The present subject matter relates to drain cleaning equipment and particularly coupling assemblies associated with drain cleaning cables and tools.
Referring to
To separate the cutter tool 3 from the coupling 5 and the end 1 of the lead cable 2 or separate sections of cable after use, a cable key pin 10, as depicted in
When the cable key pin 10 is fully inserted through the tool 3 and the spring-actuated plunger 6 is fully retracted, the cutter tool 3 or adjacent cable section can then be disengaged from the adjacent component. The user can then remove their hand from the cable key pin 10 and use manual hand force to slide the two components, for example the tool 3 and the cable coupling 5, apart as shown in
The system described above, typically requires the user to remove their hand from the cable key pin 10 in order to obtain the proper leverage for easily separating sections of cable or a cutter from the cable. This requires additional time to complete, and the sliding motion required to separate the components is difficult to maneuver by hand. This difficulty is increased as dirt and debris accumulate onto the cable, as well as after corrosion has developed on the sliding surfaces of the coupling and the tool or adjacent cable section.
Accordingly, a need exists for a new strategy and assembly for disengaging couplings of drain cleaning cables.
The difficulties and drawbacks associated with previous approaches are addressed in the present subject matter as follows.
In one aspect, the present subject matter provides a decoupler tool comprising a handle, a first pin extending from the tool handle, and a second pin extending from the tool handle. A distal end of the first pin is tapered.
In another aspect, the present subject matter provides a decoupler tool comprising a base having a first outwardly extending member and a second outwardly extending member spaced from the first member to thereby define a receiving region between the first member and the second member. The decoupler tool also comprises a primary pin extending from the base and disposed within the receiving region. The primary pin defines a distal end, wherein the distal end of the primary pin is tapered. The decoupler tool also comprises a cam face extending from the first member toward the base.
In yet another aspect, the present subject matter provides a system for selectively disengaging a drain cleaning cable coupling and a mating component. The system comprises a drain cleaning cable coupling. The coupling includes an axially displaceable plunger biased to extend axially outward. The system also comprises a mating component. The mating component includes provisions to radially and slidably engage the coupling along opposing faces of the coupling and the mating component. The mating component defines an aperture that provides radial access to a distal end of the plunger upon engagement between the coupling and the mating component and axial extension of the plunger. The system also comprises a decoupler tool including a tool handle, a first pin extending from the tool handle, and a second pin extending from the tool handle, wherein the first pin is sized and shaped to enable the first pin to be inserted within the aperture of the mating component.
In still another aspect, the present subject matter provides a system for selectively disengaging a drain cleaning cable coupling and a mating component. The system comprises a drain cleaning cable coupling. The coupling includes an axially displaceable plunger biased to extend axially outward. The system also comprises a mating component. The mating component has provisions to radially and slidably engage the coupling along opposing faces of the coupling and the mating component. The mating component defines an aperture that provides radial access to a distal end of the plunger upon engagement between the coupling and the mating component and axial extension of the plunger. The system also comprises a decoupler tool including a base having a first outwardly extending member and a second outwardly extending member spaced from the first member to thereby define a receiving region between the first member and the second member, and a primary pin extending from the base and disposed within the receiving region. The primary pin defines a distal end. The distal end of the primary pin is tapered. The decoupler tool also includes a cam face extending from the first member toward the base.
In yet another aspect, the present subject matter provides a method for selectively disengaging a drain cleaning cable coupling and a mating component. The coupling includes an axially displaceable plunger biased to extend axially outward. The mating component defines an aperture that provides radial access to a distal end of the plunger upon engagement between the coupling and the mating component and axial extension of the plunger. The method comprises providing a coupling engaged to the mating component and providing a decoupler tool including a handle, a first pin, and a second pin. The method also comprises inserting the first pin of the tool into the aperture of the mating component. The method also comprises rotating the tool about the first pin until the second pin contacts the coupling. The method also comprises further rotating the tool about the first pin so that the coupling and the mating component are displaced relative to each other. The method further comprises continuing rotation of the tool about the first pin until the coupling and the mating component are disengaged from each other.
