Patent Grant
9856058
Exemplary embodiments relate to mechanical latches that selectively hold items in engagement and release such items from engagement. Exemplary embodiments further relate to latches used to selectively hold and release lids or covers of waste containers.
Waste containers are mechanical devices that are typically used to hold discarded items. An example of a waste container includes a trash can or bin that is typically used to temporarily store garbage or other waste items. Waste containers often have lids that help hold and isolate the contents of the waste container. For example, lids can prevent the contents of waste containers from being exposed to wind, rain and snow. Lids can contain undesirable odors of the contents. Lids can also prevent the contents of waste containers from being accessed by domestic and wild animals scavenging for food.
To avoid a lid from being opened at inappropriate times, the lid and/or the bin of the waste container to which the lid is attached may include a latch mechanism. Such latch mechanisms for waste containers may benefit from improvements.
The following is a brief summary of subject matter that is described in greater detail herein. This summary is not intended to be limiting as to the scope of the claims.
In one example embodiment described herein, a latch mechanism may be configured to be mounted to a waste container that includes a bin and a lid. Such a bin of the waste container includes walls that bound an interior space and an opening into the interior space, which is coverable by the lid. Such a lid may be attached to the bin via a hinge or other pivoting connection such that the lid is operative to pivot with respect to the bin between an open position and a closed position relative to the opening into the interior space.
When the lid is in the closed position, the lid includes an inside surface facing the interior space and the lid includes an opposed outside surface. In the examples described herein, the latch mechanism may be in operative connection with either the bin or the lid. For example, in an exemplary embodiment, the latch mechanism is in operative connection with the inside wall surface of the bin of the waste container and a release mechanism is in operative connection with the lid of the waste container.
The latch mechanism may automatically engage with the release mechanism in order to lock the lid in the closed position relative to the bin. However, it should be appreciated that in alternative embodiments the latch mechanism and release mechanism may be located in different locations. For example, the latch mechanism could be mounted in operative attached connection to the lid of the container and be operative to engage a release mechanism in operative attached connection with the bin. Also, in alternative embodiments, multiple outside and/or inside release mechanisms may be mounted to the waste container such as on the lid and/or on an upper ledge of the bin.
In an example embodiment, the release mechanism mounted to the lid is operative to enable a human to manually disengage the lid and the latch mechanism so that the lid may pivot to its open position. However, it should also be appreciated that in some applications, the waste container may also need to be configured to enable the lid to automatically open without direct manual intervention.
For example, waste disposal providers may employ a lifting mechanism to lift and rotate a waste container over a trash receptacle of a garbage truck. To avoid the lid from remaining closed and preventing the contents of the bin from falling out into the garage truck, the latch mechanism may be configured to automatically disengage from the release mechanism and permit the lid to rotate to an open position. In such an embodiment, the latch mechanism may be configured such that in certain predetermined dump angular orientations of the latch mechanism, gravity is operative to actuate portions of the latch mechanism to cause the latch mechanism to disengage from the release mechanism.
In general, both the hand operated exemplary release mechanism accessible from the outside of the lid (and optionally accessible from inside the waste container) and the automatic release features of the latch mechanism, are capable of maintaining a lid in a closed position when the waste container is in an upright position and a human is not engaging the release mechanism. However, some animals (such as raccoons) working individually or in groups may be capable of discovering methods of opening a lid of a waste container in order to access discarded food therein. Thus, example embodiments of the latch mechanism and release mechanism described herein may be configured to require specific actions to operate that are not capable of being discovered and/or carried out by most raccoons.
For example, raccoons working together may be capable of pushing a waste container on its side, which causes the waste container and latch mechanism to rotate 90 degrees. Thus, to prevent the lid from opening in this possible situation, an example embodiment of a latch mechanism may be operative to prevent the lid from opening unless the waste container and latch mechanism have rotated to a dump angular orientation, such as a range of predetermined angles (such as by more than 90 degrees). In this example embodiment, a dumping mechanism of a garbage truck or other device may lift and rotate the waste container by 120 degrees or more, and thus the described latch mechanism would still be operative to automatically disengage the lid for this use. However, on flat ground, a raccoon is much less likely to be able to rotate a waste container more than 90 degrees by tipping it over. Thus, the lid would remain shut when tipped over by a raccoon or other animal.
