Container with magnetic cap

Abstract
A container having a canister can be configured to retain a volume of liquid. The canister can be sealed by a lid structure, and the lid structure can have a spout opening. The spout opening may be sealed by a removably-coupled cap. Further, the cap may have a magnetic top surface configured to magnetically couple to a recess on the top surface of the lid for temporary storage of the cap when manually removed from the spout opening.
Description
BACKGROUND

A container may be configured to store a volume of liquid. In one example, an opening in the container may be sealed with a removable cap. As such, in order to extract the liquid from the container, the cap may first be manually removed and set aside.


BRIEF SUMMARY

In certain examples, an insulating container may have a canister, which can include an insulated double wall, a first end to support the canister on a surface, a second end, and a sidewall. The canister may also have an opening in the second end that extends through the insulated double wall. A neck structure may encircle the opening and extend in an axial direction.


In certain examples, a lid may seal the opening of the canister, with the a threaded sidewall of the lid received into the neck structure of the canister. The lid may also have a circular domed top surface having a spout opening, and a removable cap that seals the spout opening. Further, the cap may have a magnetic top surface configured to be magnetically attracted to, and retained within, an optional dimple on the domed top surface.


This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. The Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter.





BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is illustrated by way of example and not limited in the accompanying figures in which like reference numerals indicate similar elements and in which:



FIG. 1 depicts an isometric view of an example container, according to one or more aspects described herein.



FIG. 2 depicts another isometric view of the container of FIG. 1, according to one or more aspects described herein.



FIG. 3 depicts an exploded isometric view of another example container, according to one or more aspects described herein.



FIG. 4 depicts a cross-sectional sectional view of the container of FIG. 3, according to one or more aspects described herein.



FIG. 5 depicts a side view of a canister, according to one or more aspects described herein.



FIG. 6 schematically depicts an end view of the container of FIG. 3, according to one or more aspects described herein.



FIG. 7 schematically depicts a plan view of the container of FIG. 3, according to one or more aspects described herein.



FIG. 8 depicts an example cap structure, according to one or more aspects described herein.



FIG. 9 depicts another example cap structure, according to one or more aspects described herein.



FIG. 10 schematically depicts an isometric view of an example lid structure, according to one or more aspects described herein.



FIG. 11 schematically depicts an isometric view of another example lid structure, according to one or more aspects described herein.



FIG. 12 depicts an isometric view of another example container structure, according to one or more aspects described herein.



FIG. 13 depicts an isometric view of another example container structure, according to one or more aspects described herein.



FIG. 14 depicts another implementation of a container structure, according to one or more aspects described herein.



FIG. 15 depicts a cross-sectional view of the container of FIG. 14, according to one or more aspects described herein.





Further, it is to be understood that the drawings may represent the scale of different components of one single embodiment; however, the disclosed embodiments are not limited to that particular scale.


DETAILED DESCRIPTION

Aspects of this disclosure relate to a container configured to store a volume of liquid. In one example, the container may have a spout opening that is sealed with a removable cap. Accordingly, the removable cap may be configured with a magnetic top surface such that when removed, the cap may be magnetically affixed to one or more surfaces of the container for temporary storage while the liquid is being poured from the container.


In the following description of the various embodiments, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration various embodiments in which aspects of the disclosure may be practiced. It is to be understood that other embodiments may be utilized and structural and functional modifications may be made without departing from the scope and spirit of the present disclosure.



FIG. 1 depicts an isometric view of a container 100. In one example, container 100 may comprise a bottom portion 102 having a lid 104 removably coupled thereto. In one example, the bottom portion 102 may be substantially cylindrical in shape. In various examples, bottom portion 102 may be referred to as a canister 102, or base 102. The bottom portion 102 may, alternatively, be referred to as an insulated base structure having a substantially cylindrical shape, and having an opening 116 in one end 114 as shown in FIG. 3. In another example to that implementation depicted FIG. 1, the bottom portion 102 may be substantially cuboidal, or prismoidal (e.g. a pentagonal prism, hexagonal prism, heptagonal prism, among others) in shape. In one implementation, the lid 104 may comprise a carry handle structure 106.


In various examples, the lid 104 may comprise a cap 108 (in one example, cap 108 may be substantially cylindrical), configured to removably couple to, and seal (i.e. resealably seal), a spout opening 110, as depicted in FIG. 2. In one implementation, the carry handle structure 106 may be rotatably coupled to the lid 104, such that the carry handle structure 106 may be pivoted from a first position, as depicted in FIG. 1, to a plurality of second positions, wherein one second position, from the plurality of second positions, is depicted in FIG. 2. For example, the carry handle structure 106 may be rotatable about an axis 103 through a fastener 150 that couples the carry handle structure 106 to the lid 104 (see FIG. 2). In one implementation, the carry handle structure 106 may be rotatable about axis 103 through an angle of greater than 320°. In another example, the carry handle structure 106 may be rotatable about axis 103 through an angle of greater than 300°, greater than 280°, greater than 260°, greater than 240°, or greater than 220°, among others.


In one example, the canister 102 may be configured to store a volume of liquid. In one implementation, the canister 102 may be configured to store approximately 1 gallon (approximately 3.79 L) of a liquid. In another implementation, the canister 102 may be configured to store at least approximately 30 ounces (approximately 0.89 L), at least approximately 50 ounces (approximately 1.48 L), at least approximately 70 ounces (approximately 2.07 L), at least approximately 80 ounces (approximately 2.37 L), at least approximately 90 ounces (approximately 2.66 L), at least approximately 100 ounces (approximately 2.96 L), at least approximately 110 ounces (approximately 3.25 L), or at least approximately 120 ounces (approximately 3.55 L) of a liquid, among others.


Turning briefly to FIG. 5, the canister 102 may have an outer diameter 122, and a height 123. In one implementation, the outer diameter 122 may measure approximately 6.5 inches (165.1 mm). In another implementation, the outer diameter 122 may measure approximately 5.7 inches (145 mm). In yet another implementation, the outer diameter 122 may range between 5 inches and 8 inches. In one example, the height 123 may measure approximately 9.7 inches (246.4 mm). In another implementation, the height 123 may measure approximately 7.4 inches (188 mm). In yet another implementation, the height 123 may range between 7 and 11 inches. However, in other implementations, the canister 102 may be embodied with different dimensional values for the outer diameter 122 and the height 123, without departing from the scope of this disclosure. Additionally, the canister 102 may maintain a same aspect ratio between the outer diameter 122 and the height 123 as that depicted in, for example, FIG. 5. However, in another implementation, the canister 102 may be embodied with dimensions such that a different aspect ratio between the outer diameter 122 and the height 123 to that depicted FIG. 5 may be utilized. In yet another implementation, canister 102 may be configured with any external or internal dimensions, and such that the canister 102 may be configured to store any volume of liquid, without departing from the scope of the disclosure described herein. Additionally or alternatively, the container 100 may be configured to store materials in a liquid, a solid, or a gaseous state, or combinations thereof, without departing from the scope of the disclosure described herein.


Turning again to FIG. 1, in various examples, the canister 102 may comprise a first end 112 forming a base configured to support the canister 102 on an external surface. In one example, for the implementation of container 100 having a substantially cylindrical bottom portion 102 (canister 102), the first end 112 may have a substantially circular shape. The canister 102 may comprise a second end 114 having an opening 116 therein, as depicted in FIG. 3. Further, the first end 112 and the second end 114 may be separated by a curved sidewall 118 forming a substantially cylindrical shape of the canister 102. In one implementation, the opening 116 may be configured to allow a liquid to be introduced into, or removed from the canister 102. In another example, when the lid 104 is coupled to the canister 102, the opening 116 may be configured to allow a liquid stored in the canister 102 to flow into the lid 104 and out through the spout 110.


In one example, the spout opening 110 may be configured with an annular ridge 172. As such, the cap 108 may be configured to be removably-coupled to the spout 110 using an interference fit between the annular ridge 172 on a cylindrical outer wall 174 of the spout opening 110, and a corresponding ridge (not pictured in FIG. 1 or FIG. 2) on an inner surface 176 of the cap 108, as depicted in FIG. 2.



FIG. 3 depicts an exploded isometric view of another example container 300, according to one or more alternative aspects described herein. In one implementation, container 300 may be similar to container 100 from FIG. 1 and FIG. 2, where similar reference numerals represent similar features. In one example, container 300 may also comprise a lid 104 having a spout opening 310. However, the spout opening 310 may include a threaded outer wall 168 for receiving a correspondingly threaded inner wall of the cap 308. Specifically, as shown in FIGS. 3 and 4, the depicted cap 308 may be similar to the cap 108, but instead of utilizing an interference fit, the cap 308 may comprise a threaded inner wall 170 configured to be screwed onto a threaded cylindrical outer wall 168 of the spout opening 310.


In one example, the lid 104 may have a substantially cylindrical shape. In one implementation, the lid 104 may be configured to removably couple to a neck structure 120 of the canister 102. As such, the neck structure 120 may encircle the opening 116 in the canister 102, and extend out from the canister 102 in a substantially axial direction. In one implementation, an axial direction 302 associated with canister 102 may be parallel to an axis of rotation of a substantially cylindrical structure of canister 102, as depicted in FIG. 3. In one implementation, a radial direction 304 may be perpendicular to the axial direction 302. In various examples, lid 104 may have an opening 111 configured to receive the neck structure 120. Further details of a removable coupling between the lid 104 and the neck structure 120 are discussed in relation to FIG. 4.


In various examples, the canister 102 may be embodied with different geometries. For example, container 100 or container 300 may be embodied with a base portion, similar to canister 102, having a non-cylindrical shape. In particular, container 100 or container 300 may have a base, similar to canister 102, having a substantially cuboidal, spherical, or prismoidal shape, or combinations thereof, among others, without departing from the scope of the disclosures described herein. As such, container 100 or container 300 may have a base portion, similar to canister 102, having a non-cylindrical shape, but maintaining a substantially cylindrical neck structure 120, configured to be removably coupled to a substantially cylindrical lid 104. In yet another implementation, an opening, similar to opening 116, and a neck structure, similar to neck structure 120, may have non-circular geometries, without departing from the scope of the disclosures described herein. Additionally or alternatively, a lid of container 100 or container 300, similar to lid 104, may have a non-circular shape, without departing from the scope of the disclosures described herein. For example, a lid of container 100 or container 300, similar to lid 104, may have a substantially cuboidal, spherical, or prismoidal shape, or combinations thereof, among others, without departing from the scope of the disclosures described herein.