In another aspect, the present subject matter also provides a method for selectively disengaging a drain cleaning cable coupling and a mating component. The coupling includes an axially displaceable plunger biased to extend axially outward. The mating component defines an aperture that provides radial access to a distal end of the plunger upon engagement between the coupling and the mating component and axial extension of the plunger. The method comprises providing a coupling engaged to the mating component and providing a decoupler tool including a base having a first outwardly extending member and a second outwardly extending member spaced from the first member to thereby define a receiving region between the first member and the second member, a primary pin extending from the base and disposed within the receiving region, the primary pin defining a distal end, wherein the distal end of the primary pin is tapered, and a cam face extending from the first member toward the base. The method also comprises inserting the primary pin of the decoupler tool into the aperture of the mating component. The method also comprises moving the coupling engaged to the mating component toward the base of the decoupler tool. The method further comprises contacting the mating component with the cam face of the decoupler tool. And, the method also comprises further moving the coupling engaged to the mating component toward the base of the decoupler tool until the coupling and the mating component are disengaged from each other.
As will be realized, the subject matter described herein is capable of other and different embodiments and its several details are capable of modifications in various respects, all without departing from the claimed subject matter. Accordingly, the drawings and description are to be regarded as illustrative and not restrictive.
The present subject matter applies to sectional drain cleaning cable equipment and operations such as separating, i.e. decoupling, sections of cable or separating a lead cable and a cutter tool or other accessory. The present subject matter could apply to drain cleaning cable and/or related equipment available under the RIDGID designation or other manufacturers of drain cleaning cable that utilize similar attachment methods between cable sections and/or between a lead cable and a cutting tool or accessory. The present subject matter also applies to nearly any cable size, i.e., diameter, and/or variation of such products. The present subject matter could further apply to separating drum drain cleaning cables. In this case, the present subject matter would apply to decoupling the cable from the cutter tool used for clearing the drain blockage. These and other aspects are described in greater detail herein.
Generally, the applicable field for the present subject matter is disengagement assemblies, tools, and methods relating to disengaging drain cleaning cable(s). The various embodiments of the drain cleaning decoupler tools detailed herein provide greater flexibility in use for accommodating multiple drain cleaning cable sizes. In this way, all sectional drain cables available under the RIDGID designation and some drum drain cables are contemplated as each share common end couplings, for example ⅜″ drum cable uses the ⅝″ sectional cable coupling; ½″ drum cable uses the ⅞″ sectional cable coupling.
The present subject matter provides tools, systems, and related strategies that more efficiently separate sectional drain cleaning cable coupling assemblies as compared to currently known tools and practices. The present subject matter is achieved by utilizing a decoupler or decoupling tool comprising two parallel cylindrical members or pins, having a specific configuration and spacing between their axes, that function to individually move the spring-actuated plunger away from the coupling joint, via a primary pin; and to displace the two coupling components apart, via a secondary pin, as shown in the referenced figures.
The tool 20 can also comprise an enlarged portion of the tool body 24 or a handle 50 for example to promote gripping of the tool by a user. The handle 50 can be in a variety of shapes and sizes. In many versions, the handle 50 is in the form of a longitudinal member having opposite ends 52, 54. In certain versions, the handle 50 extends along an axis that is perpendicular or substantially so, to the axes of one or both of the first and second pins 30, 40. This configuration is depicted in
To achieve separation between a coupling having a spring-biased plunger and a tool or adjacent section of cable, the primary pin of the decoupler tool utilizes a feature to aid inserting the pin in the gap between the spring-actuated plunger and the engagement aperture in the mating cable or cutter tool. This feature is achieved by using a particular size and shape cross section of the primary pin that allows the pin to be completely inserted from various rotational orientations due to its reduced cross sectional area. Specifically, referring to
Using the primary pin, the spring-actuated plunger is retracted or otherwise moved into the cable body, leaving the cutter tool free from plunger engagement. Specifically,
The decoupler tool is then rotated about the primary pin which serves as a pivot point until the secondary pin contacts the cable coupling of the cable with the integrated spring-actuated plunger. In many embodiments, the present subject matter requires the spacing between the primary and secondary pins to be adequate to contact the coupling of the cable and not the coil of the cable. In many embodiments, the present subject matter also requires the spacing between the primary and secondary pins be adequate to ensure that the secondary pin avoids contact with the cutter tool. And thus, this spacing requires that the secondary pin must clear the edge of the cutter tool during rotation of the decoupler tool. Referring to
As the tool is further rotated in this manner, force applied via the secondary pin against the coupling slides the coupling joint apart, as shown in
With the decoupler tool rotated further, the joint becomes completely separated and the coupling components, i.e., coupling 5 and tool 3, freed from each other, thereby completing the process of separating the cables or the cable and the cutter tool, as shown in
The present subject matter decoupler tools feature the use of two pins to perform a function of depressing the spring-actuated plunger and another function of shifting apart the cable coupling components, i.e., the coupling 5 and the tool 3, to achieve complete separation. This can be accomplished for example with two separately mounted pins, a weldment of two pins, and/or a loop of continuous pin material formed to create the proper spacing between pins, as depicted in
The present subject matter includes tools having two pins with the same end profile/geometry or pins with different end profiles as described herein. Thus, in certain embodiments of the tools, the distal end of the second pin may be the same or different than the distal end of the first pin.
