1. Field of the Disclosure
The present disclosure is generally directed to safety gates and, more particularly, to a safety gate with a clamp adjustment mechanism for extending the length or width of the safety gate and securely installing the safety gate in an opening.
2. Description of Related Art
Safety gates for preventing children and pets from accessing specific areas in a home or dwelling, such as a stairwell or a particular doorway, are well known in the art. Conventional safety gates, such as the one disclosed in expired U.S. Pat. No. 4,492,263, generally have overlapping panels and tubes that are widthwise slidably adjustable to extend the width of a particular opening. The tubes or panels have end caps or feet that engage the surfaces of the opening or doorway when the gate is installed. The end caps or feet are typically installed under compression between the surfaces of the doorway or opening to secure the safety gate in place.
Conventional safety gates tend to be rather bulky and have a rudimentary adjustment system with relatively large adjustment increments. As a result, safety gates can be difficult to transport and/or store and can be time consuming and frustrating to set-up. Such safety gates can also be difficult to adjust to precisely fit a given opening. Often, the gate can be adjusted incrementally to fit different opening sizes. However, the adjustment sizes can be limited by the relatively large gap between available size increments. The actual opening size to be barricaded often falls between two adjustment increments. Thus, the gate may be under too much, which may damage the surfaces of the opening, or under too little compression and thus not fully secured in place when installed.
Clamp mechanisms are also well known in the art. Conventional clamp mechanisms, such as the one disclosed in expired U.S. Pat. No. 5,009,134, generally include a fixed jaw and a movable jaw. When the clamp mechanism is actuated, the movable jaw moves towards the fixed jaw to clamp an item between the jaws. A squeezing action on a grip, handle, or actuator is typically employed to allow for small incremental adjustment of the clamp jaw spacing relative to one another.
In one example according to the teachings of the present invention, a safety gate has a frame with top and bottom assemblies spaced apart in a vertical direction and with opposed side assemblies spaced apart in a horizontal direction in a deployed configuration. A length of the top and bottom assemblies is extendable and retractable to adjust a width of the frame between the opposed side assemblies. A flexible barrier is connected to and supported by the frame. A one-way jack mechanism is carried on each of the top and bottom assemblies. The length of the top and bottom assemblies can be extended without actuating the jack mechanisms to adjust the frame to a desired width to loosely fit a space between two surfaces. The one-way jack mechanisms, when actuated, incrementally further extend the length of the top and bottom assemblies such that the frame interferingly fits between the two surfaces under compression.
In one example, each one-way jack mechanism can have a lever to actuate the respective one-way jack mechanism.
In one example, actuation of a lever on each of the one-way jack mechanisms can further extend the top and bottom assemblies in a direction of extension and neither actuation nor return of the levers can retracts the top and bottom assemblies in an opposite direction of retraction.
In one example, each one-way jack mechanism can have a lever that is generally parallel with the respective top or bottom assembly in a home or unactuated position.
In one example, the barrier can cover a substantial portion of an opening in the frame within the top, bottom, and opposed side assemblies.
In one example, the barrier can be coupled to the top and bottom assemblies and/or to the opposed side assemblies and can be extendable and retractable as the width of the frame is adjusted.
In one example, each jack mechanism can have a squeezable lever that, when squeezed from a home position incrementally further extends the length of the respective top or bottom assembly and when released returns to the home position leaving the respective top or bottom assembly in the incrementally extended length.
In one example, the top and bottom assemblies can each have a fixed segment and an adjustable segment telescopically slidable along and relative to the fixed segment.
In one example, each jack mechanism can be connected to and positionally fixed lengthwise along the respective fixed segment of the corresponding top or bottom assembly. Actuating the jack mechanism can incrementally further extend an adjustable segment of the corresponding top or bottom assembly relative to and telescopically along the respective fixed segment.
In one example, each jack mechanism can have a squeezable lever that, when squeezed from a home position and released back to the home position, incrementally further extends an adjustable segment relative to a fixed segment on each of the top and bottom assemblies.
In one example, each jack mechanism can prevent an adjustable segment from being retracted back along a respective fixed segment on the respective top or bottom assembly unless the jack mechanism is released.
In one example, each jack mechanism can have a release mechanism that can be actuable to release an adjustable segment relative to a fixed segment on each of the top and bottom assemblies so as to be retractable back along the fixed segment.