FIG. 4 depicts a cross-sectional view of one implementation of the container 300. In one example, the lid 104 may be removably coupled to the canister 102 using a threaded fastening mechanism. Accordingly, in one implementation, the neck structure 120 may have a smooth outer surface 160 and a threaded inner surface 162. In this way, the threaded inner surface 162 may be configured to interface with a threaded inner wall 164 of the lid 104. As such, when coupled to the canister 102, an outer wall 166 of the lid 104 may cover the neck structure 120.


Additional or alternative coupling mechanisms may be utilized to removably couple the lid 104 to the canister 102, without departing from the scope of the disclosures described herein. For example, the neck structure 120 may be embodied with a threaded outer surface (e.g. outer surface 320 may be threaded) and configured to interface with a corresponding threaded structure on the lid 104. In one example, this additional or alternative threaded structure on the lid 104 may be on an inside surface of the outer wall 166 (e.g. threads may be formed on inside surface 167 of the outer wall 166), among others.


In one example, a connection mechanism configured to removably couple the lid 104 to the canister 102 may be designed such that the coupling is fully engaged upon rotation of the lid 104 relative to the canister 102 by any number of revolutions, or by any fraction of a revolution. For example, the lid 104 may be fully engaged with the canister 102 upon placing the lid 104 on the neck structure 120, and rotating the lid 104 by approximately ¼ of one full revolution, approximately ⅓ of one full revolution, approximately ½ of one full revolution, approximately 1 full revolution, approximately 2 full revolutions, approximately 3 full revolutions, at least 1 revolution, or at least five revolutions, among many others.


In one implementation, a removable coupling between the lid 104 and the canister 102 may comprise one or more gaskets (e.g. gasket 169) configured to seal the coupling such that, in one example, liquid may not escape from the canister 102 while the removable coupling between the lid 104 and the canister 102 is engaged.


In one example the cap 308 may be fully engaged with the threaded fastening mechanism of the spout 310 by rotating the cap 308 relative to the spout 310 through an angle. For example, the cap 308 may be fully engaged with the spout 310 by rotating the cap 308 by approximately ¼ of one full revolution, approximately ⅓ of one full revolution, approximately ½ of one full revolution, approximately 1 full revolution, approximately 2 full revolutions, approximately 3 full revolutions, at least one revolution, or at least five revolutions, among many others.


In one implementation cap 108 (or cap 308) may seal the spout opening 110 (or spout opening 310) using one or more deformable gaskets structures that are compressed when the cap 108 (or cap 308) is brought into a removable coupling with the spout opening 110 (or spout opening 310). In one example, element 171 may be a gasket between the spout opening 310 and the cap 308.


In one implementation, containers 100 and 300 may include one or more insulating elements configured to reduce a rate of heat transfer to or from a material stored within the container. In one example, the canister 102 may be configured with a vacuum-sealed insulating structure, otherwise referred to as a vacuum-sealed double wall structure, or an insulated double wall structure, and such that a vacuum is maintained between an inner wall 178 and an outer wall 118 of the canister 102. In one implementation, a sealed vacuum cavity 180 may be sandwiched between the inner wall 178 and the outer wall 118. In other examples, specific implementations of insulating structures that utilize one or more vacuum chambers to reduce heat transfer by conduction, convection and/or radiation may be utilized within canister 102, without departing from the disclosures described herein. In another implementation, containers 100 and 300 may include an insulated double wall comprising an inner wall 178 and an outer wall 118. In one example, a cavity 180 between the inner wall 178 and the outer wall 118 may be filled with air to form an air pocket. In another example, the cavity 180 may be filled with an insulating material, such as an insulating foam (e.g. polystyrene).


In one example, the combination of the inner wall 178 and the outer wall 118 may be referred to as an insulated wall. In one implementation, the first end 112, the second end 114, the curved sidewall 118, and/or a shoulder region 126 (described in further detail in relation to FIG. 5) may comprise a vacuum-sealed insulated wall between the inner wall 178 and the outer wall 118. Further, an inner surface of one or more of the inner wall 178 or the outer wall 118 may comprise a silvered surface configured to reduce heat transfer by radiation.


In one implementation, canister 102 may comprise a concave structure 181 formed in the first end 112. In one example, the concave structure 181 may provide added rigidity to the first end 112, and such that the concave structure 181 reduces, or prevents, deformation of the first end 112 as a result of a vacuum within the vacuum cavity 180. Accordingly, the concave structure 181 may have any radius or multiple radii of curvature (i.e. the concave structure 181 may comprise a geometry having multiple radii of curvature), without departing from the scope of these disclosures.


In another implementation, the cavity 180 may be filled with an insulating material that exhibits low thermal conductivity. As such, the cavity 180 may, in one example, be filled with a polymer material, or a polymer foam material. In one specific example, the cavity 180 may be filled with polystyrene. However, additional or alternative insulating materials may be utilized to fill the cavity 180, without departing from the scope of these disclosures. In one example, a thickness of the cavity 180 may be embodied with any dimensional value, without departing from the scope of these disclosures.


In one example, the canister 102 may be constructed from one or more metals, alloys, polymers, ceramics, or fiber-reinforced materials. Additionally, canister 102 may be constructed using one or more hot or cold working processes (e.g. stamping, casting, molding, drilling, grinding, forging, among others). In one implementation, the canister 102 may be constructed using a stainless steel. In one specific example, the canister 102 may be formed substantially of 304 stainless steel. In one implementation, one or more cold working processes utilized to form the geometry of the canister 102 may result in the canister 102 being magnetic (may be attracted to a magnet).


In one example, and as depicted in FIG. 4, the lid 104 may be embodied with a cavity 182. As such, this cavity 182 may be formed between the top surface 128 and a bottom surface 184. In this way, the cavity 182 may provide further insulation to the container 300 by containing one or more of an air pocket, a vacuum-sealed cavity, or by containing a mass of an insulating material, among others. In one specific example, the cavity 182 may be filled with a polymer foam, such as polystyrene. However, additional or alternative insulating materials may be utilized to fill the cavity 182, without departing from the scope of these disclosures.



FIG. 5 depicts an end view of canister 102, which may be used with container 100 or container 300. Accordingly, canister 102 may have a first outer diameter 122 at the first end 112 and a second outer diameter 124 at the opening 116 of the canister 102. In one example, the second diameter 124 may be less than the first diameter 122, such that an outer diameter of the substantially cylindrical sidewall 118 tapers from the first outer diameter 122 to the second outer diameter 124 along a shoulder region 126. In one example, the shoulder region 126 may improve heat transfer performance of the canister 102 (reduce a rate of heat transfer) when compared to a container having a constant outer diameter between a first end, similar to first end 112, and a second end, similar to the second and 114. In particular, the first end 112, the curved sidewall 118 (otherwise referred to as the outer wall 118), and the shoulder region 126 may comprise insulation having lower thermal conductivity (higher thermal resistance/insulation) than the lid 104 that seals the opening 116. As such, a configuration of container 100 or container 300 having opening 116 with a smaller second diameter 124 than the first diameter 122 provides for an increased surface area having the comparatively higher performance insulation (lower thermal conductivity insulation).


In another implementation, having the second outer diameter 124 less than the first outer diameter 122 may increase the structural rigidity of the canister 102 at the second end 114, and such that the opening 116 may be less prone to undesirable warping/bending during one or more processes used to form the structure of the canister 102.


In another example, the container 100 should not be limited to having a first diameter 122 greater than a second diameter 124 such that an outer diameter of the substantially cylindrical sidewall 118 tapers from said first outer diameter 122 to said second outer diameter 124 along a shoulder region 126. As such, the canister 102 may have a substantially constant outer diameter (not pictured), and such that an opening, similar to opening 116, may have a diameter approximately equal to an outer diameter of a first end of the base, similar to the first end 112.



FIG. 6 schematically depicts an end view of container 300. In one implementation, the lid 104 may be configured with a circular domed (convex) top surface 128. In one implementation, the cap 308, when removed from the spout opening 310, may be positioned within a dimple 130, otherwise referred to as a recess structure 130 (depicted in the plan view of container 300 of FIG. 7). In one implementation, when positioned within the dimple 130, the cap 308 may be angled away from the spout 310, as schematically depicted in FIG. 6.


Additionally, FIG. 6 depicts the cap 308 removed from the spout 310 and positioned within the dimple 130. The spout 310 may have a central axis 132 corresponding to (parallel to) an axis of rotation associated with a substantially cylindrical structure of the spout opening 310. The central axis 132 may be perpendicular to an annular ridge 311 of the spout opening 310, similar to annular ridge 172 of the spout opening 110 from FIG. 2. In various examples, the dimple 130 may have a central axis 134 corresponding to (parallel to) an axis of rotation associated with a substantially circular structure of the dimple 130. The central axis 134 may be perpendicular to a planar surface 131 of the dimple 130.


In various examples, the spout 310 extends from the substantially convex geometry of the circular domed top surface 128 and has a central axis 132 which extends along a normal 132 relative to the domed top surface 128. The dimple 130 also includes a central axis 134 (which may be parallel to a central axis of cap 308, when positioned within dimple 130) and extends substantially along a normal 134 relative to the domed top surface 128, such that the spout 310 and the cap 308 may angled away from one another.


Advantageously, and in various examples, this relative positioning of the spout 310 and the cap 308 may allow for improved separation, such that the cap 308 is not contacted when a user is drinking from/pouring from the spout 310.


In one implementation, an angle between central axis 132 (otherwise referred to as normal 132) and central axis 134 (otherwise referred to as normal 134) is schematically depicted as angle 604. As such, angle 604 may be referred to as an intersection angle 604 between a central axis 132 of the spout 310 and a central axis 134 of the dimple 130. As such, angle 604 may be greater than approximately: 2°, 5°, 10°, 15°, 20°, 30°, 45°, 55°, 60°, 70°, 80°, 90°, 100°, or 110°, among others. In another implementation, angle 604 may range from 2 to 110 degrees, among others. Angle 602 schematically represents an angle between central axis 132 (normal 132) and a base surface of the container 300 (e.g. first end 112). In one example, angle 602 may be referred to as a tilt angle 602 between the central access 132 and a base surface of the container 300 (e.g. first end 112, or any plane parallel thereto). In this way, tilt angle 602 may be an angle of less than 90°. As such, in various examples angle 602 may be less than approximately: 90°, 85°, 80°, 70°, 60°, 45°, or 30°, among others. In another implementation, angle 602 may range from 30 to 90 degrees, among others. Similar to angle 602, angle 606 schematically represents an angle between central axis 134 (normal 134) and a base surface of the container 300 (e.g. first end 112, or any plane parallel thereto). As such, angle 606 may be referred to as tilt angle 606. In this way, tilt angle 606 may be an angle of less than 90°. In various examples, angle 606 may be less than approximately: 90°, 85°, 80°, 70°, 60°, 45°, or 30°, among others. In one implementation, angle 606 may range from 30 to 90 degrees, among others. In one example, angle 602 may be approximately equal to angle 606. However, in other examples, angle 602 may not be equal to 606.