It should also be appreciated that aggressively tipping over a waste receptacle at only 90 degrees could impart a sufficient amount of kinetic energy, jarring, momentum, and/or centrifugal forces to internal parts of the latch mechanism to mimic the effect that gravity would have on the internal parts of a latch mechanism if a waste container were rotated by more than 90 degrees. Thus, to prevent the lid from opening in this possible situation, an example embodiment of a latch mechanism is operative to slow and/or mechanically prevent the automatic actuation of the release mechanism so as to provide time for the initial jarring effects of the fallen waste container to dissipate. Thus, only the angular orientation of the waste container and latch mechanism to the predetermined range of the dump angular orientation (e.g., more than 90 degrees) may cause the latch mechanism to disengage the lid from the waste container to enable it to open, and not the jarring forces caused by knocking a waste container on its side.
An example latch mechanism that is operative in this described manner may include a latch housing, an engagement portion, and a release weight. An example release mechanism for use with this described latch mechanism may include a release receptacle.
In this example, the latch mechanism may be mounted in fixed operative engagement to an inside wall of a waste container and the release mechanism may be mounted in fixed operative engagement to a wall of a lid of the waste container. In order to latch the lid to the waste container, the release receptacle is operative to engage with the engagement portion of the latch (when the lid is closed).
In this example, when the waste container it rotated from the upright condition by more than 90 degrees in at least one direction, the release weight may be operative to move responsive to gravity and the change in orientation to cause the engagement portion to disengage from the release receptacle, and thereby automatically enable the lid to rotate responsive to gravity to an open position relative to the waste container. Also, operative movement of the release knob relative to the release base causes the release receptacle to disengage from the engaging portion of the latch mechanism, to enable a human to manually unlatch the lid from the closed position closing the opening of the waste container.
Also, in this example, when the waste container is rotated back to an upright position (e.g., a zero degrees of rotation orientation), the release weight may be operative to move responsive to gravity to cause the engagement portion of the latch mechanism to change to a configuration that is operative to hold in latched engagement the release receptacle of the release mechanism (when the lid is placed in a closed position relative to the waste container).
An example latch mechanism that is operative to provide these features may include a release weight that is operative to move responsive to gravity in the latch housing from a first position, in which the weight is not in contact with the engagement portion, to a second position in which the weight is in contact with an engagement portion. The engagement of the weight and the engagement portion is operative to cause the engagement portion to change from a first configuration in which the engagement portion is enabled to hold the release mechanism in latched engagement, to a second configuration in which the engagement portion is enabled to disengage from the release mechanism. Also, the exemplary release weight may be operative to move responsive to gravity in the latch housing from the second position to the first position to cause the engagement portion to change from the second configuration to the first configuration.
In this exemplary embodiment, the rotary damper is configured to control and slow movement of the release weight in the latch housing from at least the first position to the second position. For example, the damper may be operative to slow movement of the release weight in the housing such that an amount of time for the release weight to move responsive to gravity from the first position to the second position is at least twice an amount of time the release weight would move responsive to gravity from the first position to the second position in the housing absent the effect of the damper on the release weight.
In this described embodiment, the engagement portion may include a release pin. The release pin includes an outer annular wall and an axial cavity therein. Also, the release pin has movable projection members (such as balls, spheres, vanes, fingers, etc.) that are operative to move between retracted positions and extended positions radially with respect to the outer wall of the release pin. In addition, the engagement portion may include a release pin button, wherein a portion of the release pin button extends in the cavity in the release pin. When the release weight moves from the first position to the second position of the release weight, the release weight is operative to engage and move the release pin button axially from a first button position to a second button position in the cavity in the release pin. In the second position of the release pin button, the projection members are enabled to move from the extended positions to the retracted positions.