In one example, the safety gate can include a cover over a release mechanism on each one-way jack mechanism and can include a lock mechanism operable between a locked position retaining the cover in a closed position preventing access to the release mechanism and an unlocked position permitting the cover to be moved to the open position allowing access to the release mechanism.
In one example, the frame can be foldable to a compact configuration with the top and bottom assemblies positioned closely adjacent and generally parallel to one another and with the opposed side assemblies folded therebetween.
In one example, the frame can be reconfigurable from the deployed configuration to a compact configuration. The side assemblies each can have a latch that locks the frame in the deployed configuration and that can be unlatched to allow the frame to be folded.
In one example according to the teachings of the present invention, a safety gate has a frame with top and bottom assemblies and opposed side assemblies. The frame is reconfigurable between a compact configuration and a deployed configuration. A flexible barrier is connected to and supported by the frame. A one-way jack mechanism is carried on each of the top and bottom assemblies. A length of each of the top and bottom assemblies can be extended to adjust the frame to loosely fit between two surfaces without operating the one-way jack mechanisms. The one-way jack mechanisms, when actuated, incrementally extend the lengths of the top and bottom assemblies such that the frame can interferingly fit between two surfaces under compression in the deployed configuration. In the compact configuration, the top and bottom assemblies are closely spaced and generally parallel to one another and the opposed side assemblies are folded between or adjacent the top and bottom assemblies.
In one example, in the deployed configuration, the one-way jack mechanisms can be actuable and returnable one or multiple times whereby each actuation incrementally extends the length of the top and bottom assemblies in one direction and each return does not retract the length of the top and bottom assemblies in a direction opposite the one direction.
In one example, each one-way jack mechanism can have a housing, a lever extending from one side or face of the housing, and a release element positioned on another side or face of the housing different from the lever. The levers, when squeezed from a home position, can actuate the respective one-way jack mechanisms. The release elements can be operable to release the respective one-way jack mechanisms allowing the lengths of the top and bottom assemblies to be retracted.
In one example, the safety gate can include a cavity on the housing and a release element disposed within the cavity. A cover can be positionable over the cavity and movable between an open position exposing the release element and a closed position covering the cavity and the release element. A lock mechanism can be operable between a locked position retaining the cover in the closed position and an unlocked position permitting the cover to be moved to the open position.
In one example, the opposed side assemblies can each have an upper section and a lower section connected to one another at a central hinge and can be pivotable between an extended orientation and a folded orientation corresponding to the deployed and compact configurations, respectively, of the frame.
In one example, the opposed side assemblies can each have a central hinge with a latch configured in a latched position to lock the respective side assemblies in the extended orientation.
In one example, the opposed side assemblies can each have a central hinge with a latch that can be selectively unlatched by pushing a corresponding pin, which can unlocks the respective upper and lower sections.
In one example, the opposed side assemblies can each have a central hinge with a latch that can be selectively unlatched by pushing a corresponding pin. The pins can be spring biased to a latched position.
In one example, the opposed side assemblies can each have a central hinge with a latch. Each latch can include a hinge knuckle defined in part on an end of each of an upper section and a lower section of the respective side assembly. A bore can extend axially along each hinge knuckle and be formed in part by each of the upper and lower sections. The bore can have differently shaped circumferential portions spaced along its length. A latch pin can be positioned within each bore and can have differently shaped circumferential segments spaced along their lengths. The latch pins can be axially movable between a latched position and an unlatched position. The differently shaped portions and segments can cooperate to permit relative rotation about the respective pin between the upper and lower sections of the opposed side assemblies in the unlatched position and to prevent such relative rotation in the latched position.
Objects, features, and advantages of the present invention will become apparent upon reading the following description in conjunction with the drawing figures, in which:
It is the aim of the present invention to provide a safety gate that is safe and secure when installed, is easy to install, is easy to use, and is easy to transport and store. A safety gate is disclosed herein that, when deployed, can be positioned and removably secured in a doorway or other opening between opposed surfaces, such as a doorframe, hallway walls, or stairwell entrance or exit walls. When installed, the disclosed safety gate serves as a barrier to inhibit pets and children from accessing certain rooms, spaces, or floors of a home or dwelling, as desired. The disclosed safety gate employs a frame that is adjustable to allow the gate to be freely expanded and pulled open to a desired length or width to loosely fit within an opening.