In one implementation, the circular domed top surface 128 may have a radius of curvature equal to approximately 13.5 inches (342 mm). However, in other implementations, any radius of curvature may be utilized to form the convex geometry of the circular domed top surface 128, without departing from the scope of these disclosures. Additionally or alternatively, the circular domed top surface 128 may comprise multiple radii of curvature, without departing from the scope of this disclosure.


In another implementation, the lid 104 may be configured with other top surface geometries than that circular domed top surface 128 depicted in FIG. 6. For example, lid 104 may have a substantially planar, or a substantially concave top surface, among others (not pictured). Furthermore, one or more of axes 132 and 134 may, in other implementations, not be normal to the circular domed top surface 128. In yet another implementation, axes 132 and 134 may be parallel to one another.



FIG. 7 schematically depicts a plan view of the container 300. In one implementation, the dimple 130 may have a substantially circular geometry. In particular, the dimple 130 may have a concave geometry. Accordingly, a concave geometry of dimple 130 may be embodied with any radius of curvature, without departing from the scope of these disclosures. In another example, the dimple 130 may have a flat bottom (i.e. substantially planar) surface 131 connected to the circular domed top surface 128 by a sidewall 133. In one example, the sidewall 133 may be straight, chamfered, or filleted. As such, in one implementation, the dimple 130 may have an inner diameter 135, an outer diameter 137, and a depth 139 (see FIG. 6). For that implementation of dimple 130 having a straight sidewall 133 between surface 131 and surface 128, the inner diameter 135 may be approximately equal to the outer diameter 137.


In one specific example, the inner diameter 135 may measure approximately 25.5 mm, and the outer diameter 137 may measure approximately 29.4 mm. In another example, the inner diameter 135 may measure up to approximately 28 mm, and the outer diameter 137 may measure up to approximately 30 mm. In other examples, the inner diameter 135 and the outer diameter 137 may be embodied with any dimensions, without departing from the scope of these disclosures. In one implementation, the depth 139 of the dimple 130 may range from 1 mm or less to 5 mm or more. However, the depth 139 may be embodied with any value, without departing from the scope of this disclosure. Further, the sidewall 133, if chamfered, may be angled at any angular value between the surface 131 and the surface 128. Similarly, the sidewall 133, if filleted, may have any radius of curvature between the surface 131 and the surface 128.


In one implementation, the magnetic surface 131 may comprise a polymer outer layer over a ferromagnetic structure (i.e. a metal plate may be positioned below magnetic surface 131 in order for the magnetic surface 131 to attract a magnet embedded within a magnetic top surface 136 of the cap 308 (see FIG. 8). In another implementation, the magnetic surface 131 may comprise a polymer overmolded over a magnet structure (i.e. a magnet may be positioned within the lid 104 as it is being molded.


The term “magnetic,” as utilized herein, may refer to a material (e.g. a ferromagnetic material) that may be magnetized. As such, the term “magnetic” may imply that a material (i.e. a surface, or object, and the like) may be magnetically attracted to a magnet (i.e. a temporary or permanent magnet) that has an associated magnetic field. In one example, a magnetic material may be magnetized (i.e. may form a permanent magnet). Additionally, various examples of magnetic materials may be utilized with the disclosures described herein, including nickel, iron, and cobalt, and alloys thereof, among others.



FIG. 8 depicts a more detailed view of the cap 308. In particular, cap 308 may be configured with a substantially cylindrical geometry. In one implementation, the cap 308 may comprise a magnetic top surface 136. As such, the cap 308 may be configured to removably couple to, and seal, the spout 310. Further, upon manual removal of the cap 308 from the spout 310, the magnetic top surface 136 may be configured to magnetically couple to a magnetic surface 131 of the dimple 130, as depicted in FIG. 7. As such, the dimple 130 may comprise a magnetic material to which the magnetic top surface 136 may be magnetically attracted.


In one example, the cap 308 may be constructed from a polymer material, and formed using one or more injection molding processes. As such, the magnetic top surface 136 may comprise an overmolded permanent magnet. Various permanent magnet materials may be utilized with the magnetic top surface 136 of cap 308, without departing from the scope of the disclosures described herein. In one particular example, the magnetic top surface 136 may comprise a neodymium magnet of grade N30, among others.


Furthermore, various overmolding methodologies may be utilized to encapsulate a magnet within the cap 308, without departing from the scope of the disclosures described herein. In another example, the cap 308 may comprises a permanent magnet coupled below the polymeric magnetic top surface 136 such that the permanent magnet may be ultra-sonically welded, or glued onto a surface within the cap 308 (e.g. magnet 173 may be retained within the cap 308 by structure 175, which may comprise a polymer plate that is ultra-sonically welded, glued, or otherwise coupled to the cap 308.


Advantageously, a magnetic coupling between the magnetic top surface 136 of cap 308, and the magnetic surface 131 of dimple 130 may provide for fast, temporary storage of cap 308 while a liquid is being poured from container 300. In this way, a user may quickly affix cap 308 into dimple 130 such that cap 308 may not be set aside on an external surface where it may be misplaced or contaminated. Further advantageously, a magnetic coupling between the magnetic top surface 136 of the cap 308 and a magnetic surface 131 of the dimple 130 may encourage surfaces 136 and 131 to contact one another such that a bottom surface of cap 308 (e.g. bottom surface 186 of cap 108, which may be similar to 308) does not contact the magnetic surface 131 of the dimple 130. In this way one or more surfaces, including the bottom surface 186, of cap 108 or 308 may be exposed to fewer contaminants, and thereby reduce transmission of fewer contaminants to spout 310 upon re-coupling of the cap 308 with the spout 310. It is noted that the previously described advantages with regard to magnetically coupling the cap 308 into the dimple 130 may, additionally or alternatively, be realized with cap 108 from container 100.


In one example, cap 308 may comprise one or more polymer materials. However, cap 308 may comprise one or more of a metal, an alloy, a ceramic, or a wood material or combinations thereof, without departing from the scope of the disclosure described herein.


In one example, cap 308 may have a substantially cylindrical shape with a cylindrical outer wall 802. As such, cap 308 may be embodied with any outer diameter for the outer wall 802, without departing from the scope of this disclosure. In one example, cap 308 may have a surface 143 extending between the magnetic top surface 136 and a side surface 142. In one implementation, the surface 143 may form a chamfer between the top surface 136 and the side surface 142. As such, surface 143 may be embodied with any chamfer angle between the top surface 136 and the side surface 142. In another implementation, surface 143 may form a fillet between the top surface 136 on the side surface 142. As such, an example filleted surface 143 may be embodied with any desired fillet angle or radius. In one implementation, surface 143 may be utilized to center the cap 308 within the dimple 130. In one implementation, a fillet radius of surface 143 may be approximately equal to a fillet radius of surface (sidewall) 133 of the dimple 130. Similarly, and in another implementation, a chamfer angle of surface 143 may be approximately equal to a chamfer angle of surface (sidewall) 133 of dimple 130. In one example, the cap 308 may have lip structures 145 and/or 147 to facilitate manual gripping of the cap 308 to remove upon removal of the cap 308 from the spout 310 or the dimple 130, among others. In another implementation, the cap 308 may be implemented such that outer wall 802 has an outer diameter equal to the outer diameter of surface 142, and such that the cap 308 is not embodied with lip structures 145 and/or 147.


In one example, and as depicted in FIG. 11, the spout 310 (FIG. 11 depicts the cap 308 coupled to the spout 310) may be off-center on the circular domed top surface 128. In particular, the spout 310 may be positioned substantially at a perimeter of the circular domed top surface 128. Further, in one implementation, the recess 130 may be diametrically opposed to the spout opening 310, as depicted FIG. 7. However, the spout opening 310 may be positioned in other locations on the lid 104, without departing from the scope of the disclosure described herein. For example, the spout opening 310 may be positioned substantially at a center of the circular domed top surface 128. In another example, the spout opening 110 may be positioned on a curved sidewall of the lid 104, such as the curved sidewall 140 depicted in FIG. 11. In another example, the recess 130 may not be diametrically opposed to the spout opening 310. As such, in one example, the recess 130 may be positioned substantially at a center of the domed top surface 128, while the spout opening 310 may be positioned substantially at the perimeter of the circular domed top surface 128.


In one implementation, the lid 104, as depicted in FIG. 7, may be constructed from a polymeric material. In one example, the lid 104 may be injection molded. In one implementation, dimple 130 may comprise a ferromagnetic structure, or plate, that is overmolded to form the lid 104. In this way, upon manual removal of the cap 308 from the spout 310, the magnetic top surface 136 of the cap 308 may be magnetically attracted to the dimple structure 130 when positioned within a given proximity of the dimple structure 130. In another example, dimple 130 may comprise a ferromagnetic structure, or plate, that is positioned behind the surface 131 (e.g. glued, or ultra-sonically weleded or otherwise attached to an interior side of the lid 104 within the cavity 182).


In one example a force needed to remove the cap 308 from the dimple structure 130 (i.e. a force to overcome a magnetic attraction between the cap 308 and the dimple structure 130) may measure approximately 10 N. In another example, the force to remove cap 308 from the dimple structure 130 may range between approximately 7 and 15 N. In another implementation, magnetic top surface 136 may be magnetically coupled to the curved sidewall 118 of the canister 102. Accordingly, in one example, a force needed to overcome a magnetic attraction between the cap 308 and the curved sidewall 118 may measure approximately 3 N. In another example, the force to remove the cap 308 from the curved sidewall 118 may range between approximately 1 and 10 N.


