Mobile galley cart with heating, cooling and braking functionality

Abstract

A mobile galley cart including a wheeled insulated housing having a door configured to open to access to the interior of the housing, a thermoelectric chiller mounted near the bottom of the cart, cold air ducting in fluid communication with the thermoelectric chiller and opening to the interior of the housing, and warm air ducting including a warm air exhaust arranged to exhaust warm air from the mobile galley cart. A mobile galley cart system including a cart configured to dock at a separate service wall to provide service connections therebetween.

Claims

1. An aircraft galley cart, comprising: a housing comprising a bottom, a top, two side walls, a first end wall, and a second end wall; a first handle assembly mounted to an upper end of the first end wall; a second handle assembly mounted to an upper end of the second end wall, wherein each of the first handle assembly and the second handle assembly includes an articulating member that moves between a first position when the handle assembly is grasped by a user and a second position when the handle assembly is not being grasped by the user; at least four wheels, wherein each wheel of the at least four wheels is mounted proximate to a respective corner of four corners of the bottom of the housing; at least one braking assembly configured to selectively engage or disengage a wheel brake on one or more of the at least four wheels; and a cabling assembly connecting each of the first handle assembly and the second handle assembly to the at least one braking assembly, wherein the cabling assembly is configured to disengage the at least one braking assembly upon actuation of the articulating member of either of the first handle and the second handle to the first position, and to engage the at least one braking assembly upon actuation of the articulating member of both the first handle assembly and the second handle assembly to the second position, wherein the cabling assembly comprises: a first cable routed from one end of the first handle assembly, down a first side of the first end wall, along the bottom of the housing and communicatively connecting to the at least one braking assembly, and up a second side of the first end wall to a second end of the first handle assembly; and a second cable routed from one end of the second handle assembly, down a first side of the second end wall, along the bottom of the housing and communicatively connecting to the at least one braking assembly, and up a second side of the second end wall to a second end of the second handle assembly; wherein the at least one braking assembly is configured for independent actuation by the first handle assembly and the second handle assembly, wherein the at least one braking assembly engages the wheel brake on the one or more of the at least four wheels when the respective articulating member of both the first handle assembly and the second handle assembly are simultaneously in the second position, and the at least one braking assembly disengages the wheel brake on the one or more of the at least four wheels when the respective articulating member of either the first handle assembly or the second handle assembly is in the first position.

2. The aircraft galley cart of claim 1, wherein the cabling assembly comprises a plurality of pulleys each configured to apply tension to a respective cable upon actuation of the articulating member of both the first handle assembly and the second handle assembly to the second position.

3. The aircraft galley cart of claim 1, wherein the first end wall comprises a first door and the second end wall comprises a second door, the first cable being routed along a vertical hinge region of the first door, and the second cable being routed along a vertical hinge region of the second door.

4. The aircraft galley cart of claim 3, wherein each of the first door and the second door is connected to one of the two side walls via a respective double throw rotating block hinge assembly.

5. The aircraft galley cart of claim 1, wherein the first handle assembly comprises a bar extending across a width of the first end wall of the housing.

6. The aircraft galley cart of claim 1, wherein the respective articulating member of each of the first handle assembly and the second handle assembly comprises a rotatable handle, wherein the rotatable handle is rotated downward in the first position, and the rotatable handle is rotated upward in the second position.

7. The aircraft galley cart of claim 6, wherein the respective rotatable handle of each of the first handle assembly and the second handle assembly is spring biased to rotate upward upon release by the user.

8. The aircraft galley cart of claim 1, further comprising a first bar mounted to a lower end of one of the first end wall and the second end wall, wherein the first bar is configured to releasably engage a corresponding first latch mounted to a service wall of a cart bay.

9. The aircraft galley cart of claim 8, wherein at least one of the first handle assembly and the second handle assembly is configured to releasably engage a corresponding second latch mounted to an upper portion of the service wall of the cart bay.