The disclosed safety gate has adjustment or jack mechanisms that can be used to micro-adjust the gate frame in fine or small increments to the length or width necessary to secure the gate in place when installed. The micro-adjustment process is easy and intuitive. By setting up the gate to its approximate size and actuating the jack mechanisms a few times or less, the safety gate can be easily yet securely set-up and installed. When not in use, the safety gate can be conveniently and easily folded or collapsed from the deployed or in-use configuration to a compact storage configuration. As a result, unlike prior art safety gates, the disclosed safety gate is easy to transport and store. These and other objects, features, and advantages of the present invention will become apparent upon reading this disclosure.
Turning now to the drawings,
The side assemblies 56 in the disclosed example are essentially identical to one another or at most mirror images of one another. Likewise, the top and bottom assemblies 58 are essentially identical to one another or at most mirror images of one another. Thus, only one of the side assemblies 56 and only the top assembly 58 are described in substantial detail herein. Similarly, the pivot joints 60 in the disclosed example are essentially identical in construction to one another or at most mirror images or one another as well. Therefore, only one of the pivot joints 60 is described in substantial detail herein.
The frame 52 is generally widthwise extendable and retractable to fit different sized openings. The safety gate 50 and frame 52 are shown in an extended and deployed configuration in
The barrier 54 is a flexible material and/or an elastic material that can fold along with the frame 52. In the deployed configuration, the side assemblies 56 and top and bottom assemblies 58 of the frame 52 form a rectangle-like shape as shown in
The barrier 54 can be a stretchable or elastic fabric, mesh, sheet, or other such material. Alternatively, the barrier 54 can instead be a non-stretchable or inelastic fabric, mesh, sheet, or other suitable material that is sufficiently flexible to be capable of folding up when the frame 52 is folded. The barrier can also be formed of one homogeneous material or from two or more different materials, material layers, or the like. The barrier 54 could be formed in two side-by-side sections of different materials. As described below, one side of the safety gate 50 has a fixed width or length defining the minimum opening size into which the gate will fit. The other side of the safety gate 50 is extendable and retractable to change the size of the gate. The extendable side of the safety gate 50 could include a limp, highly flexible, foldable, or compressible fabric, such as a mesh material. This can allow the gate to achieve a relatively small, compact minimum package size in the folded or compact configuration. The fixed side of the safety gate 50 could utilize a less flexible, stiffer, more course material, such as a solid fabric. This material could permit the printing of required warning labels/instructions directly on the fabric or permit sewing directly to the material separate patches or swatches with the labels/instructions thereon. In the deployed configuration, the material of the barrier 54, regardless of its make-up, serves as the barrier of the safety gate 50 that inhibits children or pets from passing to the other side of the gate, as is known in the art.
As depicted in
Also as shown in
The jack mechanism 70 has a housing 84 with a bore 86 extending lengthwise through the housing. Both of the segments 80 and 82 extend at least partly through the bore. A fixing element 88 is shown in
The jack mechanism 70 has a lever 90 pivotally mounted partly over and partly within a first cavity 92 on one side of the housing 84. The lever 90 has an actuator or grip 94 that is spaced from and generally parallel to a surface of the housing 84. The lever 90 also has a body 96 connected to the grip 94. The body 96 is seated in the first cavity 92 and pivotally mounted therein. Pivot pins 97, as shown in
With reference to
The lever 90 is shown in
The housing 84 has a second cavity 120 formed in the side of the housing opposite the first cavity 92. The second cavity 120 has a brake wall 122 facing into the cavity. The brake wall 122 is oriented at a non-perpendicular angle relative to the axis A of the adjustable segment 82. A brake plate 124 is disposed in the second cavity 120 and bears against the brake wall 122 in a braking position as shown in
According to one aspect of the invention, the safety gate 50 can be easily adjusted without actuating the jack mechanisms 70 to nearly fit a desired opening size. Then the safety gate 50 can be secured using the jack mechanisms 70. In a disclosed example, the adjustable segment 82 can be readily pulled in the direction of the arrow E to extract the adjustable segment and extend the length of the top assembly 56. When pulled in this direction, the brake plate 124 will pivot about the pivoting end 128 away from the brake wall against the bias force of the spring 134. The brake plate 124 and thus the through-hole 126 will then be more perpendicular to the axis A. Likewise, the pivoting end of the drive plate 100 will release from the bearing surface 99 in the first cavity. The drive end 106 will remain captured in the seat 108 under the lever grip 94 so that the drive plate 100 pivots about the drive end. The drive plate 100 and through-hole 102 will then become more perpendicular to the axis A. The edges of the through-holes 102 and 126 will release the surface 114 of the adjustable segment 82, allowing the segment to slide along the bore 86 in the direction of the arrow E.