In another implementation, there may be a specific distance/proximity within which magnetic attraction is exerted between the magnetic top surface 136 of the cap 308, and the ferromagnetic structure of the dimple 130. This proximity may be dependent upon a strength (magnetic field strength, and the like) of the magnet contained within the magnetic top surface 136, among other factors. As such, there may exist a proximity within which the magnetic top surface 136 of the cap 308 may be positioned relative to the dimple structure 130 in order to magnetically couple the two structures may be embodied with any distance value. This proximity may be embodied with any value, without departing from the scope of the disclosures described herein. Accordingly, any strength of magnet may be utilized with the disclosures described herein. Additionally, various ferromagnetic materials may be utilized within the dimple structure 130, without departing from the disclosures described herein.


In another example, a ferromagnetic material may be positioned within the dimple structure 130, and such that that an overmolding process is not utilized to cover the ferromagnetic material. Similarly, a magnet may be positioned on the magnetic top surface 136 of the cap 308, and such that the magnet is exposed, rather than being overmolded or covered.


In various examples, the container 300 may be configured such that the magnetic top surface 136 of the cap 308 is configured to magnetically couple only within the recess 130. As such, the remainder of container 300 may be constructed using one or more non-magnetic materials. In another example, a magnetic top surface 136 of the cap 308 may be configured to magnetically couple to one of a plurality of locations on the lid 104. In particular, in one example, the circular domed top surface 128 of the lid 104 may comprise a plurality of overmolded ferromagnetic pieces configured to magnetically couple to the magnetic top surface 136 of the cap 308. In another example, the lid 104 may be constructed using, or coated with, a metallic material that may be attracted to a magnetic field.


In various examples, container 300 may be configured such that the magnetic top surface 136 of the cap 308 may be configured to magnetically couple to the spout 310 (i.e. spout 310 may be embodied with one or more ferromagnetic materials). Accordingly, the opening into the canister 102 through the spout opening 310 may be sealed by magnetic attraction of the cap 308 to the spout opening 310.


In various examples, cap 308 may be attached within dimple 130 using another coupling mechanism in addition to, or as an alternative to, the magnetic metric coupling between the magnetic top surface 136 and surface 131. For example, the top surface 136 and surface 131 may be embodied with complementary threaded coupling elements, interference fit coupling elements (i.e. snap coupling), or hook and loop coupling elements, among others.


Additionally or alternatively, the canister 102 may comprise a magnetic material, such that the magnetic top surface 136 may be magnetically coupled to a surface (e.g. the curved sidewall 118) of the canister 102. In one particular example, the canister 102 may comprise a stainless steel material (e.g. 304 stainless steel), and may be magnetized by a one or more cold working processes used to form the various geometries of the canister 102. However, the canister 102, and indeed any of the structures of container 300 described herein, may be constructed using one or more of a metal, an alloy, a polymer, a ceramic, a wood material, or combinations thereof.


In various examples, the recess 130 may comprise an overmolded, or otherwise covered, permanent magnet, and the magnetic top surface 136 of the cap 308 may comprise an overmolded ferromagnetic material (e.g. iron). In yet another example, both of the magnetic top surface 136 and the recess structure 130 may comprise overmolded, or otherwise covered, permanent magnets configured to attract one another, and the like.


In one example, the cap 308 may comprise a substantially planar magnetic top surface 136. In this way, the substantially planar magnetic top surface 136 may be configured to interface with a substantially planar surface of the recess 130. In another example, a cap 308 may be configured with different geometries. For example, the cap 308 may comprise a curved top surface 136. In another example, FIG. 9 depicts a cap 908 having a magnetic channel structure 138 (rounded surface 138) configured to allow the cap 908 to be magnetically coupled to a curved surface. In one implementation, the magnetic channel structure 138 may be configured to magnetically couple to one or more curved surfaces of the carry handle structure 106. In this way, the carry handle structure 106 may be configured with one or more magnetic materials (overmolded, covered, or exposed magnetic materials). In one implementation, one or more portions of the carry handle structure 106 may comprise a magnet and such that one or more portions of the carry handle structure 106 may be magnetically attracted to, and held in position when brought into contact with, sidewall 118. In yet another example, the magnetic channel structure 138 may have a concave geometry configured to conform to a curved surface geometry of a curved sidewall 118 of the canister 102. As such, the magnetic channel structure 138 may comprise one or more overmolded, or otherwise covered, permanent magnet structures, similar to the magnetic top surface 136 of cap 308 depicted in FIG. 8.


In one implementation, the cap 308 may be embodied with additional or alternative features. For example, and as depicted in FIG. 10, the cap 308 may be embodied with a tether 144 connected between a first anchor point 146 on the cap 308 and a second anchor point 148 on the lid 104. The first anchor point 146 and the second anchor point 148 can be in the form of U-shaped connectors that are either separately fastened or integrally molded. Advantageously, the tether 144 may be utilized to prevent separation of the cap 108 and the lid 104, and may be utilized in combination with a magnetic coupling between a magnetic top surface 136 and a recess 130, such that the magnetic coupling prevents the cap 108 from falling into a stream of liquid being poured from the spout 310, among others. As such, the tether 144 may comprise any flexible material, such as a polymer, a metal, or an alloy, among others, and may be embodied with any length. Similarly, the first anchor point 146 and the second anchor point 148 may be positioned at different locations on the cap 308 and the lid 104, respectively, without departing from the scope of the disclosures described herein.



FIG. 11 depicts a more detailed view of a hinged coupling between the carry handle structure 106 and the lid 104. In particular, a rotatable coupling between the carry handle structure 106 and the lid 104 may be facilitated by fastener 150. In one implementation, fastener 150 may act as a bearing about which the carry handle structure 106 may rotate relative to the lid 104. In one implementation, fastener 150 may comprise a screw configured to be received into a recess in the curved sidewall 140 of the lid 104. However, additional or alternative fastening mechanisms that may be utilized to hingedly couple the carry handle structure 106 to the lid 104, without departing from the scope of the disclosures described herein.



FIG. 12 depicts an implementation of a container 1200. Accordingly, container 1200 may be similar to containers 100 and 300, and may, additionally, be embodied with a hook structure 152 rigidly coupled to the carry handle structure 106. As such, the hook structure 152 may be configured to allow the container to be hung from an external structure (e.g. a chain-link fence, similar to fence 156 from FIG. 13, among many others). As depicted in FIG. 12, the hook structure 152 may be positioned at one side of the carry handle structure 106. However, alternative configurations for the hook structure 152 may be utilized without departing from the scope of the disclosures described herein. For example, container 1200 may be embodied with two or more hook structures (e.g. one hook structure to either side of the carry handle structure 106).


In one implementation, the hook structure 152 may be angled at an angle 1202. In one specific example, angle 1202 may range be range from approximately 20° to approximately 75°. However, additional or alternative implementations of the hook structure 152 may be utilized, including an angle 1202 outside of the range of 20° to 75°, without departing from the scope of these disclosures.



FIG. 13 depicts another example implementation of a container 1300. Accordingly, container 1300 may be similar to containers 100, 300, and 1200 where similar reference numerals represent similar components and features. In this example implementation, container 1300 may have a hook structure 154, which may be positioned as a center of a grip structure 158 of the carry handle structure 106, and such that the container 100 may be hung from a chain-link fence 156, among others. Accordingly, hook structure 152 and hook structure 154 may be constructed from one or more metals, alloys, or polymers, without parting from the scope of the disclosures described herein.


According to one aspect, an insulating container may have a canister that has an insulated double wall with a first end to support the canister on a surface, a second end, and a sidewall. The canister may also have an opening in the second end that extends through the insulated double wall. A neck structure may encircle the opening and extend in an axial direction. A lid may seal the opening by receiving the neck structure into a corresponding opening in the lid. The lid may further have a circular domed top surface having a spout opening, and a removable cap that seals the spout opening. Further, the cap may have a magnetic top surface configured to be magnetically attracted to, and retained within, a dimple on the domed top surface.


According to another aspect, a container may have a bottom portion with a first end, a second end having an opening, and a cylindrical wall spaced between the first and the second end. The bottom portion may taper from a first outer diameter at the first end, to a second, smaller outer diameter at the second end. The bottom portion may further have a neck structure around the opening. Additionally, the container may have a lid that seals the opening, the lid further having an opening to receive the neck structure. A top surface of the lid may have a spout opening, and a removable cylindrical cap that seals the spout opening. The removable cylindrical cap may have a magnetic top surface. Additionally, the top surface may have a recess with a magnetic surface that magnetically couples to the magnetic top surface of the cylindrical cap when removed from the spout.


In yet another aspect, a container may have an insulated base structure with a cylindrical shape and an opening in one end. The container may also have a lid with a bottom surface that seals the insulated base structure. A top surface of the lid may have a spout, and a cap that removably couples to, and seals, the spout. The cap may have a magnetic top surface. Additionally, the lid may have at least one ferromagnetic piece, and a carry handle. Further, a tilt angle between a central axis of the spout and the bottom surface of the lid may be less than 90°.



FIG. 14 depicts another implementation of a container 1400, according to one or more aspects described herein. In one example, container 1400 may comprise a bottom portion 1402 having a lid 1404 removably-coupled thereto. Further, the bottom portion 1402 may be referred to as a canister, base, or insulated base structure that has a substantially cylindrical shape, among others. Carry handle 106 may be rotatably-coupled to the lid 1404. Additionally, the lid 1404 may comprise a cap 1406 that is configured to removably-coupled to, and resealably seal a spout opening 1408 (as depicted in FIG. 15) of the lid 1404.


In various examples, the cap 1406 may have a substantially cylindrical side wall 1410 separated from a substantially circular magnetic top surface 1412 by a chamfered surface 1414, as depicted in FIG. 14. Accordingly, the chamfered surface 1414 may be similar to surface 143, as depicted FIG. 8. As such, the chamfered surface 1414 may be configured to center the magnetic top surface 1412 of the cap 1406 within the dimple/depression 1416 (as depicted in FIG. 15). In this way, the dimple 1416 may have complementary geometry configured to receive the magnetic top surface 1412 and chamfered surface 1414 of cap 1406.



FIG. 15 depicts a cross-sectional view of container 1400. Accordingly, the bottom portion 1402 may comprise a concave structure 1418, similar to concave structure 181 of bottom portion 102. Further, the bottom portion 1402 may have an insulated double wall structure comprising an inner wall 1420 and an outer wall 1422. As such, a sealed vacuum cavity 1424, similar to vacuum cavity 180, may be positioned between the inner wall 1420 and the outer wall 1422. In other implementations, the cavity 1424 may be filled with one or more insulating materials.


In one implementation, the lid 1404 is configured to resealably seal an opening 1401 in the bottom portion 1402. Accordingly, a threaded wall 1426 of the lid 1404 may be received by a threaded sidewall 1428 of the bottom portion 1402 to removably-couple the lid 1404 to the bottom portion 1402.


