Containers that may be used to enclose and transport fluids are often subject to significant stresses during use. Such containers may be dropped while full or partially full of fluid, stacked on top of one another, supported in a suspended configuration (e.g., when held by a user), and/or the like. Accordingly, various containers incorporate strengthening features in order to provide strength to the container against breakage.
However, containers may be subject to additional limitations, such as a requirement to minimize the cost of materials in the containers, the weight of materials in the containers, and/or the like. Accordingly, container configurations often are subject to generally conflicting design considerations of maximizing the strength of the container while minimizing the cost and/or weight of materials in the container.
Accordingly, a need exists for containers providing an optimal balance of maximum strength against undesired breakage while minimizing the cost and/or weight of materials in the container.
Certain embodiments are directed to high-strength blow-molded containers having a thin overall sidewall thickness. The container may be particularly suitable for storing and transporting industrial fluids, such as solvents, cleaners, automotive fluids, and/or the like. The container may have a multi-angle top portion configured to distribute vertical compression loads received by the container over a large surface area of the container sidewalls to avoid common crush-failure points surrounding the spout. Moreover, the container includes an integrated handle having similar crush-resistant properties through the introduction of gradual, large radius curves between the handle and adjacent portions of the container, and via the placement of the handle portion outside of the circumference of the spout, such that vertical crushing loads do not create a large localized crushing stress on the bottom proximate a perimeter of the container portion.
Various embodiments are directed to a container comprising: a base portion configured to support the container in an upright orientation relative to a support surface and wherein the base portion defines an at least substantially ovular perimeter; a spout positioned opposite the base portion and oriented such that a centerline of the spout is aligned with a centerline of the base portion; an ovular sidewall extending between the perimeter of the base portion to the spout, wherein the ovular sidewall defines: a vertical portion extending away from the base portion; a downward sloping linear top portion extending away from the spout and toward the vertical portion; and a gradually curved transition region extending between the vertical portion and the downward sloping linear top portion, wherein the gradually curved transition region defines a continuously variable radius of curvature having an at least substantially linear portion adjacent the downward sloping linear top portion; wherein the vertical portion is inset relative to the gradually curved transition region and the base portion; and wherein the downward sloping linear top portion has a steeper slope than the at least substantially linear portion of the gradually curved transition region.
In certain embodiments, the sidewall defines an at least substantially uniform wall thickness through the vertical portion, top transition region, and downward sloping top portion. Moreover, the ovular sidewall may further define a curved base transition region extending between the base portion and the vertical portion, and wherein the vertical portion is inset relative to the curved base transition region. The container may also comprise a handle portion defining a handle cavity within the downward sloping top portion and the top transition region; a face surface extending across the handle cavity; and a handle comprising an upper portion adjacent the spout and a lower portion adjacent the vertical portion of the sidewall.
The ovular base may define a major diameter measured across the container and aligned with a first center plane of the container and a minor diameter measured across the container and aligned with a second center plane perpendicular to the first center plane, wherein the major diameter is longer than the minor diameter; and wherein the handle may be aligned with the first center plane. In certain embodiments, the handle and face surface are spaced a horizontal distance away from a third plane, wherein the third plane is parallel with the second plane and tangent to the spout such that the spout is positioned on a first side of the third plane and the handle and face surface are positioned on a second side of the third plane. Moreover, the face surface may be bound by a convex perimeter curve joining the face surface with the downward sloping top portion and the top transition region. Moreover, the convex perimeter curve may be bounded by a perimeter groove positioned between the convex perimeter curve and the top portion and top transition region.
Certain embodiments are directed to a container comprising: a base portion configured to support the container in an upright orientation relative to a support surface and wherein the base portion defines an at least substantially ovular perimeter having a major diameter and a minor diameter measured perpendicular to the major diameter, wherein the major diameter is larger than the minor diameter; a spout positioned opposite the base portion and oriented such that a centerline of the spout is aligned with a centerline of the base portion; an ovular sidewall extending between the perimeter of the base portion to the spout, wherein the ovular sidewall defines: a vertical portion extending away from the base portion; a downward sloping top portion extending away from the spout and toward the vertical portion; a gradually curved transition region extending between the vertical portion and the downward sloping linear top portion; and a curved base transition region extending between the base portion and the vertical portion; and wherein the base portion defines: a base channel extending across the base portion and aligned with the major diameter, wherein the base channel has a first depth extending toward an interior of the container; and an ovular inset panel oriented such that a centerline of the ovular inset panel is aligned with the centerline of the base portion, wherein the ovular inset panel has a second depth extending toward the interior of the container, wherein the second depth is greater than the first depth.