The present subject matter decoupler tools can additionally use a larger feature on the secondary pin that prevents the user from inadvertently inserting the secondary pin into the access aperture 8 of the tool or coupling, which would not result in axial movement of the spring-actuated plunger 6. For example, the second pin could exhibit a larger cross sectional area than the first pin and/or feature a cross sectional area or shape that precludes insertion of the second pin into the aperture 8 of the tool 3 or adjacent cable section. Instead of utilizing a larger cross section for the second pin, it is also contemplated that the second pin could include one or more projections or regions extending outward from the second pin so as to prevent insertion of the second pin into the noted aperture. For example,
Additionally, the present subject matter decoupler tools could feature a longer secondary pin as compared to the length of the primary pin to protect the smaller cross sectional area tip or distal end of the primary pin, as shown in
To further protect the primary pin from damage during use, the working length of the primary pin is configured to extend no further than the body of the cable coupling so that, when completely inserted, the tip or distal end of the primary pin cannot contact any outside components and become damaged. This configuration is also shown in
In certain versions, the distal end of the primary pin features a reduced cross section for easier insertion into the gap between the spring-actuated plunger tip and the adjacent coupling. The geometry of this configuration can take many forms, but a conical profile is preferred in particular versions as it provides the ability for the primary pin to be inserted from any rotational orientation that the operator chooses to use as depicted in
An additional feature for this tool is the use of an integrated keychain aperture that allows tethering the decoupler tool to another component, piece of equipment or to the user's clothing to reduce the possibility of misplacement or loss, as shown in
The decoupler tools of the present subject matter may additionally feature a component for cleaning debris and drain blockage remnants from the windings of the cable. This feature could be inserted through the cable coils and the tool moved to pick or scrape at the debris. This function could be achieved through use of the primary or secondary pin, or with a dedicated cleanout feature incorporated or otherwise provided on the tool. Another additional feature for this tool is an area intended for tapping coupling joints, i.e. a hammer face. A feature that allows the user to tap cable couplings could be used by the operator to force two coupling components together or to confirm that a proper connection has been made after attachment, ensuring that separation will not inadvertently occur when the coupling assembly is located in the drain. Another additional feature for the tools of the present subject matter is an enlarged section of the handle to promote separation of the tool from the ground when set down, thereby easing the ability of the user to grasp the tool, especially when wearing gloves as is typical for drain cleaning professionals.
In yet another embodiment, the present subject matter provides a decoupler tool having three (3) pins.
The general features and use of the tool 120 are as previously described with regard to the decoupler tool 20. However, in the decoupler tool 120, the addition of the smaller primary pin 45 enables the tool 120 to be used with different cable sizes. The larger primary pin 30 is typically larger in both diameter and length as compared to the small primary pin 45, and is for use with relatively large cable sizes, for example ⅞ inch and 1¼ inch. The smaller primary pin 45 is for use with ⅝ inch cable, for example. Each primary pin 30 and 45 is configured for use with a particular cable size such that the diameter, length, and distal end profile are selected for performance with the particular cable. The secondary pin 40 is disposed between the two primary pins 30 and 45.
Using the decoupler tool 120, a user positions the appropriate primary pin 30 or 45 through the cable coupling to depress the spring-actuated plunger as described herein. The decoupler tool 120 is then rotated such that the secondary pin 40 contacts the opposite side of the coupling joint and rotated further through the connection to thereby separate the coupling components. The function with either the small or large primary pin is the same to the user, and the common secondary pin always creates the separation. As previously described herein, the secondary pin can be of larger diameter to prevent inadvertent placement of it into the spring-loaded plunger access hole of the coupling.