10. A braking system for an aircraft galley cart, comprising: a first handle assembly for mounting to a first end wall of a housing of the aircraft galley cart; a second handle assembly for mounting to a second end wall of the housing, wherein each of the first handle assembly and the second handle assembly includes an articulating member that moves between a first position when the respective handle assembly is grasped by a user and a second position when the respective handle assembly is not being grasped by the user; at least one braking assembly configured, upon installation, to selectively engage or disengage wheel brakes on one or more of a plurality of wheels of the aircraft galley cart; and a translation assembly connecting each of the first handle assembly and the second handle assembly to the at least one braking assembly, wherein the translation assembly and the at least one braking assembly are configured to cooperate to disengage the wheel brakes on the one or more of the plurality of wheels upon movement of the articulating member of one of the first handle assembly and the second handle assembly into the first position, and to engage the wheel brakes on the one or more of the plurality of wheels upon the articulating member of both of the first handle assembly and the second handle assembly being simultaneously in the second position, wherein the translation assembly comprises: a first cable routed, upon installation, from one end of the first handle assembly, down a first side of the first end wall, along the bottom of the housing and communicatively connecting to the at least one braking assembly, and up a second side of the first end wall to a second end of the first handle assembly; and a second cable routed, upon installation, from one end of the second handle assembly, down a first side of the second end wall, along the bottom of the housing and communicatively connecting to the at least one braking assembly, and up a second side of the second end wall to a second end of the second handle assembly.

11. The braking system of claim 10, wherein the translation assembly comprises a plurality of cables.

12. The braking system of claim 11, wherein the translation assembly comprises a plurality of pulleys each configured to apply tension to a respective cable of the plurality of cables when the respective articulating member of each of the first handle assembly and the second handle assembly is in the second position.

13. The braking system of claim 10, wherein the first handle assembly comprises a bar extending across a width of the first end wall.

14. The braking system of claim 10, wherein the respective articulating member of each of the first handle assembly and the second handle assembly comprises a rotatable handle, wherein the rotatable handle is rotated downward in the first position, and the rotatable handle is rotated upward in the second position.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) These and other features, aspects and advantages of the present invention are better understood when the following detailed description of the invention is read with reference to the accompanying drawings, in which:

(2) FIG. 1 is a sectional view through the width of a galley cart according to an embodiment of the invention;

(3) FIG. 2 is a top view into the interior of the galley cart;

(4) FIG. 3 is an end view of the galley cart shown with the door open;

(5) FIG. 4 is a bottom view of the galley cart;

(6) FIG. 5 is a side elevation view showing the galley cart docked at a separate service wall;

(7) FIG. 6 is an end view of the galley cart showing service wall connections;

(8) FIG. 7 illustrates service wall air returns;

(9) FIG. 8 illustrates air exchange between the service wall and the galley cart;

(10) FIG. 9 illustrates air circulation within the galley cart and between the galley cart and the service wall;

(11) FIG. 10 is an end view of the galley cart illustrating a handle;

(12) FIG. 11 is a side view of the cart illustrating platen compartmentalization of the interior;

(13) FIG. 12 is a side view of the cart with the door removed to illustrate a specific platen arrangement;

(14) FIG. 13 is a detailed view of the service connections between the galley cart and the service wall;

(15) FIG. 14 is an isolated view of the handle and braking mechanism arrangement of the galley cart;

(16) FIG. 15 illustrates a galley cart service wall latch;

(17) FIG. 16 is an isometric view of a galley cart handle;

(18) FIGS. 17a-e are sequential views of service wall latch operation;

(19) FIG. 18 illustrates service wall latching;

(20) FIG. 19 illustrates galley cart latching bars;

(21) FIG. 20 shows two galley carts docked side-by-side at a service wall;

(22) FIGS. 21a-c are sequential views illustrating the operation of a visual latching indicator;

(23) FIGS. 22a-c are sequential views of galley cart door hinge operation;

(24) FIGS. 23a-c illustrate various meal tray configurations;

(25) FIG. 24 shows a meal tray configuration; and

(26) FIG. 25 shows a meal tray configuration including a heated beverage area.