In various implementations, the bottom portion 1402 may have a neck structure 1430, and such that the threaded sidewall 1426 extends into the bottom portion 1402 to a depth 1432, greater than a height 1434 of the neck structure 1430. As such, the threaded sidewall 1428 may be configured to receive the threaded sidewall 1426 such that the neck structure 1430 abuts/is positioned proximate an outer wall 1445 of the lid 1404 at end 1447.


The spout opening 1408 may be embodied with a threaded sidewall 1440 configured to receive a threaded sidewall 1442 of cap 1406 to removably-couple the cap 1406 to the lid 1404.


A magnetic material 1444, such as, among others, a ferromagnetic plate that is not magnetized, or a permanent magnet, may be positioned below the magnetic top surface 1412 of the cap 1406. In this way, magnetic material 1444 may be similar to magnet 173 from FIG. 4. Similarly, a magnetic material 1446 may be positioned below the dimple 1416. As such, dimple 1416 may be similar to dimple 130.


In addition to the various elements described in relation to container 1400 and depicted in FIG. 14 and FIG. 15, container 1400 may comprise one or more additional or alternative elements described in relation to containers 100 or 300, without departing from the scope of these disclosures.


The present disclosure is disclosed above and in the accompanying drawings with reference to a variety of examples. The purpose served by the disclosure, however, is to provide examples of the various features and concepts related to the disclosure, not to limit the scope of the invention. One skilled in the relevant art will recognize that numerous variations and modifications may be made to the examples described above without departing from the scope of the present disclosure.

Claims
  • 1. An insulating container, comprising: a canister comprising: an insulated double wall structure comprising: a first end, configured to support the canister on a surface;a second end; anda sidewall;an opening in the second end extending through the insulated double wall structure; anda neck structure encircling the opening and extending in an axial direction;a lid adapted to seal the opening, the lid comprising: a threaded sidewall configured to be received into the neck structure;a top surface, further comprising: a spout that is off-centered on the top surface;a removable, cylindrical cap adapted to resealably seal the spout, and comprising a magnetic top surface;a depression structure positioned off-center on the top surface, diametrically opposed to the spout, and recessed relative to the top surface, the depression structure further comprising an outer diameter at the top surface and an inner diameter, less than the outer diameter, at a magnetic surface of the depression structure onto which the magnetic top surface of the cylindrical cap is magnetically attracted and retained when the cylindrical cap is manually removed from the spout and positioned within a proximity of the depression structure;a sealed cavity spaced between the top surface and a bottom surface of the lid, wherein the spout extends through the sealed cavity between the top surface and the bottom surface of the lid; anda carry handle, rotatably coupled to a cylindrical sidewall of the lid, wherein the carry handle further comprises a cylindrical grip structure.
  • 2. The insulating container of claim 1, wherein an intersection angle between a central axis of the spout and a central axis of the depression structure is between 5 and 20 degrees.
  • 3. The insulating container of claim 1, wherein the magnetic surface of the depression structure comprises a permanent magnet.
  • 4. The insulating container of claim 1, wherein the magnetic top surface of the cylindrical cap comprises a permanent magnet.
  • 5. The insulating container of claim 1, wherein the cylindrical cap is magnetically attracted to and retained within the depression structure with the magnetic top surface in contact with the magnetic surface of the depression structure.
  • 6. The insulating container of claim 1, wherein the cylindrical cap is configured to seal the spout with an interference fit between an annular ridge on a cylindrical outer wall of the spout and a corresponding ridge on an inner surface of the cylindrical cap.
  • 7. The insulating container of claim 1, wherein the spout further comprises a threaded cylindrical outer wall configured to interface with a threaded inner surface of the cylindrical cap.
  • 8. The insulating container of claim 1, wherein a first opening of the lid comprises a threaded inner wall configured to screw onto a threaded inner surface of the neck structure.
  • 9. The insulating container of claim 1, wherein the insulated double wall structure comprises a sealed vacuum cavity between an inner wall and an outer wall.
  • 10. The insulating container of claim 1, further comprising a chamfered sidewall connecting the magnetic surface of the depression to the top surface of the lid.
  • 11. The insulating container of claim 1, further comprising a filleted sidewall connecting the magnetic surface of the depression to the top surface of the lid.
  • 12. A container, comprising: a bottom portion, further comprising: a first end configured to support the container on a surface, wherein the first end has a first outer diameter;a second end having an opening, wherein the opening has a second outer diameter smaller than the first outer diameter;a cylindrical wall spaced between the first end and the second end, wherein an outer diameter of the cylindrical wall tapers from the first outer diameter to the second outer diameter along a shoulder region of the cylindrical wall;a neck structure encircling the opening and extending in an axial direction;a lid adapted to resealably seal the opening, the lid further comprising: a threaded sidewall configured to be received into the neck structure;a top surface, further comprising: a spout opening;a removable, cylindrical cap adapted to resealably seal the spout opening and having a magnetic top surface; anda recess having a magnetic surface adapted to receive, and magnetically couple to, the magnetic top surface of the cylindrical cap when the cylindrical cap is manually removed from the spout opening, the recess further comprising an outer diameter at the top surface and an inner diameter, less than the outer diameter, at a flat-bottomed magnetic surface of the recess;a sealed cavity spaced between the top surface and a bottom surface of the lid, wherein the spout extends through the sealed cavity between the top surface and the bottom surface of the lid; anda carry handle, rotatably coupled to a cylindrical sidewall of the lid, wherein the carry handle further comprises a cylindrical grip structure.
  • 13. The container of claim 12, wherein a ferromagnetic plate is positioned below the recess.
  • 14. The container of claim 12, wherein the carry handle comprises a ferromagnetic material configured to optionally magnetically couple to the magnetic top surface of the cylindrical cap.
  • 15. The container of claim 12, wherein the magnetic top surface comprises a permanent magnet.
  • 16. The container of claim 12, further comprising a chamfered sidewall connecting the flat-bottomed magnetic surface to the top surface of the lid.
  • 17. The container of claim 12, further comprising a filleted sidewall connecting the flat-bottomed magnetic surface to the top surface of the lid.
  • 18. The container of claim 12, wherein the recess is positioned off-center on the top surface, diametrically opposed to the spout opening.
CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 14/826,612, filed Aug. 14, 2015, which is incorporated herein by reference in its entirety for any and all non-limiting purposes.