In certain embodiments, the vertical portion of the ovular sidewall is inset relative to the gradually curved transition region and the base portion. Moreover, the ovular inset panel may be concave and may have a centerpoint aligned with the centerline of the base portion and inset relative to a perimeter of the ovular inset panel toward the interior of the container. In certain embodiments, the base portion defines a support ring configured to support the container in the upright configuration, wherein the support ring surrounds the ovular inset panel and has an at least substantially uniform width measured between the perimeter of the container and a perimeter of the ovular inset panel; and wherein the base channel interrupts the support ring. Moreover, the curved base transition region may define an inflection point defining a convex peak surrounding the perimeter of the container, and wherein the inflection point transitions from a high position aligned with the minor axis to a low position aligned with the major axis.
Certain embodiments are directed to a container comprising: a base portion configured to support the container in an upright orientation relative to a support surface and wherein the base portion defines an at least substantially ovular perimeter having a major diameter and a minor diameter measured perpendicular to the major diameter, wherein the major diameter is larger than the minor diameter; a spout positioned opposite the base portion and oriented such that a centerline of the spout is aligned with a centerline of the base portion; an ovular sidewall extending between the perimeter of the base portion to the spout, wherein the ovular sidewall defines: a vertical portion extending away from the base portion; a downward sloping top portion extending away from the spout and toward the vertical portion; and a gradually curved transition region extending between the vertical portion and the downward sloping linear top portion; and a handle portion defining: a handle cavity within the downward sloping top portion and the top transition region; a face surface extending across the handle cavity; and a handle comprising an upper portion adjacent the spout and a lower portion adjacent the vertical portion of the sidewall; wherein the vertical portion is inset relative to the gradually curved transition region and the base portion; and wherein the face surface of the handle portion is spaced a horizontal distance away from the spout.
In certain embodiments, the major diameter is aligned with a first center plane of the container and the minor diameter is aligned with a second center plane perpendicular to the first center plane, wherein the handle is aligned with the first center plane, and the face surface of the handle portion is spaced away from the spout by a distance measured parallel to the major axis. Moreover, various embodiments of the face surface are bounded by a convex perimeter curve joining the face surface with the downward sloping top portion and the top transition region. In certain embodiments, the convex perimeter curve is bounded by a perimeter groove positioned between the convex perimeter curve and the top portion and top transition region. Moreover, in certain embodiments the upper portion of the handle intersects the convex perimeter curve at a first position proximate the spout and the lower portion of the handle intersects the convex perimeter curve at a second position proximate the vertical portion of the sidewall. In certain embodiments the lower portion of the handle further comprises a protruding strap portion interrupting the perimeter groove. Moreover, the protruding strap portion may be hollow.
Reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the invention are shown. Indeed, the invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.
Described herein is a container configured to enclose a fluid and/or other substance. The container comprises a plurality of strengthening features that provide desirable strength characteristics while minimizing the required amount of material necessary to construct the container having the desired strength characteristics. For example, various strengthening features may extend across planar surfaces, curved surfaces, and/or complex curved surfaces in order to provide crush resistance, tensile strength, and/or the like for the container. In various embodiments, the container may comprise a plastic material (e.g., High-Density Polyethylene (HDPE)). As a non-limiting example, the container may comprise at least about 70-90 g of material to provide a container having an interior volume of at least substantially 1 gallon; substantially larger or smaller containers may be formed or provided, with structural features beyond size/dimension otherwise as detailed herein.