DETAILED DESCRIPTION OF THE INVENTION

(27) The present invention will now be described more fully hereinafter with reference to the accompanying drawings in which exemplary embodiments of the invention are shown. However, the invention may be embodied in many different forms and should not be construed as limited to the representative embodiments set forth herein. The exemplary embodiments are provided so that this disclosure will be both thorough and complete, and will fully convey the scope of the invention and enable one of ordinary skill in the art to make, use and practice the invention. Like reference numbers refer to like elements throughout the various drawings.

(28) Referring to FIGS. 1-4, a mobile galley cart according to an embodiment of the invention is shown generally at reference numeral 20. The galley cart 20 includes a wheeled, insulated housing 22 formed from a pair of opposing sidewalls, a pair of opposing end walls, a top and a bottom. One or more of the opposing end walls is a door 32 configured to open and close to provide access to the interior of the cart 20. The walls, doors, top and bottom are preferably insulated so as to maintain a predetermined temperature within the interior of the cart and help prevent any thermal loss and gain from the outside environment.

(29) Any of the walls, doors, top and bottom of the cart 20 may be made from composite construction to provide both thermal and structural integrity. In a specific embodiment, the composite construction is a sandwich panel construction incorporating foam and honeycomb phenolic panels and vacuum insulation panels.

(30) A thermoelectric chiller, shown schematically at reference numeral 24, based for example on the principles of the Peltier cycle, is mounted near the bottom of the cart 20, with the heat generated therefrom being extracted or exhausted through a separate service wall by way of a warm air exhaust and associated warm air ducting. The cooled air inside the cart 20 as a result of the electrical operation of the chiller is distributed inside the cart via cold air ducting 26 in the floor and doors. The cooled air is directed through the ducts 26 along the bottom of the cart, upward through the doors, and exits through openings 28 or jet holes of varying diameters. As shown, the openings 28 increase in diameter from the bottom to the top of the cart. The diameters can be customized to provide the same or different levels of cooling to each individual layer of meal trays. The ducts 26 may be integral within the inner walls or doors. The services for the chiller 24 are supplied via connections (see FIG. 13) to the service wall at the back of the cart bay or in another location. The chiller 24 is preferably mounted near the bottom or at the bottom of the cart 20 to maintain a low center of gravity, facilitate easy and rapid installation/removal, enable simple and effective connection to an exhaust air or extraction system, and isolate the hot and cold sides from each other's air flow. The flow of air is of re-circulatory nature, with FIG. 2 illustrating an air return grill 30. Forced and filtered hot air is ducted beneath the chiller 24 to the exhaust air or extraction system.

(31) In addition to the chilled cart 20 described above, the same technological principles of thermoelectric chilling can be used as a Point of Use (POU) system. Using the air through system of chilling a cart, the POU system is mounted on the galley or other structure outside of the cart where the air is distributed in a similar mode as the self-contained cart with the flow being optimized within internal air distribution ducting for this purpose.

(32) Referring to FIGS. 5-9, the galley cart 20 is configured to dock at a separate service wall 34 located at the galley or other location. Service connections between the galley cart 20 and service wall 34 can include, but are not limited to, one or more of electrical, data, water, air circulation, air extraction, and waste water services. Connectors may be provided on either end or both ends of the cart 20. Examples of service connectors mounted on the service wall 34 and the galley cart 20 are shown in FIG. 13. The service wall connectors 36 may include spigots 38 mounted on the wall. Receivers 54 on the cart may be coned to facilitate alignment of the cart 20 during latch engagement. The flexibility in the connections between the cart 20 and service wall 34 facilitates alignment and permits relative movement between the service wall and cart while engaged to prevent damage from floor deflection during turbulence, takeoff and landing. The cart latching mechanism, which is discussed below and further illustrated in FIGS. 15-18, may be mounted on an articulating wall mounting or interface to further facilitate relative movement between the cart 20 and the separate service wall 34.