In this example, the engagement portion may also include a spring in operative connection with the release pin button. When the release weight moves from the second position to the first position of the release weight, the spring is operative to automatically urge the release pin button to move from the second button position toward the first button position, which movement causes the release pin button to urge the projection members to move to the extended positions.
In example embodiments, the release mechanism further includes a release base and a release knob. Movement of the release knob relative to the release base from an extended position to a retracted position and then from a first angular orientation to a second angular orientation relative to the release base, enables the release receptacle of the release mechanism to disengage from the engagement portion of the latch mechanism.
In example embodiments, the described release receptacle comprises a release pin receptacle that is in operative connection with the release base. The release pin receptacle includes a rotatable portion that is operative to rotate between a first angular orientation and a second angular orientation. In the first angular orientation of the rotatable portion, the rotatable portion is operative to lockingly engage with the release pin when the projection members are in the extended positions and the knob is in the extended position.
Also in this example embodiment, movement of the release knob relative to the release base from the extended position to the retracted position of the knob and then from a first angular orientation to a second angular orientation of the knob relative to the release base, causes the rotatable portion to rotate to the second angular orientation of the rotatable portion, which orientation enables the release pin and release mechanism to disengage from each other while the projection member remains in the extended position.
The exemplary rotatable portion includes an aperture and inner ridges. The aperture is operative to receive the release pin therein. As the release pin moves inwardly in the aperture (to engage and hold the latch mechanism and release mechanism in engaged relation), the projection members in the extended position are operative to contact the inner ridges and cause the rotatable portion to rotate from the first angular orientation towards the second angular orientation. The rotatable portion is also configured such that when the release pin extends sufficiently far into the aperture to position the projection members inwardly past the ridges, the rotatable portion is operative to automatically rotate back to the first angular orientation. In addition, when the rotatable portion is in the first angular orientation and the release knob is in the extended position of the release knob, the inner ridges are operative to block the projection members in the extended positions of the projection members, from moving out of the aperture in the rotatable portion.
In this example embodiment, when the rotatable portion is moved to the second angular position by the knob, the inner ridges move to positions that enable the projection members in the extended positions to move outwardly past the inner ridges and enable the release pin and release pin receptacle to separate from each other. Also, in example embodiments, the rotatable portion is operative to rotate from the first angular position to the second angular position of the rotatable portion without causing the knob to rotate from the first angular position to the second angular position of the knob. In addition, when the release knob is in the extended position relative to the release base, the release knob is not operative to be rotated in a manner that causes the rotatable portion to rotate.
In example embodiments, the release mechanism further includes a torsion spring, an extension spring, and a compression spring. The torsion spring is configured to urge the rotatable portion to rotate from the second angular position to the first angular position of the rotatable portion. The extension spring is configured to urge the knob to rotate from the second angular position to the first angular position. Also, the compression spring is configured to urge the knob to move from the retracted position to the extended position.
Also, in example embodiments, each of two opposed walls of the release pin receptacle include guide channels. In addition, the latch housing includes guide flanges spaced apart from the release pin on opposed sides of the release pin. The guide channels are operative to receive the guide flanges of the latch housing when the latch mechanism engages with the release mechanism so as to enable self-alignment of the release mechanism with the latch mechanism which may initially be off center with respect to each other.
In example embodiments, the release weight may include a channel. Also, the previously described damper may include a rotatable shaft and a lever that extends from the rotatable shaft into the channel of the release weight. The channel has a shape that causes the lever to pivot and rotate the rotatable shaft from a first angular orientation to a second angular orientation when the release weight moves from the first position to the second position. Likewise, the configuration of the channel causes the lever to pivot and rotate the rotatable shaft from the second angular orientation to the first angular orientation when the release weight moves from the second position to the first position. The rotation of the rotatable shaft from the first angular position to the second angular position causes the damper to exert a first force on the release weight that slows movement of the release weight when moving from the first position to the second position.