As discussed herein, the container may define an at least substantially ovular base-perimeter having an at least substantially ovular sidewall extending therefrom. The sidewall may extend from a base portion (e.g., from a base transition region), through a vertical region, through a top transition region, through a top region, and to a spout. In various embodiments, the container may additionally define a handle portion encompassing a portion of the top region. The handle portion may be defined as a handle cavity and a handle, thereby providing a portion enabling a user to comfortably hold the container.
The container may be extrusion blow-molded. In various embodiments, the container may be constructed by placing (e.g., injecting) a parison within a container mold, wherein the container mold has an interior surface corresponding to the shape of the container. In various embodiments, the container mold may comprise two mold shells that collectively define the entirety of the mold. The mold shells may be symmetrical and have corresponding features, and accordingly the resulting container may be symmetrical across one or more planes.
The following description of a container is divided into various portions of the container for purposes of clarity, however it should be understood that such divisions should not construed as limiting, as one or more containers according to various embodiments may be constructed as a single continuous part. Moreover, the following description provides various dimensions for an example embodiment. These dimensions should not be construed as limiting, and are instead provided as example dimensions an example embodiment.
In various embodiments, the container 1 may comprise an at least semi-rigid material. Semi-rigid containers 1 may be configured to flex when exposed to externally applied forces, and/or rigid containers 1 may be configured to resist substantial flexing when subject to externally applied forces. For example, the container 1 may comprise plastic or other rigid or semi-rigid material. As just one specific example, the container 1 may comprise HDPE. As will be discussed herein, the container may be extrusion blow-molded. In such embodiments, the container 1 may comprise at least approximately 70-90 g of material to provide a 1-gallon interior volume container. As a specific example, a 1-gallon container may comprise at least approximately 80 g of material. As other example embodiments, the container 1 may comprise at least approximately 40-50 g (e.g., 45 g) of material for a ½-gallon interior volume container, and/or at least approximately 50-60 g (e.g., 55 g) of material for a 96-ounce interior volume container.
Except as otherwise discussed herein, the container 1 may have an at least substantially uniform wall thickness (extending between the interior of the container 1 and the exterior surface of the container 1) of at least approximately 0.009″ to 0.050″ (e.g., between about 0.015″ to 0.020″). Accordingly, each sidewall may have an at least substantially uniform wall thickness between the vertical portion 200, top transition region 300, and top portions 400 (each described in greater detail herein). In various embodiments, the container 1 may be configured to resist a vertical crushing force of between about 150-160 lbf of force with about a 0.25 inch deflection in overall height of the bottle when filled and having a cap secured onto a spout thereof before breaking. Moreover, the container 1 may be configured to fall from a height of at least 3 feet while filled with fluid onto a hard surface without breaking.
As will be discussed herein with reference to specific contours of the container 1, the container 1 may define a symmetry plane A extending through the center of the container. In various embodiments, the container may be at least substantially symmetrical about the symmetry plane A (except as specifically noted herein), such that contours on a first side of the symmetry plane A are equal and opposite to contours on a second side of the symmetry plane A. As illustrated in
As illustrated in
Moreover, the base transition region 150 may comprise spacing portions 152, 153 spaced around the perimeter of the base transition region 150. As shown in the figures, the spacing portions 152, 153 may be spaced at approximately 90 degrees relative to one another around the perimeter of the container 1. The spacing portions 152, 153 are defined as portions of the base transition region 150 having an interrupted radius of curvature. As shown, the spacing portions 152, 153 comprise first spacing portions 152 and second spacing portions 153, wherein the first spacing portions 152 have a first width (measured along the circumference of the base transition region 150) and the second spacing portions 153 have a second width (measured along the circumference of the base transition region 150). In certain embodiments, the spacing portions 152, 153 may have an at least substantially identical radius of curvature between the base portion 100 and the vertical portion 200, but may have a different radius of curvature measured around the perimeter of the base portion 100 than other portions of the base transition region 150. In certain embodiments, the spacing portions 152, 153 may be at least substantially planar portions of the perimeter of the base transition region 150. Due at least in part to the inclusion of the spacing portions 152, 153, the base portion 100 (and the container 1 as a whole) may have an at least substantially ovular shape having a major axis parallel with the plane of symmetry A and a minor axis perpendicular to the plane of symmetry A. In the illustrated embodiments, the ratio between the length of the major axis and the minor axis is between about 1.016 to 1, although other ratios may be used based on needed interior dimensions of the container 1.