When the adjustable segment is extended to a desired position in this manner, the spring 134 will return the brake plate 124 against the brake wall 122 in the second cavity. Likewise, the spring 110 will return the drive plate 100 back into contact with the bearing surface 99 in the first cavity 92. The edges of the through-hole 126 in the braking position will again bite against the surface 114 on the adjustable segment 82, preventing it from returning in the direction of the arrow R.
The jack mechanism 70 can then be actuated by squeezing the lever 90 toward the housing 84 as shown in
The construction of the jack mechanism 70 allows the length of the top assembly 58 to be readily extended by pulling the adjustable segment 82 in the direction of the arrow E. The bottom assembly 58 can be extended in the same way. In this manner, the safety gate 50 can be easily extended to nearly fit the size of an opening. Once the safety gave 50 is placed within a desired opening and extended manually to nearly fit the opening size, the jack mechanisms 70 can then actuated to incrementally further extend the top and bottom assemblies 58 into contact with the surfaces of the opening. The lever 90 can be squeezed to secure the top and bottom assemblies 58 under compression against the surface of the opening. The top and bottom assemblies 58 can be adjusted independent of one another. The safety gate 50 can thus accommodate openings where the two surfaces are not square relative to one another.
The top segment 58 can be released by actuating a release mechanism as shown in
According to another aspect of the invention, the frame 52 is easily foldable to the substantially compact configuration shown
The configuration and construction of the joints 60 can vary from this example. There are a large number of pivot joint constructions that can be utilized within the spirit and scope of the present mention. In this example, the fixed pin 148, trunnion 144, and slots 146 provide a joint construction that is a relatively simple, inexpensive, and easy to assemble. The frame 52 can thus be relatively inexpensive to manufacture, require relatively few components, be relatively easy to assemble, and yet provide high-end performance and functionality. In one alternative example, the joints can be configured as ball and socket connections.
As shown in
As shown in
The latch pin 163 has a cylindrical first part 174 adjacent the head 170. The latch pin 163 has a cylindrical intermediate part 176 adjacent the first part 174. The intermediate part 176 has a smaller diameter than the first part 174. The latch pin 163 has a non-circular, shaped, keyed part 178 adjacent the second part 176. The keyed part 178 has a pair of opposed flat segments 180 and a pair of opposed bearing segments 182 offset 90° relative to the flat segments 180 circumferentially around the latch pin 163. The bearing segments 182 are of about the same curvature and diameter as the first part 174 on the latch pin 163. The flat segments 180 have a lesser diameter across the pin thereat. The latch pin 163 also has an end part 184 at the end of the pin opposite the head 170 and first part 174. The end part 184 is cylindrical, but of a smaller diameter than the first part 174. The groove 172 is formed in the surface of the end part 184 near the tip of the latch pin 163. Thus, the latch pin 163 has a number of differently shaped regions or segments over its length.
The pin bore 168 likewise has a number of differently shaped portions or segments over its length as well. With reference to
As shown in
The right side assembly 56 can have the identical construction as the left side. Alternatively, as in this example, the right side can be a mirror image of the left side, but with the latch pin oriented with the head 170 facing in the same direction as the left side latch pin. Thus, the upper and lower sections on the right side would be flipped, having the lower section 142 above the upper section as shown in the drawings.
As shown in
During use, the safety gate 50 can be folded from the deployed configuration to the compact configuration by first pushing in the latch pins 163 to the unlatched positions of
To remove the safety gate 90 from an opening and fold the gate, the jack mechanisms 70 should first be released. This can be done by manipulating the brake plates 124 as discussed above. The release mechanisms allow the top and bottom assemblies 58 to be retraced to the shorted deployed configuration of
From the partially folded configuration shown in
In one alternative example, the pivot hub 72 can be configured without any type of latch. Instead, compression of the top and bottom assembly 58, once installed, can be solely relied upon to retain the overall shape of the frame 52. Alternatively, the pivot hubs can be configured to have an over-center condition that occurs just prior to achieving the deployed configuration. The over-center condition can help retain the side assemblies in the extended orientation. In another alternative example, the pivot hubs 72 can be configured to latch in both the extended orientation of the side assemblies as well as the compact position of the site assemblies. The latch pins and latch bores could be configured so as to latch in both positions, if desired. This would help retain the safety gate 50 in the compact configuration for easy storage and transport. The flats on the pivot pin and in the bore in this example could be arranged to realign in the folded, compact configuration and in the deployed configuration to accomplish this dual latching alternative.