(33) Referring to FIGS. 5-9, the air circulation system of the cart 20 engages with the air circulation system of the service wall 34 by way of spaced upper and lower connections 40, 42. The upper connection 40 includes a cold air feed 44 in the case of a POU chiller, and the lower connection 42 includes a warm air return 46 for extracting/exhausting warm air from the cart. When the cart 20 is engaged with the service wall 34, the cold air feed 44 and the warm air return 46 are in fluid communication with the respective cold air ductwork and warm air ductwork of the cart, thereby allowing hot air to flow from the cart, and chilled air to flow into the cart in the case of a POU chiller. With the cart 20 engaged, warm air from the cart is extracted through the warm air return 46 and warm air intakes 48 of the service wall 34 that align with the respective warm air exhaust and hot side of the cart. Warm air is directed through the service wall 34 and exhausted elsewhere through exhaust 50. Seals, such as sponge seals 52 or like seals, may be provided at the cold air feed 44 and warm air return 46 to help prevent air loss during air transfer. In the case of a POU chiller located at the service wall, cold air generated at the galley chiller is directed to the cart through the cold air feed 44.

(34) Referring to FIGS. 10-12, the galley cart 20 may include induction platens 56 for heating specific ferric portions of a meal tray within the cart. The cart 20 may be chilled, or not, and the induction system can be operated with or without a chiller or a POU system. Thus, the cart 20 can be configured to chill, heat or a combination of both.

(35) The interior of the galley cart 20 may be subdivided into a plurality of planes by the induction platens 56 that may be formed integrally with the housing or supported by the housing walls. Induction coils for generating the eddy currents are positioned along the length of the cart on one side or on alternative sides (see FIG. 12) in the form of the induction platens with local ferric, aluminum or other electrically-conductive heat receivers within the meal trays 58. The exposure of the receivers to the electromagnetic field enables localized heating within the trays, with the rest of the system remaining chilled or unaffected by the locally heated area(s).

(36) Services for the induction heating may be provided through the connection with the service wall 34. The generator may be fed by a power line from the service wall 34, or from a battery within the cart 20. The electrical connection to each individual platen 56 may be contained within the mounting wall(s) itself. The cart 20 can be either singularly loaded with the trays 58 or can be pre-loaded in a bulk carrier that is loaded into the cart, locating the receivers in the necessary operational position relative to the induction coils. Control of the EMI emissions generated by the operation of the inductive heating coils may be achieved by the use of a form of Faraday cage built into the wall structure of the cart itself.

(37) Cooking cycles may be pre-programmed or controlled by a temperature feedback loop or microchip temperature sensor. Through programming or other feedback loop, a switching mechanism (e.g., programmable distribution bus) can be situated between the power supply (e.g., power line or battery) and the individually wired induction coils to pulse between different induction coils to minimize power consumption, yet achieve local heating of the receivers and hence the food or beverage in the area of or overlying the receivers.

(38) Referring to FIG. 14, the wheel brake mechanism according to an embodiment of the invention remains in a braked configuration when no one is pushing or pulling on the cart (i.e., reverts to a safety mode when stationary). The brakes are released by actuating a handle at either end of the cart. Each handle operates independently of the other, allowing the brakes to be disengaged from either end of the cart without operating the other mechanism.

(39) Brake handles 60 are located at both ends of the cart for accessibility, ease of use and pushing/pulling the cart. The handles 60 are rotated downward when pressure is applied to push the cart forward or pull the cart. Cabling 62, which runs along the sides and bottom of the cart and which is guided through a plurality of pulleys, operably connects the handles to the brake mechanism. As a handle rotates downward, the cabling is pulled in the direction of the handle, thereby releasing the brakes from engagement with the wheels. Releasing the handle causes the handle to rotate upward, releasing the tension on the cabling and engaging the brakes. The cart may include a brake on one or more of the wheels, and each handle disengages every brake.

(40) Referring to FIGS. 15-19, the galley cart and service wall system may further be configured with a latching mechanism for retaining the docked carts between uses. The latching system includes latches 66 on the service wall that positively engage bars 68 that form part of the brake release handles 60 in the case of an upper latch, and an independent bar near the bottom of the cart in the case of a lower latch. Providing two spaced latches (i.e., a primary latch and a secondary latch) prevents kick up of the cart.

