This application claims the benefit of U.S. Provisional Application Ser. No. 61/343,262, filed Apr. 26, 2010 titled “InFlight Trash Compactor Main Door Interlock,” the entire contents of which are hereby incorporated by reference.
Embodiments of the present invention relate generally to door locking systems for use in connection with trash compactor systems for preventing inadvertent opening of the main door during a compaction cycle.
Collecting and disposing of trash in confined conditions, particularly on-board passenger transport vehicles, such as aircraft, trains, ships, buses, RVs, and other water or air travel vessels can be challenging. However, a good deal of rubbish is generated on such vehicles. For example, after in-flight beverage service, unused items are collected, which often includes drink cups, napkins, newspapers, food wrappers, tea bags, beverage cans, other packaging or non-consumable items and the like, food wastes, or any other type of disposable item that a passenger may consume or bring on-board.
Trash compactors are thus often used in aircraft and other vehicle galleys in order to manage the amounts of trash generated. If the main door of the trash compactor is opened during a compaction cycle, there are built-in safety sensors on the main door that deactivate the downward movement of the platen (the plunger-like plate that raises and lowers in order to compress the trash in the compactor unit) to prevent harm to the user. Although this deactivation addresses a definite safety need, it fails to address the nuisance that occurs when the main door is opened before the trash container in the unit is full.
Because compaction applies a substantial load on the contents of the trash container in the compactor unit, the sides of the container exert a continuous force against the main door and walls of the compactor unit. This force causes the container to expand, press, or bulge outwardly against the door and walls—this is normally not of concern because the container is supported and contained by all sides of the compactor unit. However, if the main door is prematurely opened during the compaction cycle when the platen is applying pressure or force to the container contents, it causes the container to bulge out the front door opening. The container can also bulge out if the main door is opened at any time between one of the compaction cycles, but before the container is entirely full and ready to be removed from the unit. Once the container bulges out, it is difficult (if not impossible) to re-close the front door in order for the compression/compaction cycle to continue. Consequently, no more trash can be loaded, and no more compaction cycles can take place. The partially full box must be removed and replaced with an empty box. If the platen gets jammed where it can't be retracted, the attendant usually has to rip the trash container apart, empty its contents on the floor, position a new container in the compactor unit, re-load the trash into the new container, and being the compaction cycle again. This is a messy and time-consuming process.
Accordingly, it is desirable to provide a mechanism that prevents the main door of a trash compactor from being opened any time that a compaction cycle is taking place.
Embodiments of the present invention relate generally to door locking systems for use in connection with trash compactor systems for preventing inadvertent opening of the main door during a compaction cycle. They provide a trash compactor main door interlock, comprising an actuator configured to indicate that a compaction cycle has begun; and a lock system configured to be activated by the actuator and to restrain the main door from opening. The actuator may be mechanically or hydraulically activated.
In a specific embodiment, the lock system comprises a vertical rod, a hinge member, and a horizontal rod. The actuator causes the vertical rod to press against the hinge member, pressure on the hinge member causes the horizontal rod to extend toward a handle of the main door, and extension of the horizontal rod causes the rod to restrain a handle of the main door.
Embodiments described provide a main door interlock that prevents the front main door handle of the trash compactor unit from being pulled open when the platen is in motion, thus preventing the door from opening. The main door interlock may be mechanically, electrically, or hydraulically activated. In either instance, the main door mechanisms are similar. Alternate embodiments provide a main door interlock that can prevent the handle from being opened at any time before the final compaction has taken place. This may be accomplished by an electrical circuit, a solenoid system that be insert and extract a pin from the door handle, or any other appropriate means.
In a first mechanical embodiment, the mechanical design allows the movement of the trash compacting platen to activate the interlock. This way, any time a compaction cycle occurs, the main door cannot be opened. In a second hydraulic embodiment, the hydraulic pressure used to push the cylinders behind the platen is secondarily used to activate the interlock. Activation of the interlock will thus lock the main door any time a compaction cycle takes place. Although not shown, it is understood that any other mechanisms may be used to ensure that the main door remains closed for the desired duration, either when the platen is in motion or until the final compaction cycle has occurred.