In the disclosed example, each of the upper and lower sections 140, 142 is constructed as a generally flat plank having a depth much greater than a thickness of the plank. The sections 140, 142 can be molded plastic or other such material and have strengthening ribs 212 within a cavity forming the thickness of the structure. This can reduce weight of the safety gate 50 while providing a strong and durable product.
Each of the upper and lower sections has a remote end 214 with a pad 216 secured to an outward facing side 218 of the remote end, opposite the face carrying the trunnion 144. In the deployed configuration, the pads 216 and outward facing sides 218 are generally aligned in parallel with one another on each of the side assemblies 56. As shown in
The pads 216 can be provided having a desired thickness, resiliency, durometer, surface texture, and the like. These aspects of the pad can produce a desired grip or friction against the surfaces of the opening into which the gate is installed. The pads 216 can be configured to take up slight angular variations, contours, bumps, depressions, etc. in the surfaces of the opening. Thus, the pads 216 can assure good surface contact regardless as to whether the surfaces themselves are irregular or non-flat, or whether the surfaces are out of square with other portions of the surfaces in the opening. It is also possible that feet can be provided on the outward facing sides 218 of the upper and lower sections 140, 142 whereby the feet are capable of slight relative, angular adjustment or movement to account for such surface irregularities. The feet could be connected to the upper and lower sections by a ball and socket joints permitting such relative movement, if desired.
The disclosed safety gate 50 is easily and securely widthwise adjustable. The gate 50 is also easily foldable to a compact configuration and also easily deployed. The free ends 138 of the top and bottom assemblies 58 can be attached to and detached from the trunnions 144 on the side assemblies 56 in this example. This can permit the safety gate 50 to be further broken down, if desired, whether to reduce the shipping cube size and/or to reduce retail shelf space required.
The upper and lower jack mechanisms 70 allow a user to extend or lengthen the upper and lower tube assemblies quickly and easily. The jack mechanisms also allow the user to micro-adjust the width of the safety gate 50 in fine increments so as to securely fit into virtually any size opening within the limits of the size of the fixed segment 80 and adjustable segment 82 of the top and bottom assemblies 58. The top and bottom assemblies need not be identical to or mirror images of one another. Likewise, the left and right side assemblies 56 need not be identical to or mirror images of one another.
In other examples, the top and bottom assemblies 58 can be shaped or sized differently, such as having a panel shape or plank shape like the side assemblies 56. Alternatively, the side assemblies can be tube shaped like the top and bottom assemblies 58. In other examples, the upper and lower sections 140, 142 and fixed and adjustable segments 80, 82 may also be coupled together in a different manners than the examples shown and described herein. The gate may utilize a different hinge or pivot components to connect the upper and lower sections 140, 142 together. Another connection mechanism can be used to connect the sections, allowing the sections to be rotated, slidably adjusted, or otherwise folded relative to one another when desired.
The jack mechanisms 70 can also very in configuration and construction. The component arrangement for the drive mechanism and the release mechanism can vary from the example shown and described herein. In one example, the release mechanism can include a cover that, when pivoted open, automatically moves the brake plate to a release orientation. The cover could have a flex finger in direct contact with the brake plate working end 130 that moves the brake plate upon rotating the cover. Such a release mechanism would require only one step instead of the two (open cover, move brake plate) required in the disclosed example. The adjustable segment or tube 82 can have a shaped surface near the proximal end that limits the function of the jack mechanism beyond a specified extend position. The shaped surface can be such that the drive plate 100 no longer can bite into the surface 114, preventing further incremental extension of the segment by the jack mechanism.