In the illustrated embodiment of
As shown in
Moreover, the base portion defines an inset portion 102 circumscribed by the support ring 101. As shown in the figures, the inset portion 102 may comprise an at least substantially ovular panel inset relative to the support ring 101 toward the interior of the container. The at least substantially ovular panel 102 may be concave, having a center point that is inset toward the interior of the container 1 relative to the edges of the concave panel 102 (the edges of the concave panel 102 may be provided within a single horizontal plane). In various embodiments, the center point of the concave panel 102 may be inset by a distance of between about 0.1″ to 0.2″ relative to the edges of the concave panel 102. Moreover, the edges of the concave panel 102 may be inset relative to the support ring 101 by a distance of between about 0.25″ to 0.3″. However, it should be understood that the concave panel 102 may be inset relative to the support ring 101 to vary the interior volume of the container 1, and accordingly the inset distance may be set according to a desired interior volume of the container 1. In certain embodiments, the outer edge of the concave panel 102 may define a transition curvature to the support ring 101, and may have a radius of curvature of at least about 0.125″ to 0.25″. The concave panel 102 may be centrally located within the base portion 100 (e.g., such that a centerpoint of the concave panel 102 is aligned with a centerline of the container 1) and may have a shape corresponding to the ovular shape of the container 1. For example, the concave panel 102 may have a ratio between a major axis and a minor axis that is at least substantially identical to the container 1. In such embodiments, the support ring 101 has an at least substantially uniform width around the perimeter of the base portion 100.
Because the concave panel 102 is located centrally within the support portion 101 of the container 1, the concave panel 102 segments the channel portion 105-106 into a first channel portion 105 and a second channel portion 106, wherein the first and second channel portions 105-106 are positioned on opposite sides of the concave panel 102 and are aligned with the plane of symmetry A.
Moreover, in the embodiment shown in the figures, the concave panel 102 comprises an alignment indenture 103. The alignment indenture 103 may be embodied as a cavity extending toward the interior of the container 1, and may be defined at least in part by an at least substantially vertical sidewall that may be configured to engage an alignment pin of a bottle fill machine. The alignment indenture 103 may be configured to facilitate rotating the container 1 into a desired alignment along a bottle fill line.
In the illustrated embodiment of
The vertical portion 200 may be configured for accepting a label printed, adhered, or otherwise secured thereon. For example, a separate label having a circumference at least substantially identical to the circumference of the vertical portion 200 may be positioned over the vertical portion 200 of the container 1. Because the vertical portion 200 may be inset relative to adjacent portions of the container, the separate label need not be directly secured onto the container sidewalls 11, and may be retained on the vertical portion 200 due to the relative size of the label (having a circumference substantially similar to the circumference of the vertical portion 200) relative to the sizes of the container portions immediately adjacent the vertical portion 200. For example, the label may be free to rotate around the vertical portion 200 and/or to slide along the height of the vertical portion between the lower bridge portion 201 and the upper bridge portion 202.
In the illustrated embodiment of
In various embodiments, the top transition region 300 defines a gradually variable radius of curvature between the portion of the sidewall 11 in the vertical portion 200 and the non-vertical portion of the sidewall 11 within the top portion 400. As a non-limiting example, the top transition region 300 has a continuously variable radius of curvature (although in certain embodiments the top transition region 300 may define a continuous radius of curvature portion and a linear portion). In various embodiments, the top transition region 300 has a height (measured vertically between beginning of the radius of curvature at the top edge of the vertical portion 200 and the ending of the radius of curvature at the lower-most edge of the top portion 400 of 3.3″ to 3.4″. Moreover, the top portion may extend at an angle with respect to horizontal of at least approximately 57 degrees. This gradual and continuously variable radius of curvature of the top transition region 300 over the height of the top transition region 300 facilitates movement of container material across the top transition region 300 between the top portion 400 and the vertical portion 200 during formation of the container 1 in order to provide an at least substantially uniform wall thickness across all of the top portion 400, the top transition region 300, the vertical portion 200 and the base portion 100.