Rotation of the rotatable shaft from the second angular position to the first angular position causes the damper to exert a second force on the release weight that slows movement of the release weight from the second position to the first position. In an example embodiment, the first force may be several times greater than the second force.
In example embodiments, the latch housing may include a housing ridge adjacent the release weight. Also, the latch mechanism may include a weight stopper in pivoting connection with a cavity in the release weight. In a first set of angular orientations of the latch mechanism (such as when the release weight is upright or angled on its back hinged side at −90 degrees of rotation from an upright position), the exemplary weight stopper is operative responsive to gravity to rotate so as to extend adjacent to the housing ridge and prevent gravity from causing the release weight from moving from the first position to the second position. Also, in a second set of angular orientations of the latch mechanism (such as a dump angular orientation greater than +120 degrees from an upright position), the weight stopper is operative to rotate away from the housing ridge and enable the release weight to slide from the first position to the second position responsive to gravity and the change in orientation.
In an alternative example embodiment, the described release mechanism may further comprise an inside release mechanism having a pull handle. The pull handle may include a flexible linkage that extends into operative connection with the rotatable portion. Pulling of the handle outwardly (by a human) from the latch mechanism causes the flexible linkage to cause the rotatable portion to rotate from the first angular position to the second angular position of the rotatable portion (which disengages the release mechanism and the latch mechanism from latched engagement). In addition in this described alternative embodiment, the release mechanism includes a handle holder that is operative to hold the handle in a position such that the flexible linkage does not urge the rotatable portion to rotate from the first angular position to the second angular position.
Other aspects of exemplary embodiments will be appreciated upon reading and understanding the attached figures and description.
Various technologies pertaining to latch and release mechanisms for waste containers will now be described with reference to the drawings, where like reference numerals represent like elements throughout. In addition, the example systems are illustrated and described herein for purposes of explanation; however, it is to be understood that functionality that is described as being carried out by certain system components may be performed by multiple components. Similarly, for instance, a component may be configured to perform functionality that is described as being carried out by multiple components.
In an example embodiment, the lid and bin of the waste container may be made of a plastic material such as a high density polyethylene (or other plastic such as a polypropylene) via a manufacturing process such as blow molding, injection molding, or other molding process. However, it should be appreciated that in alternative embodiments, the lid and bin of the waste container may be made out of other materials such as metal (e.g., aluminum or steel).
In this example, the waste container 104 includes features that enable the waste container to be lifted, rotated and unloaded via a lifting mechanism of a dump truck or other dumping device. Such features, for example, may include a metal horizontal retention bar 210 that extends in a recess bounded by exterior walls of the bin. Such a waste container 104 may also include wheels 212 and a handle 214. In the U.S., such waste containers may be compatible with a standard such as ANSI Z245.60—2008 which is incorporated herein by reference in its entirety. Also, such waste containers may have different interior capacities such as 26 gallon, 32 gallon, 64 gallon, or 96 gallon sizes, or other waste container sizes. Thus, it should be appreciated that embodiments of the latch and release mechanisms described herein may be adapted for use with any type and/or configuration of a waste container that includes a lid.