The segments 80, 82 or tubes can be round, oval, square, or any other suitable shape in cross-section. The tube assembly can also be constructed of two planar, interlocking plates slidably connected to one another. The springs disclosed herein are conventional compression springs. However, the springs for the pivot hub and the jack mechanisms can be other types of springs such as torsion springs, leaf springs, or the like. The lever 90 is L-shaped in this example. The lever 90 is pivotable about the pivot pins 97 in this example. However, the lever 90 can pivot about any pin or axle configuration that extends laterally relative to the housing 84 and body 96. The pins 97 or other structure can seat in pivot pockets in the first cavity 92 of the housing 84. The shape, structure, and configuration of the lever 90 can also vary from the example shown and described herein. In other examples, the grip and/or body may have a different shape and size. The lever may also be configured to be squeezed or actuated in a different manner than described herein. The cavities in the housing 84 can also vary, as can the functional surfaces therein.
Each squeezing action of the lever 90 causes the adjustable segment 82 to incrementally slide out of the fixed segment, slightly extending the length of the tube top or bottom assembly 58. The amount or degree of incremental movement permissible by the jack mechanism can be designed and predetermined by altering the lever travel, various surface angles, cavity sizes, plate through-hole sizes, plate and surface orientations, and the like. The number and size of the springs can be altered to change the squeeze force required to actuate the lever 90. One single spring instead of two springs could be arranged in the housing to bias both the brake and drive plates, if desired.
The release mechanism on the jack mechanisms 70 can also vary from the aforementioned example. One such example is shown in
The release mechanism in this example also has a lock mechanism 240 provided on the cover opposite the depression 238. The lock mechanism 240 has a rotatable lock cylinder 242 with a rib 244 disposed on a head 246 of the lock cylinder. The rib 244 acts as both a grip to rotate the lock cylinder 242 and as an indicator of the position of the lock cylinder. The face of the cover 232 includes the words “lock” and “unlock” and a directional arrow between them. The lock cylinder 242 can be rotated via the rib 244 to direct the rib toward one of the “lock” and “unlock” words on the cover 232 as discussed below.
The head 246 also includes a pair of engagement prongs 260 to attach the lock cylinder 242 to the cover 232. Each prong 260 protrudes in the direction of the shaft 254, but is positioned spaced slightly inward from the perimeter edge of the head 246. Each prong 260 has a tab 262 that protrudes radially outward beyond the perimeter of the head 246. The cover 232 has an opening 264 that is sized to receive the lock cylinder 242 therein. With reference to
As shown in
The lock mechanism 240 can be unlocked in order to release the cover 232. To do so, one need only rotate or twist the lock cylinder 242 via the rib 144 in the direction of the arrow toward the word “unlock” on the cover. When the rib is pointing toward the word “unlock,” as shown in
Details of the lock mechanism 240 can also vary from the example shown and described herein. Features of the lock cylinder 242 can be changed without altering the locking capability of the mechanism. The key hole in the second cavity 120 of the housing can also change to accommodate. Other latching or locking devices could also be used to secure or release the cover as a secondary safety feature for the jack mechanisms. Features of the opening in the cover can also be altered from the disclosed example. Other means can be used to indicate the locked or unlocked arrangement or orientation of the locked mechanism and other structures can be used to retain the lock mechanism components on the housing and/or cover.
Although certain safety gate features, methods, components, and constructions have been described herein in accordance with the teachings of the present disclosure, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all embodiments of the teachings of the disclosure that fairly fall within the scope of permissible equivalents.
This patent application is a continuation-in-part of U.S. application Ser. No. 13/401,880 filed on Feb. 21, 2012 which is related to and claims priority benefit of U.S. provisional patent application Ser. No. 61/444,966 filed Feb. 21, 2011 and entitled “Safety Gate.” The entire contents of this prior filed provisional application are hereby incorporated by reference herein.
Number | Name | Date | Kind |
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5197360 | Wooster, Jr. | Mar 1993 | A |
5575113 | Huang | Nov 1996 | A |
5704164 | Huang | Jan 1998 | A |
6152434 | Gluck | Nov 2000 | A |
6733220 | Brown | May 2004 | B2 |
7422048 | Andersen | Sep 2008 | B2 |
20110018226 | Jessie, Jr. | Jan 2011 | A1 |
Number | Date | Country | |
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20150330142 A1 | Nov 2015 | US |
Number | Date | Country | |
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61444966 | Feb 2011 | US |
Number | Date | Country | |
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Parent | 13401800 | Feb 2012 | US |
Child | 14807949 | US |