In various embodiments, the top transition region 300 has a variable and gradual radius of curvature along the entire height of the top transition region 300 (with the exception of the upper bridge portion 202 discussed herein). For example, the radius of curvature of the top transition region 300 may linearly increase and/or linearly decrease over the height of the top transition region 300. The top transition region 300 may also have a decreasing (e.g., continuously decreasing) diameter between a bottom portion of the top transition region 300 and the top portion 400, such that the container sidewall 11 may begin converging toward the spout 500.
In the illustrated embodiment of the figures, the top transition region 300 has an overall diameter larger than the adjacent vertical portion 200 (e.g., the top transition region 300 may have an overall diameter at least substantially the same as the base transition region 150), and thus the top transition region 300 may additionally comprise an upper bridge portion 202 connecting the vertical portion 200 with the top transition region 300. The upper bridge portion 202 may have a configuration at least substantially the same as the lower bridge portion 201. In certain embodiments, the upper bridge portion 202 may be chamfered or curved (e.g., a convex curve or a concave curve) as shown in the figures.
The top transition region 300 may additionally comprise one or more spacing portions 302, 303 corresponding to the spacing portions 152, 153 of the base transition region 150. In the illustrated embodiments, the spacing portions 302, 303 comprise first spacing portions 302 and second spacing portions 303 that may be aligned with the first spacing portions 152 and second spacing portions 153, respectively, of the base transition region 150. The first spacing portions 302 have a first width (measured along the circumference of the top transition region 300) and the second spacing portions 303 have a second width (measured along the circumference of the top transition region 300). The first width and the second width may correspond to the respective first width and second width of the first spacing portions 152 and second spacing portions 153 within the base transition region 150. The spacing portions 302, 303 may be spaced evenly around the perimeter of the top transition region 300. For example, the spacing portions 302, 303 may be spaced at approximately 90 degrees around the perimeter of the top transition region 300. Moreover, the spacing portions 302, 303 may converge within the top portion 400 toward the spout, as the cross-sectional area of the top portion 400 decreases toward the spout.
Moreover, as will be discussed in greater detail herein, at least a portion of the top transition region 300 may be interrupted by the handle portion 600. Accordingly, the top transition region 300 may extend partially around the perimeter of the container 1 between opposite side edges of the handle portion 600.
In the illustrated embodiment of
In the illustrated embodiments, the top portion 400 is separated from the top transition region 300 by a slope transition 401 positioned between the top portion 400 and the top transition region 300. As mentioned above, the top transition region 300 may be defined by a continuously variable radius of curvature between the vertical portion 200 and the top portion 400. For example, the radius of curvature of the top transition region 300 may increase from the vertical portion 200 to the top portion 400, such that the top transition region 300 is approximately linear proximate the top portion 400. In certain embodiments, the top portion 400 may be defined by a steeper slope (e.g., a more acute angle relative to vertical) than the portion of the top transition region 300 proximate the top portion 400. The change in slope between the top portion 400 and the top transition region 300 may increase the top load crush resistance of the container 1 by providing a load-bearing top portion 400 that directs vertical crushing forces away from the spout 500 and the interface between the spout 500 and the top portion 400, and acts to spread the vertical crushing forces over a large portion of the sidewall 11, particularly within the top transition region 300 of the container 1.
In certain embodiments, the ratio between the vertical height of the top transition region 300 and the top portion 400 is at least approximately 2.7 to 1. For example, the top transition region 300 may have a vertical height of at least approximately 3.3, and the top portion 400 may have a vertical height of at least approximately 1.25. Moreover, as mentioned above, the top portion 400 may define an angle relative to horizontal of at least approximately 57 degrees. In certain embodiments, the portion of the top transition region 300 immediately adjacent the slope transition 401 may define a less-steep angle relative to horizontal. However, it should be understood that in certain embodiments, the portion of the top transition region 300 immediately adjacent the slop transition 401 may define an angle relative to horizontal that is at least approximately equal to the angle of the top portion 400.