Alternatively, this common decoupler function could be achieved by mounting a separate primary pin/secondary pin couple at a different position on the tool. Likewise, rotating or sliding action of the second primary pin could be incorporated to achieve the storage and positioning of the pins for use.
In still another embodiment, the present subject matter provides a stationary decoupler tool. In this embodiment, the decoupler function can be achieved by utilizing a stationary fixture featuring a pin with a wedge shaped or tapered end tip similar to the previously described decoupler tool 20, a straight guide, and an offset guide, as shown in
Specifically, this embodiment of a decoupler tool 60 is shown in
The decoupler tool 60 also comprises a primary pin 80 extending from the base 62 and located generally between the first and second members 66, 68. The primary pin 80 is generally disposed within the noted receiving region 70 defined by the members 66, 68. In many versions of the decoupler tool 60, the primary pin 80 is parallel or substantially so, to the longitudinal axes of one or both of the first and second members 66, 68. However, it will be appreciated that the present subject matter includes versions in which the primary pin 80 is not parallel to one or both of the members 66, 68.
The primary pin 80 defines a distal end 82. The shape of the distal end 82 is typically tapered as previously described herein regarding the distal end 32 of the primary pin 30 of the decoupler tool 20.
The decoupler tool 60 also comprises a cam face 90 extending from member 66 or the second member 68. In the embodiment depicted in
The cam face 90 is typically flat or substantially so. However, the present subject matter includes arcuate shapes and/or complex geometries for the cam face 90. The cam face 90 extends toward the base 62 from the inner face 67 of the first member 66. Typically, the cam face 90 extends at an angle from a longitudinal axis of the first member 66 shown in
In particular versions of the decoupler tool 60, the cam face 90 extends from the inner face 67 of the first member 66 at a location that is generally the same distance from the base 62 as the distance between the distal end 82 of the primary pin 80. However, the present subject matter includes a wide array of variant configurations and arrangements of components.
The decoupler tool 60 may in certain versions include a harbor region 94 for receiving a portion of the drain cleaning cable and/or coupling component undergoing disengagement. In particular versions, the harbor region 94 is accessible along a face of the tool 60, and also accessible from the receiving region 70. In the version of the decoupler tool 60 shown in
In certain versions of the decoupler tool 60, the harbor region 94 includes a straight guide which is generally in the shape of a U-shaped region defined by one or more guide walls 95 extending between the rear face 63 and a ledge 96. The harbor region 94 can also include an offset guide which is generally in the shape of a U-shaped region defined by one or more guide walls 97 extending between the ledge 96 and an end face 98. In particular versions of the decoupler tool 60 at least a portion of the guide wall 95 and/or the guide wall 97 extends at an angle parallel to or approximately the same as the angle of the cam face 90 taken with respect to axis S, i.e., from about 110° to about 160°, preferably from 120° to 150° and more particularly about 135°. However, it will be understood that the present subject matter includes embodiments in which the guide walls 95 and/or 97 or their portions are not parallel to the cam face 90.
The decoupler tool 60 is typically mounted or affixed to a drain cleaning machine or comparable larger equipment component. Such mounting or affixment can be by fastener(s) or welding, or other techniques.
The decoupler tool 60 is used to disengage a drain cleaning cable 2/coupling 5 from a mating component such as a cutter tool 3 or adjacent cable section as follows. A coupling assembly including a coupling 5 and a cutter tool 3 or other accessory as shown in the figures referenced herein, is positioned relative to the decoupler tool 60 so that the pin 80 is directed toward the engagement aperture 8 of the cutter tool 3. The coupling assembly is then positioned within the receiving region 70 of the decoupler tool 60 and the assembly aligned for insertion of the pin 80 in the engagement aperture 8 of the cutter tool 3. The coupling assembly is then urged toward the base 62. With such continued movement, the pin 80 is inserted into the engagement aperture 8 of the cutter tool 3, and the coupling 5 contacts the cam face 90 of the decoupler tool 60. With such further movement, as the coupling 5 contacts the cam face 90 and the pin 80 is inserted within the engagement opening 8 of the cutter tool 3, the plunger 6 is axially retracted as previously described, thereby allowing separation between the coupling 5 and the cutter tool 3. With continued urging of the coupling assembly toward the base 62 of the decoupler tool 60, the coupling 5 is received in the harbor region 94 and the cutter tool 3 is retained via insertion of the pin 80 in the engagement aperture 8.