US Referenced Citations (483)
Number Name Date Kind
1002983 Geoghegan Sep 1911 A
1004059 Means Sep 1911 A
1008698 Coulston Nov 1911 A
1018379 Seward Feb 1912 A
1018961 Coffield Feb 1912 A
1196492 Sykes Aug 1916 A
1477936 Bott Dec 1923 A
D101575 Windbiel Oct 1936 S
D109331 McManus et al. Apr 1938 S
D154378 Fuller Jul 1949 S
2735566 Bramming Feb 1956 A
D177761 Reinhardt May 1956 S
2804103 Wall Aug 1957 A
2881776 Wrage Apr 1959 A
2957596 Rehborg Oct 1960 A
2963187 Bramming Dec 1960 A
3089603 Leslie-Smith May 1963 A
3140799 Mehr Jul 1964 A
3141586 Wetterek Jul 1964 A
3220695 Downey et al. Nov 1965 A
3239090 Bramming Mar 1966 A
3249268 Neuner May 1966 A
3285453 Wagner Nov 1966 A
3307752 Anderson Mar 1967 A
3439843 Corsette Apr 1969 A
3456840 McAlaster Jul 1969 A
3470929 Thornton Oct 1969 A
3592349 Baugh Jul 1971 A
3638821 Guala Feb 1972 A
D224646 Vollquartz Aug 1972 S
3752347 Bell Aug 1973 A
3776433 De Treitas Dec 1973 A
3785539 Wetterek Jan 1974 A
3842790 Clark Oct 1974 A
3863798 Kurihara et al. Feb 1975 A
3874541 Lagneaux et al. Apr 1975 A
D235303 Boucher Jun 1975 S
D248373 Allen Jul 1978 S
4190173 Mason et al. Feb 1980 A
D256651 Leung et al. Sep 1980 S
4358024 Underwood Nov 1982 A
4497422 Klees Feb 1985 A
D279346 Ruxton Jun 1985 S
D281567 Zimmermann Dec 1985 S
D286604 Bierlein et al. Nov 1986 S
D286847 Zimmermann Nov 1986 S
D287211 Weiss Dec 1986 S
D289614 Sanchez et al. May 1987 S
D292492 Ross et al. Oct 1987 S
4723677 Nagel, Jr. Feb 1988 A
4981233 Scheurer Jan 1991 A
D321628 Kobayashi et al. Nov 1991 S
D325167 Humfress Apr 1992 S
5105975 Patterson Apr 1992 A
D329809 Bloomfield Sep 1992 S
D332379 Murphy Jan 1993 S
5190178 Luch Mar 1993 A
5211299 Manfredonia May 1993 A
5232112 Howard Aug 1993 A
5249703 Karp Oct 1993 A
5251788 Moore Oct 1993 A
D354915 Schneider et al. Jan 1995 S
5392967 Satomi et al. Feb 1995 A
D361265 Doxey Aug 1995 S
5490622 Tardif Feb 1996 A
D368224 Arndt Mar 1996 S
5498333 Canther Mar 1996 A
D370629 Lynch Jun 1996 S
5605241 Imperioli Feb 1997 A
D384280 Kuczer Sep 1997 S
D398193 Sanchez Sep 1998 S
5813557 Oratz Sep 1998 A
5839611 Obadia et al. Nov 1998 A
D402510 Miller Dec 1998 S
D405642 Toriba Feb 1999 S
D405650 Meier Feb 1999 S
D407211 Diviak, Sr. Mar 1999 S
D407273 Moran Mar 1999 S
D410175 Moran May 1999 S
5909820 Yeh Jun 1999 A
D415395 Hunt et al. Oct 1999 S
D415936 Moran Nov 1999 S
D422916 Herrmann Apr 2000 S
6079589 Matsuyama et al. Jun 2000 A
6102227 Cochrane Aug 2000 A
6102244 Kuwano et al. Aug 2000 A
D437528 Kitamura et al. Feb 2001 S
6264072 Johannes Jul 2001 B1
D447410 Malmborg Sep 2001 S
6321924 Yurkewicz et al. Nov 2001 B1
6332557 Moran Dec 2001 B1
6357628 Long, Jr. Mar 2002 B1
D456669 Munari May 2002 S
D458133 Berish et al. Jun 2002 S
D458134 Berish et al. Jun 2002 S
D466814 Hurlburt Dec 2002 S
6530496 Moran Mar 2003 B2
6536618 Hwang et al. Mar 2003 B1
D475924 Haffner Jun 2003 S
D476890 Hirose Jul 2003 S
6601740 Clive Aug 2003 B1
D479800 McRae Sep 2003 S
D479995 Duceppe Sep 2003 S
D482607 McRae Nov 2003 S
6648158 Lawrence Nov 2003 B1
6651838 Bissell Nov 2003 B2
6662978 Lin et al. Dec 2003 B2
6675998 Forsman et al. Jan 2004 B2
6702138 Bielecki et al. Mar 2004 B1
D490275 Moran May 2004 S
D494064 Hook Aug 2004 S
D494425 Segura Aug 2004 S
6908015 Choi et al. Jun 2005 B2
D507495 Williams et al. Jul 2005 S
D511457 Biesecker et al. Nov 2005 S
D521314 Ball May 2006 S
D524909 Bakke et al. Jul 2006 S
D525518 Baldwin Jul 2006 S
D530141 Wilgus et al. Oct 2006 S
D533032 Liu et al. Dec 2006 S
D536929 Kingsley Feb 2007 S
D536974 Smith et al. Feb 2007 S
7172101 Find Feb 2007 B2
D537714 Yerby et al. Mar 2007 S
D540625 Sandberg Apr 2007 S
D548006 Lapsker Aug 2007 S
D548082 Kingsley Aug 2007 S
D549444 Schnackenberg Aug 2007 S
7270244 Liu Sep 2007 B1
D553914 Wahl Oct 2007 S
D554000 Walsh Oct 2007 S
D557994 Wahl Dec 2007 S
D564363 Rhea Mar 2008 S
D567007 Bodum Apr 2008 S
D567021 Bach et al. Apr 2008 S
D569195 Kim May 2008 S
D572585 Perrin et al. Jul 2008 S
D574237 Yates, III Aug 2008 S
D581211 Lapsker Nov 2008 S
D582206 Fuller Dec 2008 S
D583200 Moran Dec 2008 S
7458486 Weist et al. Dec 2008 B2
D584623 Chupak Jan 2009 S
D586183 Junket Feb 2009 S
D587533 Carreno Mar 2009 S
D589348 Miller et al. Mar 2009 S
D594346 Mouquet Jun 2009 S
D599616 Cresswell et al. Sep 2009 S
D601436 Stephens et al. Oct 2009 S
D603331 Schupp Nov 2009 S
D603722 Reimer Nov 2009 S
D604181 Reimer Nov 2009 S
D604561 Chisholm Nov 2009 S
D605040 Fry et al. Dec 2009 S
D605060 Reimer Dec 2009 S
D605942 Miksovsky Dec 2009 S
D610871 Alviar et al. Mar 2010 S
D611346 Camomile Mar 2010 S
D612197 Chan Mar 2010 S
D612235 Cresswell et al. Mar 2010 S
D612660 Bodum Mar 2010 S
D614918 Chisholm May 2010 S
D614955 Cresswell et al. May 2010 S
D615360 Joy et al. May 2010 S
D615361 Goble May 2010 S
D615816 Joy et al. May 2010 S
D616703 Joy et al. Jun 2010 S
D616743 Cresswell et al. Jun 2010 S
D616744 Cresswell et al. Jun 2010 S
D619457 Walsh Jul 2010 S
D619458 Walsh Jul 2010 S
D619459 Walsh Jul 2010 S
D620798 Cresswell et al. Aug 2010 S
D621207 Bodum Aug 2010 S
D621257 Gullickson et al. Aug 2010 S
D621258 Gullickson et al. Aug 2010 S
D621648 Lown et al. Aug 2010 S
D622089 Daniel et al. Aug 2010 S
D622145 Walsh Aug 2010 S
D623475 Aarnoudse et al. Sep 2010 S
D623480 Moran Sep 2010 S
D623481 Moran Sep 2010 S
D625560 Olson et al. Oct 2010 S
D626414 Cresswell et al. Nov 2010 S
D626416 Cresswell et al. Nov 2010 S
D627601 Eyal Nov 2010 S
D627602 Eyal Nov 2010 S
D627604 Eyal Nov 2010 S
D628018 Gilbert Nov 2010 S
D628486 Lane Dec 2010 S
D628898 Barnett et al. Dec 2010 S
D628900 Barnett et al. Dec 2010 S
D628901 Barnett et al. Dec 2010 S
D629689 Cresswell et al. Dec 2010 S
D629690 Cresswell et al. Dec 2010 S
D629691 Cresswell et al. Dec 2010 S
D630474 Gilbert Jan 2011 S
D630475 Lu Jan 2011 S
D631349 Arnell et al. Jan 2011 S
7870968 Hanson Jan 2011 B2
D631666 Lim et al. Feb 2011 S
D633338 Rosbach et al. Mar 2011 S
D633794 Cresswell et al. Mar 2011 S
D633795 Cresswell et al. Mar 2011 S
D633796 Cresswell et al. Mar 2011 S
D633797 Cresswell et al. Mar 2011 S
D634156 Fuller et al. Mar 2011 S
D634160 Cetera Mar 2011 S
D635457 Lane Apr 2011 S
D635856 Lauret Apr 2011 S
D638695 Woodrow et al. May 2011 S
D638708 Walsh May 2011 S
D639164 Walsh Jun 2011 S
D639177 Pape Jun 2011 S
D639661 Llerena Jun 2011 S
D639663 Llerena Jun 2011 S
D640466 Staton Jun 2011 S
D641257 Thiebaut et al. Jul 2011 S
D641591 Tsukida Jul 2011 S
D643691 Selina et al. Aug 2011 S
D643693 Jama Aug 2011 S
D645709 Endo Sep 2011 S
8011535 Tauber et al. Sep 2011 B2
D648984 Gullickson et al. Nov 2011 S
D651050 Goshi Dec 2011 S
D651847 Gilbert Jan 2012 S
D652255 Carland Jan 2012 S
D652682 Eyal Jan 2012 S
D653499 Dietterle et al. Feb 2012 S
D654762 Gilbert Feb 2012 S
D655134 Gilbert Mar 2012 S
D655581 Kotani Mar 2012 S
D657196 Beyers, III Apr 2012 S
D658064 Barnes et al. Apr 2012 S
D658445 Carreno May 2012 S
D659007 Pape May 2012 S
D660084 Gilbert May 2012 S
8177097 Duran May 2012 B2
D662360 George Jun 2012 S
8210572 Davis Jul 2012 B2
8215511 Lin Jul 2012 B1
D664809 Eyal Aug 2012 S
D665621 Eyal Aug 2012 S
8245600 Beard Aug 2012 B2
8245870 McKinney et al. Aug 2012 B2
8251247 Breckner Aug 2012 B1
D666908 Dabah et al. Sep 2012 S
8256631 Hoffmann et al. Sep 2012 B2
8272532 Michaelian et al. Sep 2012 B2
D668913 Mayer Oct 2012 S
8292133 Baughman et al. Oct 2012 B2
D670137 Gilbert Nov 2012 S
D671372 Zou Nov 2012 S
D672238 Aziz et al. Dec 2012 S
D672609 Aziz et al. Dec 2012 S
D673459 Moran, Sr. Jan 2013 S
D675100 Herbst Jan 2013 S
D675865 Wahl Feb 2013 S
D676706 Kern et al. Feb 2013 S
D676764 Moore et al. Feb 2013 S
D677103 Melzer Mar 2013 S
D677119 Ying Mar 2013 S
D678729 Peeters et al. Mar 2013 S
D678772 Johnson et al. Mar 2013 S
D679185 Brown et al. Apr 2013 S
D680389 Zemel et al. Apr 2013 S
D682016 Knight May 2013 S
D682617 Miksovsky et al. May 2013 S
8443993 Desselle May 2013 B1
8443994 Desselle May 2013 B1
D684059 Johnson et al. Jun 2013 S
8459468 Lin Jun 2013 B2
D686078 Johnson et al. Jul 2013 S
D688093 Roth et al. Aug 2013 S
8505760 Ott Aug 2013 B2