Collectively, the top portion 400 and the top transition region 300 collectively define at least approximately 40% percent of the total height of the container (measured between the support ring 101 of the base portion 100 to the top of the spout 500). By providing such a large percentage of the container 1 height within the top portion 400 and top transition region 300, the container 1 may have a gradual diameter increase from the spout 500 to the vertical portion 200. This gradual increase in diameter is characterized by a relatively steep slope of the top portion 400 and top transition region 300 which is configured to support a larger portion of a vertical compressive force applied to the spout and to distribute the received compressive load over a larger surface area of the container sidewall 11. The gradual increase in diameter prevents the formation of localized stress points within the top portion 400 of the container that subject to relatively high compressive forces when the container is subject to a vertical compressive load.
In various embodiments, the spout 500 extends above the top portion 400, and forms an opening from which the contents of the container 1 may be added to the container and/or removed from the container 1. The spout 500 may define a raised shoulder 501 surrounding the spout 500 and intersecting the top portion 400 (e.g., intersecting the second slope portion 402). The raised shoulder 501 may extend between the top portion 400 and a neck 502 extending at least substantially vertically from the raised shoulder 501. The raised shoulder 501 may be angled relative to horizontal, defining an angle of between about 20 to 55 degrees relative to horizontal.
The neck may extend upward to a cap engagement portion 504 defining one or more threads, nipples, and/or the like to engage a removable cap (not shown) such that the removable cap may be selectably secured to the container 1. In various embodiments, one or more portions of the spout 500 may have a wall thickness greater than the wall thickness of remaining portions of the container 1. Particularly in embodiments comprising a threaded cap engagement portion 504, the cap engagement portion 504 may not be symmetrical across the container symmetry plane A.
Moreover, in certain embodiments, the spout 500 may be configured to provide additional rigidity to the container 1 while a cap is secured thereto. Accordingly, the container 1 may have a higher crush resistance strength while the cap is secured relative to the spout.
In various embodiments, the spout 500 may be located at least substantially centrally with respect to the profile of the container 1. As shown in
As mentioned herein, the container 1 may additionally comprise a handle portion 600. In the illustrated embodiment of
As shown in the figures, the face surface 601 defines a plurality of complex curved surfaces configured to spread vertical crushing loads across a large surface area of the container 1. The face surface generally slopes away from a central portion (aligned with the handle 650 and the plane of symmetry A) and toward the top portion 400 and top transition region 300. The face surface 601 thus has a generally convex cross-sectional shape for the container 1. Moreover, the face surface 601 defines a plurality of convex surfaces, such that the horizontal cross-sectional shape of the face surface 601 varies along the height of the face surface 601. The face surface 601 also defines an obtuse “L” shape over the height of the face surface 601. As shown in the attached figures, the face surface 601 defines a lower portion angled at an obtuse angle relative to an upper portion (the lower portion being separated from the upper portion by a curved portion as discussed herein).
As shown in
In various embodiments, the vertical cross-sectional shape of the central portion of the upper portion and the face surface transition portion (e.g., a cross-section taken within a plane parallel with the plane of symmetry A and within the width of the central portion) is at least substantially continuous across the width of the central portion. In certain embodiments, the central portion may be sloped away from the plane of symmetry A with an at least substantially constant slope (e.g., uncurved away from the plane of symmetry A) while maintaining an at least substantially continuous vertical-cross section of the central portion within a plane parallel with the plane of symmetry A.
Outside of the width of the central portion, the upper portion and the lower portion of the face surface 601 define complex, convex curves that slope away from the plane of symmetry A and slope downward toward the vertical portion 200 of the container 1. Due to the complex nature of the curves of the face surface 601 outside of the width of the central portion, the vertical cross section shape (measured in a plane parallel with the plane of symmetry A) and the horizontal cross sectional shape (measured in a horizontal plane perpendicular with the plane of symmetry A) change over the width of the face surface 601 and height of the face surface 601, respectively.