Referring again to
The exemplary outside release mechanism includes a movable element such as a knob 126. Such a knob may include a handle 116. The knob is in operative connection with a base 128. The exemplary base has an outer shape that is compatible with the surface configuration of the lid 106. For example, as shown in
However, it should be appreciated that in alternative embodiments, the base may be configured to orientate the knob at other angular orientations and may be adapted to mount to lids or sides of waste containers with other slopes and surface designs. Also, in alternative embodiments of the outer release mechanism, rather than having a knob shape, the movable element may have the shape of a paddle, lever, button, handle, or any other configuration that is capable of being manipulated by a user to actuate the release mechanism. Further, exemplary embodiments may include knobs or other manually movable members that are required to be moved in two different directions in order to enable the latch to be unlatched. Such directions may include linear directions, rotational directions or combinations thereof. Examples of different knobs, and other components that may be adapted for use with the embodiments described herein and or that may be adapted to use the features described herein are shown in U.S. Patent Applications Nos.: 61/984,464 filed Apr. 25, 2014; 61/984,428 filed Apr. 25, 2014; Ser. No. 29/489,045 filed Apr. 25, 2014; Ser. No. 29/489,172 filed Apr. 28, 2014; and Ser. No. 29/509,434 filed Nov. 18, 2014, which are hereby incorporated herein by reference in their entirety.
As shown in
In order to mount these described elements to the waste container, the latch mechanism and outside release mechanism may include threaded bores and/or apertures. Such bores or apertures may accommodate the use of fasteners 140 such as of bolts, screws, nuts (or any other type of fasteners or other items that are operative to hold these elements to the waste container).
With reference to
When the latch 120 is rotated from the neutral orientation shown in
In this described example, the damper 508 includes a rotatable shaft 516 and a lever 518 that extends from the rotatable shaft into the channel 506 of the release weight 504. The exemplary channel has a shape that causes the lever 518 to pivot and rotate the rotatable shaft 516 from a first angular orientation (shown in
In this example, the rotation of the rotatable shaft 516 from the first angular position to the second angular position causes the damper to exert a first force on the release weight 504 (opposite to the direction of movement of the release weight) that controls and slows movement of the release weight from the first position to the second position.
It should also be noted that the rotation of the rotatable shaft 516 from the second angular position (shown in
In the exemplary embodiment, the pin 518 includes a rounded end disposed away from the damper. The rounded end is configured so as to enable the lever to move in readily sliding engagement with the walls bounding the channel 506. In some exemplary arrangements, the curved end of the lever 518 and the channel walls may be polished or otherwise configured or treated with a material that facilitates relative movement of the channel walls and the end of the lever. In other arrangements, the end of the lever may include a rotatable member such as a roller, which may further facilitate the ability of the weight to move without being limited by frictional engagement between the lever and the walls bounding the channel 506.
It should be further noted that in the exemplary embodiment, the wall bounding the channel on the side that is disposed the furthest away from the engagement portion 514 is angularly configured to be sloped in a direction away from the engagement portion and outwardly to the lateral side of the weight on which the damper is located. This configuration in the exemplary embodiment is configured to cause the force of the damper, which resists movement of the weight and which acts through the rounded end of the lever, to act generally along the line of movement of the weight between the first and second weight positions. The configuration of the wall bounding the channel surface in this way enables the exemplary embodiment to assure that the force applied by the damper and acting to resist movement of the weight, acts almost entirely in the direction of the weight movement and does not have significant angular components to the force which might cause the weight to twist or otherwise become stuck so as to limit its movement. As can be appreciated, if the force applied by the damper were to act in a manner that would twist or otherwise cause the weight to move in a direction other than along the linear direction within the housing, this might result in a greater tendency of the weight to become twisted and stuck.
Further in the exemplary embodiment, the angle of the wall bounding the channel in the direction that is disposed away from the engagement portion 514, has a very low slope angle that extends from the center of the channel outward to the periphery of the weight. This low angle of slope also conforms with the configuration of the side of the lever 518. Thus for example, as can be seen in
Further in the exemplary arrangement as represented in
Further it should be understood that while one rotary damper is utilized in connection with the exemplary embodiment, in other embodiments other configurations and types of dampers may be used. This may include for example rotary dampers positioned on both lateral sides of the weight so as to control the movement thereof between the first and second positions. Such rotary dampers may include lever arms that engage the same side, or alternatively, opposed lateral sides of the weight. Further in still other embodiments, other types of damper mechanisms that control or limit the speed of movement of the weight may be utilized. Such dampers may include torsional dampers that utilize springs, gears, etc. Alternatively, fluid dampers such as hydraulic or pneumatic dampers for other suitable devices may be utilized in other embodiments.