The decoupler tool of this embodiment is configured such that the drain cleaning cable has two flat surfaces that slide within the guide walls 97 and/or 95 of the decoupler tool 60. A completely cylindrical coupling assembly would not function using this version of the stationary cable decoupler. The present subject matter includes stationary decoupler tools similar to the decoupler tool 60 but devoid of one or more of the harbor region 94, the straight guide having guide walls 95, and/or the offset guide having guide walls 97. In these versions, the decoupler tools can be used with coupling assemblies exhibiting a cylindrical shape.
A significant advantage of the cable decoupler tools of the present subject matter is efficiency gained by the operator during use. While valuable to all drain cleaning professionals, the decoupler tools of the present subject matter are particularly useful to sectional drain cleaning users that use cable couplings frequently and numerously during use when connecting the sections of drain cleaning cable together to reach the distance to the drain blockage. Gains in efficiency can be achieved when separating couplings without removal of the actuation hand from the tool. Additional advantages include faster sliding of the coupling sections apart compared to the currently known methods.
The present subject matter tools provide also greater leverage to the user to separate drain cleaning cable couplings. The large end of the decoupling tool provides greater surface contact area between the user's hand and the tool compared to currently known tools. This allows the user to more easily apply the required force to completely disengage the spring-actuated plunger from the coupling joint or connection. Further, the present subject matter provides leverage in sliding the two coupling components apart through normal twisting motion of the hand. This motion more smoothly separates the components as compared to gripping each side of the coupling joint and using direct application of lateral force(s) to separate the components. For at least these reasons, completing the cable coupling disconnection is achieved more easily than currently known methods and tools.
A common complaint of drain cleaning professionals is the frequency at which currently known key pins are lost on jobsites, carried off inadvertently in a user's pocket, or thrown out accidently with other components. When this occurs, the user must seek out a new tool or search extensively for a tool which has been lost. The tools of the present subject matter provide greater visibility when used or stored on the jobsite. This is at least partly because the tools are larger. A large shaped metal handle or polymeric handle can further improve visibility by using a brightly colored body to further stand out against the surroundings.
The molded handle of many of the decoupler tools described herein can provide a larger and more ergonomic contact point for the user when separating drain cleaning cable couplings. The handle can ease the occupational burden of releasing cable coupling sections repeatedly on a jobsite. Further, this handle allows better access and use of the tool when wearing gloves, common to drain cleaning professionals.
An optional feature of a key ring hole integrated into the body of the handle further reduces the likelihood of the tool being misplaced or lost on a jobsite as the tool can be tethered to another component, larger piece of equipment, or to the user.
The pins of the decoupler tools of the present subject matter can also be used by the operator to clean debris and remnants from the drain that have become intertwined into the cable. As noted, the decoupler tools can include a cleanout component. By inserting the pins or cleanout component through the cable windings, the user can push or pull the debris from the cable to aid in cleanliness of the retrieved cleaning cable.
The addition of a flat and/or hammer section of the handle provides a readily-accessible tool for the user to quickly verify that the spring-actuated plunger has properly engaged the mating coupling to ensure that inadvertent and undesirable separation of the coupling joint does not occur in the drain. Similarly, this feature can be used to help complete the coupling connection if/when binding occurs during installation of the two coupling components together. The user can tap on the coupling joint to help push the coupling components together or to a state of engagement.
Another advantage of the decoupler tools of the present subject matter using a conical shaped distal end of the first pin is the ability to insert the primary pin into the engagement aperture from nearly any angle. With the currently known key pin, the key pin can be inserted into the coupling joint in only a small range of rotational orientations to result in successful actuation of the plunger. With a tip that has a more uniform cross section, the user can extend the tip into the gap between the plunger and the coupling interior wall of the engagement aperture from various orientations, resulting in faster decoupling and minimized nuisance insertions that are impeded by the key pin contacting the blunt surface of the plunger rather than the distal end of the plunger.
For decoupler tools using an enlarged secondary pin for coupling separation, the possible inconvenience of inserting the wrong pin into the coupling assembly is eliminated, resulting in faster operation and eliminating the nuisance of improper pin insertion.