As shown in the figures, the face surface 601 is bounded by a convex perimeter curve 603 joining the face surface 601 with adjacent portions of the top portion 400 or top transition region 300. The convex perimeter curve is configured to increase the strength (e.g., the top load crush resistance strength) of the container by distributing received loads over a wide surface area of the container 1. The convex perimeter curve 603 has a radius of curvature of between about 0.4″ to 0.5″ (e.g., 0.041″ inches), and may vary around the perimeter of the face surface 601. Moreover, the linear width of the convex perimeter curve 603 may be between about 0.3″ to 0.5″, measured along a line extending perpendicular to the lateral edge of the face surface 601.
Moreover, the convex perimeter curve 603 of the handle portion 600 is bounded by a perimeter groove 604 circumscribing the handle portion 600. In the illustrated embodiment of the figures, the perimeter groove 604 has a depth of between about 0.03″ to 0.045″ (e.g., 0.039 inches), and a width (measured across the perimeter groove 604) of at least about 0.07″ to 0.08″.
As shown in the figures, the handle 650 extends from the upper end, along a generally obtuse and inverted “L”-shaped profile, and to the lower end, thereby forming the gap between the obtuse “L”-shaped face surface 601 and the inverted and obtuse “L”-shaped handle 650. Moreover, the handle 650 may have a rounded rectangular cross-section (e.g., defined by perpendicular pairs of parallel sidewalls joined by rounded corners) and may be hollow, having a sidewall thickness at least substantially similar to the sidewall thickness of the container 1 as a whole. In certain embodiments, the outermost sidewall of the handle may have a non-linear profile, and may form an at least substantially obtuse sidewall to provide additional strength against deformation of the handle when used to support the weight of a filled container 1.
The upper end of the handle 650 may be defined by a concave handle perimeter curve circumscribing the handle 650 and joining the sidewalls of the handle with the face surface 601, convex perimeter curve 603, and/or perimeter groove 604. As shown in the figures, the handle 650 intersects the convex perimeter curve 603 at the upper end, and therefore the concave handle perimeter curve intersects the convex perimeter curve 603 and perimeter groove 604. The concave handle perimeter curve remains within the handle portion 600 however, as defined by an outer edge of the perimeter groove. Moreover, the concave handle perimeter curve may have a radius of curvature of between about 0.18″ to 0.45″, and may vary around the perimeter of the handle 650.
As shown in the figures, the upper end of the handle 650 may additionally define a handle rib 605 centered on the plane of symmetry A and extending along the length of the concave handle perimeter curve. The handle rib 605 may have a width (measured across the plane of symmetry A) of between about 0.04″ to 0.08″, and a maximum height (measured perpendicular to the surface of the concave handle perimeter curve) of between about 0.02″ to 0.08″. The handle rib 605 may be configured to provide additional crush resistance strength at an anticipated stress point along an interior surface of the handle 650.
The lower end of the handle 650 may be defined by a lower concave handle perimeter curve circumscribing the handle 650 and joining the sidewalls of the handle 650 with the face surface 601, convex perimeter curve 603, and/or perimeter groove 604. As shown in the figures, the handle 650 intersects the convex perimeter curve 603 at the lower end, and therefore the lower concave handle perimeter curve intersects the convex perimeter curve 603. Moreover, as shown in the figures, the lower end of the handle 650 is partially bounded by a protruding strap portion 651 extending between the outer edge of the perimeter groove 604 and the lower end of the handle 650. The protruding strap portion 651 has a convex profile (parallel with the plane of symmetry A) and is configured to distribute the portion of vertical crushing forces transmitted from the container spout 500 along the handle 650 to avoid a compressive stress concentration point at the lower end of the handle 650. The protruding strap portion 651 interrupts the perimeter groove 604 such that compressive forces transmitted along the length of the handle 650 are distributed over the sidewall 11, and are not concentrated within the perimeter groove 604. Like the remaining portions of the handle 650 (including both the upper end and the lower end of the handle 650), the protruding strap portion 651 may be hollow and may have a sidewall thickness at least substantially equal with the sidewall thickness of the remaining portions of the container 1.
As shown in the side-view of
As mentioned herein, the container 1 may have an ovular shape mirrored about the plane of symmetry A, and having a major axis aligned with the plane of symmetry A and a minor axis perpendicular to the plane of symmetry A. In such embodiments, the handle 650 is aligned with the major axis of the container 1.
Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the inventions are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.