8505787 Fox et al. Aug 2013 B2
D690987 Gallen Oct 2013 S
D690988 Audette Oct 2013 S
D691848 Trudeau et al. Oct 2013 S
8550269 Lane Oct 2013 B2
D693628 Tavenner et al. Nov 2013 S
D693698 Miller, Jr. Nov 2013 S
8584902 Dejonge Nov 2013 B2
D695138 Ball Dec 2013 S
8613369 Kitto Dec 2013 B2
D696945 Newman Jan 2014 S
D697404 Johnson et al. Jan 2014 S
D697802 Lane Jan 2014 S
8622229 Lane Jan 2014 B2
D698668 Vaughn Feb 2014 S
D701464 Ogata et al. Mar 2014 S
D702092 Mettler et al. Apr 2014 S
D702506 Mettler et al. Apr 2014 S
8695822 Kwon Apr 2014 B2
8701881 Gibson et al. Apr 2014 B2
8701924 Dalbec Apr 2014 B2
8708176 Andis Apr 2014 B2
D703998 Funnell, II et al. May 2014 S
8720730 Bodden, Jr. May 2014 B2
8752720 Habig et al. Jun 2014 B1
D708484 Bishop Jul 2014 S
D708914 Moran, Sr. Jul 2014 S
D708954 Barnes et al. Jul 2014 S
D709734 Kotani Jul 2014 S
8777031 Aneas Jul 2014 B2
D712254 Geis et al. Sep 2014 S
D712255 Geis et al. Sep 2014 S
D713268 Jones et al. Sep 2014 S
D713365 Green Sep 2014 S
8833586 Meyers et al. Sep 2014 B2
D714584 Boroski Oct 2014 S
D717102 Taketani et al. Nov 2014 S
D717601 Dixon Nov 2014 S
D719780 Sullivan Dec 2014 S
8905252 Latham et al. Dec 2014 B2
D724385 Hurley et al. Mar 2015 S
D724435 Kaufman et al. Mar 2015 S
8967414 Lane Mar 2015 B2
8985406 Tachi Mar 2015 B2
D728315 Bo May 2015 S
D728995 Barberi May 2015 S
D729579 Molayem May 2015 S
D729584 Weston et al. May 2015 S
D732402 Jones et al. Jun 2015 S
D734154 Johnson et al. Jul 2015 S
D734638 Wahl Jul 2015 S
D735033 Lynd et al. Jul 2015 S
D735038 Tamarindo Jul 2015 S
D735578 Mazurkiewicz et al. Aug 2015 S
9113698 Blain et al. Aug 2015 B2
9126731 Chen Sep 2015 B2
D741655 Whelan et al. Oct 2015 S
D743255 Niggemyer Nov 2015 S
D743742 Rummel et al. Nov 2015 S
D744781 Rummel et al. Dec 2015 S
9205445 Fang et al. Dec 2015 B2
9215942 Bodum Dec 2015 B2
D748472 Seybel et al. Feb 2016 S
D748955 Oliver Feb 2016 S
D751345 Lane et al. Mar 2016 S
D751399 Lynd et al. Mar 2016 S
D751898 D'Anglade Mar 2016 S
9272822 Samartgis Mar 2016 B2
D754472 Munari Apr 2016 S
D755561 Eyal May 2016 S
D757543 Sorensen et al. May 2016 S
9346591 Martinengo May 2016 B2
D758136 Liotta et al. Jun 2016 S
D758790 Boroski Jun 2016 S
D758791 Hanna et al. Jun 2016 S
D758804 Liotta et al. Jun 2016 S
D758859 Sorensen et al. Jun 2016 S
D759487 Jayakaran Jun 2016 S
9376243 Cerveny Jun 2016 B2
D760586 Seiders et al. Jul 2016 S
D761624 McLean et al. Jul 2016 S
D762418 Sorensen et al. Aug 2016 S
D763076 Lane et al. Aug 2016 S
D764916 Mount, III et al. Aug 2016 S
D767390 Miksovsky et al. Sep 2016 S
D772021 Joy Nov 2016 S
D772652 Yao Nov 2016 S
D772718 Lee Nov 2016 S
9493274 Ledun et al. Nov 2016 B2
9493283 Tuyn Nov 2016 B2
D773250 Miller Dec 2016 S
D773938 Weber Dec 2016 S
D774826 Boroski Dec 2016 S
9522770 Pichrt Dec 2016 B2
9532671 Lin Jan 2017 B2
D778117 Du Feb 2017 S
D778118 Du Feb 2017 S
D778725 Sorensen et al. Feb 2017 S
9586733 Garza Mar 2017 B2
D784812 Miller Apr 2017 S
D786012 Hein et al. May 2017 S
D787893 Seiders et al. May 2017 S
D790913 Stover et al. Jul 2017 S
D791542 Miksovsky et al. Jul 2017 S
D792765 Buck Jul 2017 S
9694953 Meyers et al. Jul 2017 B2
9708108 Gregory et al. Jul 2017 B2
D795008 Eyal Aug 2017 S
9745110 Boyer et al. Aug 2017 B2
9771189 Miksovsky et al. Sep 2017 B2
D799269 Vargo Oct 2017 S
D799909 Partridge Oct 2017 S
D799963 Akiyama Oct 2017 S
9801969 Griffis Oct 2017 B2
D802375 Kao Nov 2017 S
D802419 Seiders et al. Nov 2017 S
D802994 Seiders et al. Nov 2017 S
D806465 Boroski Jan 2018 S
D806543 Finkbohner et al. Jan 2018 S
9919860 Dabah et al. Mar 2018 B2
9926115 Jung et al. Mar 2018 B2
D814852 Melanson et al. Apr 2018 S
D814930 Tremayne et al. Apr 2018 S
D816426 Washburn et al. May 2018 S
D817114 Beckman May 2018 S
D818775 Woodruff May 2018 S
D819402 Silsby et al. Jun 2018 S
D819443 Martinez Carregui et al. Jun 2018 S
D820039 Fitzsimons Jun 2018 S
D831434 Washburn et al. Oct 2018 S
D834938 Barnes et al. Dec 2018 S
D835937 Nichols Dec 2018 S
D836387 Silsby et al. Dec 2018 S
D836388 Abante et al. Dec 2018 S
D836389 Abante et al. Dec 2018 S
10167120 Levy et al. Jan 2019 B1
10189619 Crawley Jan 2019 B1
10196179 Wisniewski Feb 2019 B2
10196186 Cox Feb 2019 B2
10202224 Painchaud Feb 2019 B2
10214323 Conley et al. Feb 2019 B2
D842030 Meyers Mar 2019 S
D842038 Seiders et al. Mar 2019 S
20020014498 Forsman et al. Feb 2002 A1
20030141321 Sekendur Jul 2003 A1
20030155323 Ekkert Aug 2003 A1
20040016715 Strikovic Jan 2004 A1
20040045967 Becker et al. Mar 2004 A1
20040201224 Chang Oct 2004 A1
20040206721 Swanberg et al. Oct 2004 A1
20050274741 Cho Dec 2005 A1
20060180585 Cunningham et al. Aug 2006 A1
20070108153 Weist May 2007 A1
20070199914 Hung Aug 2007 A1
20070251956 Wasserman et al. Nov 2007 A1
20080142466 Balitski Jun 2008 A1
20080230506 Lantz et al. Sep 2008 A1
20090045194 Rhee Feb 2009 A1
20090084752 Coulson Apr 2009 A1
20090101644 Maiwald et al. Apr 2009 A1
20100012615 Brooks Jan 2010 A1
20100089151 Mantilla Apr 2010 A1
20100200602 Chan Aug 2010 A1
20100215294 Berman Aug 2010 A1
20100237078 Lentz et al. Sep 2010 A1
20110056386 Taketani Mar 2011 A1
20110186585 Lu Aug 2011 A1
20110198352 Lown et al. Aug 2011 A1
20120074143 Lin Mar 2012 A1
20120199548 Kitto Aug 2012 A1
20130136382 Barron May 2013 A1
20130306642 Dabah et al. Nov 2013 A1
20140069917 Meyers et al. Mar 2014 A1
20140251938 Rose et al. Sep 2014 A1
20140312077 Tajima et al. Oct 2014 A1
20140353275 Hung Dec 2014 A1
20150191293 Forcella Jul 2015 A1
20150251812 Gillie Sep 2015 A1
20150314929 Tebbe Nov 2015 A1
20150374151 Lin Dec 2015 A1
20160159538 Michie Jun 2016 A1
20160167852 Moradi Jun 2016 A1
20160176587 Heraud Jun 2016 A1
20160192797 Yang Jul 2016 A1
20160256359 Trawick et al. Sep 2016 A1
20160318693 Hein Nov 2016 A1
20160355305 Hoskins Dec 2016 A1
20170001772 Rho Jan 2017 A1
20170043916 Seiders et al. Feb 2017 A1
20170081090 Boyer et al. Mar 2017 A1
20170127859 Hornung et al. May 2017 A1
20170144811 Wohlgenannt May 2017 A1
20170158398 Shively Jun 2017 A1
20170158412 Seiders et al. Jun 2017 A1
20170354289 Marina et al. Dec 2017 A1
20180029762 Eyal Feb 2018 A1
20180050845 Chin et al. Feb 2018 A1
20180105346 Tolman et al. Apr 2018 A1
20180118427 Lee et al. May 2018 A1
20180134457 Mutterle et al. May 2018 A1
20180141722 Langelaan May 2018 A1
20180162608 Kim Jun 2018 A1
20180162610 Kim Jun 2018 A1
20190002164 Nakatani et al. Jan 2019 A1
20190039782 Campbell Feb 2019 A1
20190047754 Dubiel et al. Feb 2019 A1
20190047773 Bullock et al. Feb 2019 A1
20190062010 Apte et al. Feb 2019 A1
Foreign Referenced Citations (136)
Number Date Country
2017280047 Jan 2019 AU
2016368382 Feb 2019 AU
3030583 Nov 2018 CA
3012127 Feb 2019 CA
201349991 Nov 2009 CN
301110494 Jan 2010 CN
201640878 Nov 2010 CN
201694495 Jan 2011 CN
201777557 Mar 2011 CN
202030152 Nov 2011 CN
202060630 Dec 2011 CN
202086330 Dec 2011 CN
202287503 Jul 2012 CN
103112651 May 2013 CN
202981686 Jun 2013 CN
203127394 Aug 2013 CN
203207847 Sep 2013 CN
103538798 Jan 2014 CN
103619723 Mar 2014 CN
104129579 Nov 2014 CN
102730301 Mar 2015 CN
103086061 Aug 2015 CN
303528321 Dec 2015 CN
105705425 Jun 2016 CN
303894653 Oct 2016 CN
303899030 Oct 2016 CN
303902404 Nov 2016 CN
303905254 Nov 2016 CN
303905266 Nov 2016 CN
303944047 Nov 2016 CN
303956194 Dec 2016 CN
303965272 Dec 2016 CN
303965286 Dec 2016 CN
303965392 Dec 2016 CN
303965400 Dec 2016 CN
303966239 Dec 2016 CN
303974938 Dec 2016 CN
303984407 Dec 2016 CN
303984493 Dec 2016 CN
304011213 Jan 2017 CN
304011214 Jan 2017 CN
205998332 Mar 2017 CN
108313494 Jul 2018 CN
107224167 Aug 2018 CN
108394633 Aug 2018 CN
106458394 Oct 2018 CN
105050907 Dec 2018 CN
105358441 Dec 2018 CN
108945789 Dec 2018 CN
106163937 Jan 2019 CN
105595863 Feb 2019 CN
106255648 Feb 2019 CN
106414269 Feb 2019 CN
106458396 Feb 2019 CN
109319295 Feb 2019 CN
208470495 Feb 2019 CN
208485029 Feb 2019 CN
208531194 Feb 2019 CN
2233565 Jun 1973 DE
2226556 Aug 1977 DE
3514261 Jan 1986 DE
29612345 Sep 1996 DE
29611746 Nov 1997 DE
69509827 Oct 1999 DE
29912668 Dec 1999 DE
202008009584 Oct 2008 DE