In an example embodiment, the damper is operative to dampen and control movement of the release weight in the housing such that an amount of time for the release weight to move responsive to gravity from the first position 510 to the second position 612 is at least twice an amount of time the release weight would move responsive to gravity from the first position to the second position in the housing absent the effect of the damper on the release weight.
In this described embodiment, the engagement portion 514 includes a release pin 520. The exemplary release pin includes an outer wall 522 and an axial cavity 524 therein. In addition, the release pin is in movable connection with projection members 526 (e.g., in the exemplary embodiment a plurality of small balls or spheres). The exemplary projection members are operative to move between radially extended positions (as shown in
As can be appreciated in the exemplary embodiment, the projection members 526 are configured to move radially within the apertures of the release pin, and in the exemplary configuration the apertures are configured to enable the projection members to move, but not pass entirely therethrough. Further it should be understood that while in the exemplary arrangement balls or spheres are used as projection members, in other arrangements other types of movable members such as tabs, fins, vanes or other elements that capable of being selectively extended and retracted may be used as projecting members.
Example embodiments of the engagement portion 514 include a release pin button 528. At least a portion of the release pin button 528 extends axially in the cavity 524 in the release pin. When the release weight moves from the first position 510 (shown in
However, when the release weight moves from the second position 612 (shown in
In this example, the release receptacle 122 corresponds to a release pin receptacle that is operative to receive and engagingly hold the release pin 520. The release pin receptacle 122 includes a rotatable portion 530 having an aperture 534. The release pin may slide into and out of engagement with the aperture 534. The rotation portion includes radially inward extending inner ridges 532 inside the aperture 534. When the projection members 526 of the release pin are in the extended position, the inner ridges 532 are operative to engage the projection members to prevent the release pin 520 from sliding out of the aperture 534 of the release pin receptacle 522.
To assist further understanding of these described features,
As shown in
As discussed previously, this enables latched holding engagement of the release pin and with the release pin receptacle 122 when the release pin 520 is inserted sufficiently far into the aperture 534 of the rotatable portion 530 to place the projection members 526 adjacent the ends of the inner ridges 532 along the walls of the aperture 534. In this position, the top sides of the inner ridges 532 are operative to block the projection members extending radially outward from the release pin 520 from disengaging sliding out of the aperture 534 of the release pin receptacle 122.
However, as illustrated in
With this described design, the latch permits the lid of the waste container to become automatically unlatched and opened when a lifting mechanism of a garbage truck (or other device) lifts and rotates the waste container to a dump angular orientation which in the exemplary configuration is an angle greater than the sideways angular orientation shown in
It should be appreciated that when a lid of a waste container is moved to a closed position, the engagement portion 514 of the latch will become engaged with the release pin receptacle 122. The release pin 520 will move into the aperture 534 of the rotatable portion 530 of the release pin receptacle 122 and the projection members will engage the inner ridges 532 to hold the latch and the receptacle in engagement.
When closing the lid of the waste container, in order to enable the projection members to pass the described inner ridge members when engaging the latch mechanism with the release mechanism, the described rotatable portion 530 of the release pin receptacle 122 is operative to rotate responsive to urging forces applied by the inwardly moving projection members themselves. In this example, the inner ridges 532 have a tapered angled helix configuration facing toward the opening of the aperture 534. For example,
As the projection members slide inwardly in engagement with the tapered and angled surfaces of the inner ridges 532, the radially extending projection members 526 function as cam surfaces that provide rotation force to turn the rotatable portion 530 a sufficient distance for the projection members to reach relatively wider channels 706 in the aperture 534. Such wider channels 706 in the aperture 534 provide sufficient space for the projection members to slide past the adjacent inner ridges.
