not take up valuable space at the galley countertop level. This system also eliminates the required clearances and keeps only the inner cavity (the insulated cooing cavity portion) in the central galley area, which results in freeing galley space that can be used for more cooking and storage space. Additionally, as a result, space in the aircraft cabin can be saved by eliminating, for example, up to even one galley, depending of the size of the aircraft.
When the oven is to be used, the central oven controller 28 is activated to the desired setting. (The provided settings will generally be the traditional oven settings available, such as warm, steam, bake, convection, roast, broil, and so forth). Activation of the controller 28 causes the heat generator 16 to begin generating heat, which may be in the form of hot air and/or steam which is directed to the cooking cavity 12 via the ducting 18. The individual meals in the meal carriers (one example of which is shown in
In an alternate or additional embodiment, the heat generator 16 may include an insulated water hose that connects the heat generator 16 with a beverage maker. This allows the heat generator to heat water that can be delivered to the beverage maker, such that the beverage maker can similarly pull heat from the remote location, saving space and possibly saving energy. In this embodiment, there may be a water reservoir provided near the heat generator 16 in the remote location to either deliver water to the heat generator and/or to contain heated water.
Changes and modifications, additions and deletions may be made to the structures and methods recited above and shown in the drawings without departing from the scope or spirit of the invention and the following claims.
This application claims the benefit of U.S. Provisional Application Ser. No. 61/642,141, filed May 3, 2012, titled “Integrated Galley,” the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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61642141 | May 2012 | US |