In still other versions of the decoupler tool, a total of three (3) pins are provided. Two primary pins and a single secondary pin are provided in a decoupler tool. The two primary pins differ in size and are adapted for separating coupling assemblies associated with different sizes of drain cleaning cable. The larger primary pin, larger diametrically and in length, is for use with larger cable sizes, for example, ⅞″ and 1¼″. The smaller primary pin, then, is for use with ⅝″ drain cleaning cable for example. Each primary pin is configured specifically for the intended cable size with the diameter, length, and tip profile optimized for performance with the intended size. A single secondary pin resides between the two primary pins.
In all embodiments and versions of the decoupler tools described herein, the pins may exhibit a wide array of cross sectional shapes or configurations. Although in many applications, a circular cross section is typical, the present subject matter includes other shapes. A representative and non-limiting listing of such alternative shapes includes non-circular, oval, irregular, and polygonal in which the pin cross section consists of a total number of n sides, such that n is an integer within a range of from 1 to 10. In certain applications, n is 3 (i.e., a triangular cross section), 4 (i.e., a square cross section, or 6 (i.e., a hexagonal cross section).
With this version of the decoupler tool, the user positions the appropriate primary pin through the cable coupling to depress the spring-actuated plunger as described herein. The decoupler tool is then rotated to allow the secondary pin to contact the opposite side of the coupling assembly and rotated further through the connection to create separation of the couplings components. The function with either the small or large primary pin is the same to the user, and the common secondary pin creates the separation. As described herein, the secondary pin can be of larger diameter to prevent inadvertent placement of the pin into the spring-loaded plunger access hole or engagement aperture of the coupling component, e.g., a cutter tool.
Alternatively, the decoupling function of the tools can be achieved by mounting a separate primary pin/secondary pin couple at a different position on the decoupler tool. Likewise, rotating or sliding action of the second primary pin could be incorporated, as in a common multi-tool or pocket knife, to achieve the storage and positioning of the pins for use.
An advantage of this variation of the cable decoupler tool is improved efficiency and reduced complexity from allowing more functional uses of a single tool. By incorporating features for decoupling all sectional cable into a single tool, the end user does not need multiple, unique tools. This simplifies tool storage by reducing the number of tools kept, eliminates inadvertent attempted use of the wrong tool, and makes finding the right tool faster.
Having a common decoupler tool for all sectional cables and/or accessories also increases the volume of a single tool design entering the market since the number of user applications is greater; not every user would have previously purchased two separate tools. This greater volume will help reduce product cost.
The present subject matter also provides systems comprising the drain cleaning cables, coupling components, and tools or accessories combined with the decoupler tools described herein. For example, in one embodiment, a system for engaging and selectively disengaging a drain cleaning cable coupling and a mating component is provided. The system comprises a drain cleaning cable coupling and a mating component. The mating component includes provisions to radially and slidably engage the coupling assembly apart along opposing faces of the coupling and the mating component. The coupling includes an axially displaceable plunger biased to extend axially outward. The mating component defines an aperture that provides radial access or substantially so, to a distal end of the plunger upon engagement between the coupling and the mating component, and axial extension of the plunger. The system additionally comprises any of the decoupler tools described herein.
Many other benefits will no doubt become apparent from future application and development of this technology.
All patents, applications, standards, and articles noted herein are hereby incorporated by reference in their entirety.
The present subject matter includes all operable combinations of features and aspects described herein. Thus, for example if one feature is described in association with an embodiment and another feature is described in association with another embodiment, it will be understood that the present subject matter includes embodiments having a combination of these features.
As described hereinabove, the present subject matter solves many problems associated with previous strategies, systems and/or devices. However, it will be appreciated that various changes in the details, materials and arrangements of components, which have been herein described and illustrated in order to explain the nature of the present subject matter, may be made by those skilled in the art without departing from the principle and scope of the claimed subject matter, as expressed in the appended claims.
This application claims priority from U.S. nonprovisional application Ser. No. 16/211,331 filed Dec. 6, 2018, which claims priority upon U.S. provisional application Ser. No. 62/598,542 filed on Dec. 14, 2017; and U.S. provisional application Ser. No. 62/652,387 filed on Apr. 4, 2018.
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Number | Date | Country | |
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20210087805 A1 | Mar 2021 | US |
Number | Date | Country | |
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62652387 | Apr 2018 | US | |
62598542 | Dec 2017 | US |
Number | Date | Country | |
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Parent | 16211331 | Dec 2018 | US |
Child | 17114634 | US |