In addition, as shown in
As discussed previously with respect to
Referring now to
Also, as shown in
Referring now to
As shown in
To illustrate this configuration more clearly,
In addition, it should be appreciated that when the user lets go of the knob 126 after the knob being rotated to the position shown in
Also, when the knob has returned to the position shown in
As illustrated in
As discussed previously, animals such as raccoons are exceptionally clever at figuring out ways to open waste containers and may be capable of knocking a waste container on its back side. In such circumstances, in order to further minimize the opportunity for the described release weight of the latch mechanism from sliding a sufficient distance to cause the latch to be disengaged from the release mechanism, an example embodiment may include an internal weight stopper that limits sliding of the release weight at only certain angular orientations of the latch mechanism.
As shown in
However, when the waste container 104 is orientated in the dump angular orientation, such as +120 degrees from an upright position, and with the hinge for the lid relatively above the latch (as shown in
With reference to
For example,
To illustrate the exemplary inside release mechanism more clearly,
To further illustrate the connection of the flexible linkage 2308,
Also, with respect to
In addition, it should be noted with respect to
Further, it should be understood while the exemplary configuration of the release handle is a T-shaped handle, other embodiments may include other types of handle configurations. Such handle configurations may include for example a cylindrical handle configuration or a round handle configuration that is suitable for being displaced and pulled in order to enable the latch change from a latched condition to an unlatched condition. Further, in other exemplary arrangements the handle may include a configuration that is in connection with a spring or other biasing mechanism that biases a flexible member or other member to rotate the receptacle to an unlatched position. Thus, in exemplary arrangements the act of moving or breaking an item which acts against the biasing force automatically changes the latch to an unlatched condition. In some exemplary configurations, such an approach of merely displacing a component from its normal position rather than having to displace and pull the component may make it easier to change the condition of the latch. Of course it should be understood that these approaches are exemplary and in other embodiments other approaches may be used.
In example embodiments, the described components of the latch mechanism, release mechanism, and striker/release button mechanism may be comprised of plastics (e.g., Polycarbonate, ABS, PVC), metals (stainless steel, aluminum, tin), and/or any other materials that are operative to form the shapes and be capable of carrying out the functions described herein. Further, these described elements may be mounted together with fasteners such as screws, bolts, adhesives, or any other fastening or bonding system applicable to the type of materials being assembled. In addition, it should be appreciated that the housings may include gaskets, o-rings, and/or other elements to increase the weather/water resistance of the described mechanisms.
It is noted that several examples have been provided for purposes of explanation. These examples are not to be construed as limiting the hereto-appended claims. Additionally, it may be recognized that the examples provided herein may be changed or permutated while still falling under the scope of the claims.
Further, it should be appreciated that while the exemplary embodiments described herein relate to waste containers and particular configurations of the exemplary waste containers, the structures and principles of the exemplary embodiments may be applied to other configurations of waste containers or other types of containment devices, closure structures or latching arrangements in other fields of use.
Thus the exemplary embodiments described herein achieve improved operation, eliminate difficulties encountered in the use of prior devices, systems and methods and attain the useful results described herein.
In the foregoing description certain terms have been used for brevity, clarity and understanding. However, no unnecessary limitations are to be implied therefrom because such terms are used for descriptive purposes and are intended to be broadly construed. Moreover, the descriptions and illustrations herein are by way of examples and the inventive aspects are not limited to the features shown and described.
Having described the features, discoveries and principles of the exemplary embodiments, the manner in which they are constructed and operated and the advantages and useful results attained, the new and useful structures, devices, elements, arrangements, parts, combinations, systems, equipment, operations, methods, processes and relationships are set forth in the appended claims.
This application claims benefit pursuant to 35 U.S.C. §119(e) of Provisional Application Nos. 61/984,428 filed Apr. 25, 2014, 61/984,464 filed Apr. 25, 2014 and 62/081,365 filed Nov. 18, 2014, the disclosures of each of which are incorporated herein by reference in its entirety.
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| Number | Date | Country | |
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