In the embodiment shown in
An actuator 16 or 18 is provided that is configured to indicate that a compaction cycle has begun. For example, the actuator 16 may be a mechanical actuator that physically actuates or moves or otherwise alerts the door locking system that the platen has begun movement. In one embodiment, actuator 16 may have a portion that provides an internal feature or hinge that cooperates with a portion of the platen, such that when the platen physically moves against or pushes the feature or hinge, it indicates that the compaction cycle is in progress. When the actuator 16 is not being pushed or moved by the platen, the remaining portions of the main door interlock (described below) maintain a default open position and the main door remains in its unlocked position.
One specific mechanical actuator 16 is shown in
As shown in schematic
As shown in schematic
A specific embodiment of one mechanical actuator 16 is shown in
Although one specific actuator system 16 is described, it should be understood that other mechanical means for accomplishing the actuator function may be used and are considered within the scope of the invention. The general concept is that movement of the platen 50 causes an actuator system 16 to activate a lock for the main door (and optionally, activate a lock for the trash door), and other mechanical interfaces may be used.
Alternatively, the actuator may be a hydraulic actuator 18, as shown in
In either embodiment, the actuator 16 or 18 indicates to the system that a compaction cycle is in progress by detecting movement of the platen. It should be understood that there may be other ways to indicate to the system that the compaction cycle is in progress, such as an electrical switch, a solenoid, or any other appropriate indicator or notifier system.
Once the actuator is pushed down or otherwise activated, the main door interlock system 20 locks the main door 12. In a specific embodiment, system 20 is configured to restrict movement (e.g., opening) of the main door handle 14. Although one specific interlock system 20 is described with relating portions below, it should be understood that other mechanical means for accomplishing the locking function may be used and are considered within the scope of the invention.
In a specific embodiment, the locking system 20 may include a vertical rod 26, a hinge member 28, and a horizontal rod 30, all of which are associated with one another or otherwise mechanically engaged. Once actuator 16 or 18 is activated by the beginning of a compression cycle, it applies pressure to the vertical rod 26. This pressure may either be applied by an end of the actuator 16 or by the plunger 22, 58. The pressure from the actuator causes the vertical rod 26 to move down (in the embodiment shown, but it should be understood that the actuator 16 or 18 may be below the vertical rod and thus cause the rod to move up) and press against the hinge member 28.
In a specific embodiment, hinge member 28 comprises two hinge legs 32, 34 connected at a point 36. Point 36 changes the vertical force “V” from the vertical rod 26 into a horizontal force “H.” Pressure on hinge member 28 thus causes the horizontal rod 30 to extend toward the handle 14 of the main door 12. Horizontal rod 30 may have a first securing feature 38 and handle 14 may have a corresponding second securing feature 40. In a particular embodiment, the first securing feature 38 on the rod 30 is a pin or other protrusion that extends from the end of rod 30, and the corresponding second securing feature 40 on the handle 14 is an opening or indentation. It should be understood that either of pin or opening may be positioned on either of the rod 30 or the handle 14. It should further be understood that alternate securing features may be used, as long as cooperation therebetween restricts movement of the handle or the door. Features 38 and 40 are dimensioned and configured such that when they are engaged, the handle 14 cannot be pulled and the main door 12 cannot be opened. In the embodiment shown, extension of the horizontal rod 30 causes the rod 30 to restrain the handle 14 of the main door.
Thus, for the mechanical version of the embodiments shown and described, there may be two hinged interfaces. A first hinged interface provides the actuator 16 (which indicates that the compaction process has begun and activates the interlock system) and a second hinged interface 28 provides the main door interlock (which secures the main door handle from being opened). The spacing and positioning of these hinges is intended to maximize space considerations on the trash compactor unit 10, while providing the functional advantages described.
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.
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Entry |
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Number | Date | Country | |
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20110259215 A1 | Oct 2011 | US |
Number | Date | Country | |
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61343262 | Apr 2010 | US |