(41) Referring to FIGS. 17a-e, the latching mechanism automatically engages when the cart bars 68 are pushed into their respective latch, and is released remotely using mechanical activation. A back-up emergency release/engagement system can also be incorporated. When empty, a spring loaded pawl 70 of the latch is tiled downward at an oblique angle to vertical, presenting the pawl for receiving one of the bars 68 of the cart 20 (see FIGS. 16 and 17a). When the bar 68 contacts the pawl 70, the bar pushes downward on the pawl causing it to rotate (see FIG. 17b). Rotation of the pawl 70 a sufficient degree allows a spring loaded block 72 to rise vertically from beneath the pawl, thereby preventing the pawl from rotating back to the unlatched position (see FIG. 17c). To release the cart from the latch, the block 72 is pulled downward allowing the pawl to rotate back toward the unlatched position (see. FIG. 17d). The pawl is then able to rotate back to the unlatched position, allowing the captured bar 68 to be pulled away from the latch.

(42) The system provides an indication of latch engagement by way of visual confirmation. Referring to FIGS. 20 and 21, positive latch engagement may be indicated by visual markers and/or the position of the latch release handles themselves. An audible warning buzzer may also be incorporated into the mechanism. FIG. 20 shows two galley carts 20 latched to a service wall in a side-by-side arrangement. The latch release mechanism may include latch buttons located above the carts for indicating latched and unlatched states of the upper and lower latches. In a further embodiment, the buttons function to lower the spring loaded blocks of their respective latch, thereby allowing the pawl 70 to rotate to release its captured bar 68. Unlatching a galley cart from the service wall may require simultaneously depressing the release buttons and pulling the cart 20 horizontally away from the wall in one specific embodiment.

(43) The release buttons may include a green button 74 and a red button 76, wherein the green button is exposed and the red button concealed when the cart is latched (see FIG. 21a), and the red button exposed and the green button concealed (i.e., hiding) when the cart is un-latched (see FIG. 21c). FIG. 21b shows one of the upper and lower latches latched, and the other of the latches un-latched. In other words, the mechanism shown identifies whether a mechanical latch is engaged or not, by either showing the green button, or when the bar is released, showing external portions of the latch release handle that are colored red, indicating an incorrect location of the latch. The release mechanism may include an electric push button release for a solenoid actuated latch and a red/green voltage controlled LED display may be used.

(44) The cart door may have a double paddle latch with a three pin locking capability (top, bottom and side) for additional security. Referring to FIGS. 22a-22c, the cart door 32 may be hinged to the housing 22 through 270 degrees by way of double throw rotating block hinges embedded into the edge member forming the side wall of the cart. The door 32 pivots through 180 degrees with respect to a rotating block 80, which in turn pivots through 90 degrees with respect to the fixed side wall 82, thus providing about 270 degrees of pivoting movement of the door.

(45) Meals trays of various sizes and configurations suitable for use with the present invention that may or may not be coated in specific areas with electrically-conductive metals are shown in FIGS. 23-25. Examples of small, medium and large tray configurations are shown in FIGS. 23a, 23b and 23c, respectively. FIG. 24 shows an exemplary large meal tray with a plurality of separate depressions 90 for holding food and dividing ridges 92. FIG. 25 shows a meal tray with a center heated drink section 94 that may be coated with an electrically-conductive coating.

(46) One or more of the foregoing features may be incorporated into a galley cart system, thereby providing a set of components used to generate a family of derivatives that are interchangeable from the point of view of stowage in a galley, operational usage and overall appearance. Incorporating one or more of the above features, the galley cart may be fitted with a chiller, chilled compartment, induction oven, combined chiller/oven, trash compactor, bulk drink maker, dispenser, etc.

(47) The foregoing description provides embodiments of the invention by way of example only. It is envisioned that other embodiments may perform similar functions and/or achieve similar results. Any and all such equivalent embodiments and examples are within the scope of the present invention.