102014011506 Jul 2015 DE
402016101176-0008 Nov 2016 DK
402016101176-0010 Nov 2016 DK
003528504-0004 Dec 2016 EM
004539732-0003 Dec 2017 EM
1088764 Apr 2001 EP
1693310 Aug 2006 EP
1934106 Jun 2008 EP
2457842 May 2015 EP
3066018 Nov 2016 EP
2851311 Jun 2018 EP
3157833 Aug 2018 EP
2796078 Oct 2018 EP
3398484 Nov 2018 EP
3398871 Nov 2018 EP
3441320 Feb 2019 EP
1359912 Apr 1964 FR
2521957 Oct 1986 FR
2786465 Jun 2000 FR
2830848 Apr 2003 FR
729903 May 1955 GB
2114959 Jul 1985 GB
H02-052759 Apr 1990 JP
H03-159974 Jul 1991 JP
H08-0117119 May 1996 JP
2000333847 Dec 2000 JP
2001315831 Nov 2001 JP
2003125912 May 2003 JP
2008162679 Jul 2008 JP
1363566 Jun 2009 JP
2010280402 Dec 2010 JP
2011093544 May 2011 JP
1530358 Aug 2015 JP
2016141412 Aug 2016 JP
6408837 Oct 2018 JP
6409250 Oct 2018 JP
2019001538 Jan 2019 JP
6467720 Feb 2019 JP
2019503943 Feb 2019 JP
200169857 Feb 2000 KR
300295354 Apr 2002 KR
300303813.0000 Aug 2002 KR
20100008131 Jan 2010 KR
300764889.0000 Oct 2014 KR
3020150002495 Dec 2015 KR
101581270 Jan 2016 KR
101668309 Oct 2016 KR
300883384.0000 Nov 2016 KR
300884377.0000 Dec 2016 KR
300885455.0000 Dec 2016 KR
300885851.0000 Dec 2016 KR
300888536.0000 Jan 2017 KR
101785906 Oct 2017 KR
20-2019-0000204 Jan 2019 KR
101922235 Feb 2019 KR
00100680 Nov 2016 RU
2005028317 Mar 2005 WO
2006023238 Mar 2006 WO
07123365 Nov 2007 WO
08048039 Apr 2008 WO
2014114493 Jul 2014 WO
14041325 Sep 2014 WO
14184341 Nov 2014 WO
D088688-002 Jan 2016 WO
16180908 Nov 2016 WO
17097485 Jun 2017 WO
17115193 Jul 2017 WO
18149763 Aug 2018 WO
17223093 Feb 2019 WO
19025589 Feb 2019 WO
Non-Patent Literature Citations (39)
Entry
Feb. 11, 2019—(CN) Office Action—App. No. 201680059619.7.
“YETI Rambler Bottle Cup Cap Accessory.” Found online: Jun. 18, 2019 at www.amazon.com. Product reviewed May 30, 2019. Retrieved from URL: http://tinyurl.com/y32g688u (Year: 2019).
Liquid Hardware, Insulated Aqua Silver Sidewinder Vacuum Bottle 20oz./592ml. Powder Coated in USA!, product description, retrieved from Internet on Aug. 12, 2015, 3 pages.
Nov. 2, 2016—(WO) International Search Report and Written Opinion—App. No. PCT/US2016/047043.
Oct. 18, 2016—(JP) Office Action—App. 2016-010799, English Translation, 3 Pages.
Oct. 18, 2016—(JP) Office Action—App. 2016-010800, English Translation, 3 Pages.
YETI 36 oz. Rambler: Announced Jan. 11, 2016 [online], site visited [May 10, 2016]. Available from Internet URL: http://yeticoolers.com/rambler-bottle-36-oz/.
KOLD Vacuum Insulated Stainless Steel Sports Bottle: Announced Dec. 8, 2015 [online], site visited [May 11, 2016]. Available from Internet URL: http://www.amazon.com/KOLD-Sports-Water-Bottles-Insulated/dp/B018YH K79E/ref=cm.
“Hydro Flask Insulated Stainless Steel Water Bottle” published on Dec. 29, 2014, retrieved from http://web.archive.org/web/*/https://www.amazon.com/dp/B004X55L9I/ref=twister_B00GA03LG4?_encoding=UTF8&psc=1 on Sep. 22, 2016.
“UA Beyond 18 oz. Vacuum Insulated Water Bottle” published on Mar. 29, 2015, retrieved from http://web.archive.org/web/*/https://www.underarmour.com/en-us/beyond-18-oz-vacuum-insulated-ss-bottle-with-flip-top-lid/pid1232014 on Mar. 22, 2016.
“Klean Kanteen Insulated Classic with Polypropylene” published on Jul. 7, 2015, retrieved from http://web.archive.org/web/*/https://www.lifewithoutplastic.com/store/klean-kanteen-insulated-classic-with-polypropylene-loop-cap-0-95-I-32-oz.html on Sep. 22, 2016.
“Eco Vessel 64 ounce Growler” published on Jan. 28, 2015, retrieved from http://web.archive.org/web/*/http://www.snewsnet.com/press-release/eco-vessel-launches-the-boss-insulated-growler/ on Sep. 22, 2016.
“64 oz Double-Wall Vacuum-Insulated Growler” published on Nov. 14, 2014, retrieved from https://web.archive.org/web/*/http://www.fiftyfiftybottles.com/64oz-growler/ on Sep. 22, 2016.
“2015 Boulder Insulated Water Bottle with Tea, Fruit, Ice Strainer” published on Jun. 28, 2015, retrieved from http://web.archive.org/web/*/http://www.ecovessel.com/boulder-insulated-water-bottle-with-tea-fruit-ice-strainer-20-oz/ on Sep. 22.
“KB8 20 oz. Double Wall Stainless Bottle,” published on May 22, 2015, retrieved from https://web.archive.org/web/20150807054814/http://thermo-steel.com/work/keen-kb8 on Sep. 27, 2016.
Nov. 1, 2016—(JP) Office Action—App. 2016-9606, English Translation, 2 Pages.
Oct. 4, 2016—(JP) Office Action—App 2016-9607, English Translation, 2 pages.
Oct. 4, 2016—(JP) Office Action—App. 2016-9608, English Translation, 2 Pages.
‘First Look: YETI Rambler One Gallon ‘Jug’ Review’. Found online Jun. 12, 2017 at gearjunkie.com. Page dated May 2, 2017. Retrieved from https://gearjunkie.com/yeti-rambler-one-gallon-jug-review.
“Lifefactory Water Bottle with Flip Cap”. Found online Oct. 26, 2016 at amazon.com. Page dated Jan. 21, 2012. Retrieved from https://www.amazon.com/Lifefactory-22-Ounce-BPA-Free-Bottle-Silicone/dp/B01JIHJYOI/ref=pd_day0_79_22?_encoding=UTF8&refRID=YW47QZQ73YFSYXXEHXG2.
“Igloo Sport Beverage Cooler”. Found online Jun. 7, 2017 at amazon.com. Page dated Mar. 9, 2013. Retrieved from https://www.amazon.com/Igloo-Beverage-Cooler-Majestic-2-Gallon/dp/B0088AYPOG/ref=cm_cr_arp_d_product_top?ie=UTF8.
“Klear Loop Cap Hangle Lids for Klear Bottle and Hydro Flask”. Found online Jun. 7, 2017 at amazon.com. Page dated Jul. 4, 2016. Retrieved from https://www.amazon.com/Klear-Handle-Bottle-Hydro-Flask/dp/B01EXKSRLQ/ref=cm_cr_arp_d_product_top?ie=UTF8.
Rambler Jug Mount. Online, published date unknown. Retrieved on Jan. 2, 2018 from URL: https://www.yeti.com/accessories/rambler-jug-mount!YRAMJM.html.
AVEX, “40oz. 3Sixty Pour Stainless Steel Thermal Bottle”, Accessed May 18, 2017. http://www.avexoutdoor.com/3sixty-pour-realtree-thermal-bottle.html.
Jan. 29, 2018—(WO) Invitation to Pay Additional Fees and Partial International Search Report—App. No. PCT/US2017/057010—13 pages.
Mar. 27, 2018—(WO) International Search Report and Written Opinion—App. No. PCT/US20171057010—19 pages.
YETI Rambler Vacuum Insulated Stainless Steel One Gallon Jug with MagCap. Found online Jun. 12, 20177 at amazon.com. Page dated May 30, 2017. Retrieved from https://www.amazon.com/YETI-Rambler-Vacuum-Insulated-Stainless/dp/B071HTJ4Q8.
“Klean Kanteen Stainless Unibody Bamboo Cap”. Found online Jun. 12, 2018 at amazon.com. Page dated Sep. 10, 2012. Retrieved from https://www.amazon.com/Klean-Kanteen-Stainless-Unibody-Bamboo/dp/B0083F0SDI/ref=cm_cr_arp_d_product_top?ie=UTF8.
“Takeya ThermoFlask”. Found online Jun. 9, 2018 at amazon.com. Page dated Apr. 15, 2016. Retrieved from https://www.amazon.com/Takeya-ThermoFlask-Pack-Back-Silver/dp/B01D7NIOWW/ref=cm_cr_arp_d_product_top?ie=UTF8.
“Twitter: h2go elevate and h2go inspire: same lid stlye, different body typw”. Found online Jun. 12, 2018 at twitter.com. Page dated Jan. 21, 2015. Retrieved from https://twitter.com/etsexpress/status/557997114589196288.
“Thermos Stainless King 60 Ounce Vacuum Insulated Beverage Bottle.” Found online Jul. 13, 2018 at www.amazon.com. Page dated Aug. 15, 2015. Retrieved from U RL: https://www.amazon.com/Thermos-Stainless-Insulated-Beverage-Midnight/dp/B008YB4V52 (Year: 2015).
“Stanley Classic Vacuum Bottle.” Found online Jul. 13, 2018 at www.amazon.com. Page dated Nov. 30, 2014. Retrieved from URL: https://tinyurl.com/y8nnymt9 (Year: 2014).
Jul. 15, 2019—(CN) Office Action—App. No. 201680059619.7.
Youtube. YETI Rambler R12 Bottle with Hotshot Cap Demo, Features & Review by Tentworld—The Camping Experts. Oct. 30, 2019. https://www.youtube.com/watch?v=cLZsvhUMydM (Year: 2019).
Dec. 4, 2019—(CN) Examination Report—App. No. 201680059619.7.
Feb. 19, 2020—(EP) Extended Search Report—App No. EP19209538.
Apr. 6, 2020—(WO) International Search Report & Written Opinion—PCT/US19/056566.
May 19, 2020—(CN) Office Action—App. No. 201680059619.7.
May 7, 2020—(WO) International Search Report & Written Opinion—PCT/US19/059799.
Related Publications (1)
Number Date Country
20190039791 A1 Feb 2019 US
Continuations (1)
Number Date Country
Parent 14826612 Aug 2015 US
Child 16154178 US