This invention relates to a closure and container combination forming a surface seal.
Many different kinds of packaged products, such as food, beverages and pharmaceuticals, can be adversely impacted through exposure to oxygen. The presence of oxygen in a package can cause oxygen contamination of the product being stored therein. The reaction of oxygen with chemicals present in foods and beverages can impact their odor and flavor. The reaction of oxygen with pharmaceuticals can impact their efficacy.
Molecular oxygen (O2) can react with a number of different compounds that are found in a number of foods and beverages. Molecular oxygen can be reduced by other molecules through the addition of electrons to form, e.g., a superoxide, a hydroxyl radical, or hydrogen peroxide. Each of these reduced forms of oxygen is very reactive and is thus likely to react with a number of products in the food and beverage industry. The reduced forms of oxygen are especially likely to react with the carbon-carbon double bonds found in almost all products with complex organic components. This reaction can cause the rapid degradation of the product. For example, the oxidated product may have an altered odor or flavor.
During storage of containers, particularly after any initial seal has been ruptured by a first opening of a container, often air, including oxygen, can leak and migrate into an ostensibly closed container through gaps between the container and the closure. This influx of oxygen and other airborne contaminants can be detrimental to the materials stored in the container. For this and other reasons, it is preferable to have a container and closure combination that forms a good seal.
Accordingly, a container and closure combination is provided. The container preferably has a neck with a base portion and a flexible upper portion. The upper portion has a proximal segment that is oriented in a first inward angle relative to the base portion and a distal segment that is oriented in a second inward angle relative the base portion.
The closure preferably has a generally planar top portion, an outer peripheral edge portion, and an annular skirt depending from the peripheral edge portion. Preferably, the top portion has at least one inner flange and at least one outer flange depending therefrom. The outer flange can be relatively flexible with an angled inner surface. The angled inner surface can correspond to the first inward angle of the proximal segment such that the inner surface of the outer flange is generally 0.0 to 6.0 degrees offset from that surface. Preferable, the inner surface of the outer flange is generally 1.0 to 3.0 degrees offset. The inner flange can be relatively rigid and have an outer angled surface.
Preferably, the angled inner surface of the outer flange and the outer angled surface of the inner flange define a channel that is capable of receiving a part of the upper portion of the neck of the container. When received, the inner flange biases the part of the upper portion of neck that is in the channel against the outer flange, specifically against the inner surface of the outer flange. Preferably, the part of the upper portion is engaged in such a manner that at least part of an upper surface of the proximal segment of the neck and at least part of the inner surface of the outer flange form a surface seal.
While the present invention is susceptible of embodiments in various forms, there will hereinafter be described some exemplary and non-limiting embodiments, with the understanding that the present disclosure is to be considered an exemplification of the invention and is not intended to limit the invention to the specific embodiments illustrated.
As seen in
The closure 10 preferably has a generally planar top portion 18, an outer peripheral edge portion 14, and an annular skirt 16 depending from the peripheral edge portion 14. Preferably, the top portion 18 is circular and has at least one inner flange 40 and at least one outer flange 50 depending therefrom. Preferably, the outer flange 50 forms a first circular ring 62 which has a first diameter. The outer flange 50 is one continuous formation forming the first ring 62. The outer flange 50 is relatively flexible when compared to the inner flange 40. The outer flange 50 can have an angled inner surface 52 and an outer surface 54. The angled inner surface 52 is preferably at an angle off a vertical line about 5 to 80 degrees from the top portion. More preferably, the angled inner surface 52 is at an angle about 10 to 70 degrees from the top portion 18. Most preferably, the angled inner surface 52 is at an angle of about 30 degrees off vertical from the top portion 18. Preferably, the outer surface 54 is oriented substantially perpendicular to the top portion 18. The outer flange 50 can have a cross-sectional shape of a right triangle with the inner angled surface being the hypotenuse.
The inner flange 40 should be relatively rigid compared to the outer flange 50 and have an outer angled surface 42. It should have a triangular cross-sectional shape.
As shown in
The inner flange 40 and outer flange 50 each have a height which is the distance that they depend from the top portion 18. In one embodiment, the inner flange 40 and outer flange 50 have the same height. In another embodiment, the inner flange 40 has a greater height than the outer flange 50. In another embodiment, the inner flange 40 has a lesser height than the outer flange 50.
In one embodiment, the inner flange 40 and outer flange 50 can be oriented in concentric rings 62, 64 on the top portion 18. The inner flange 40 and outer flange 50 define a channel 66 between them. Preferably, the channel 66 is capable of receiving a part 68 of the upper portion 30 of the neck 22. Preferably, the part 68 of the upper portion 30 of the neck 22 includes the distal segment 36 and a portion of the proximal segment 32. Preferably, the upper portion 30 of the neck 22 is flexible. When received, the inner flange 40 biases the part 68 of the upper portion 30 of neck 22 that is in the channel 66 against the outer flange 50. The inner flange 40 can act like a backstop that causes the upper portion 30 of the neck 22 to become wedged in the channel 66. Preferably, the surface 34 of part 68 of the upper portion 30 of the neck 22 is biased against the inner surface 52 of the outer flange 50. Preferably, the part 68 of the upper portion 30 forms a surface seal between the surface 34 of part 68 and the inner surface 52. More preferably, at least part of an upper surface 34 of the proximal segment 32 of the neck 22 and at least part of the inner surface 52 of the outer flange 50 form a surface seal. Generally, the upper portion 30 of the neck will not form a seal with the inner flange 40. As used herein, the term surface seal is a joining along a surface of a first object and a surface of a second object for a distance along both surfaces. As such, the surface seal defines an area. This would be in comparison to a line seal, which would be a joining of an edge of one object and the surface of a second object. In addition, under certain conditions, upper surface 34 may contact the inner surface 42 or the top portion 18 of the closure 10 to form a secondary seal.
To effectuate the surface seal, it is preferred that the slope of the distal segment 36 of the neck 22 and the slope of the inner surface 52 of the outer flange 50 are relatively similar. For example, in one embodiment, the proximal segment 32 has a slope that is about 0 to 6.0 degrees offset from the inner surface 52 of the outer flange 50. Preferably, the proximal segment 32 has a slope that is about 1.0 to 3.0 degrees offset from the inner surface 52. When biased, the upper surface 38 of the proximal segment 32 and the inner surface 52 of the outer flange 50 are abutted or pushed together to form a surface seal.
As shown in
The closure 110 preferably has a generally planar top portion 118, an outer peripheral edge portion 114, and an annular skirt 116 depending from the peripheral edge portion 114. Preferably, the top portion 118 is circular and has at least one inner flange 140 and at least one outer flange 150 depending therefrom. The outer flange 150 is relatively flexible when compared to the inner flange 140. The outer flange 150 can have an angled inner surface 152 and an outer surface 154. The angled inner surface 152 is preferably at an angle about 5 to 80 degrees off vertical from the top portion 118. More preferably, the angled inner surface 152 is at an angle about 10 to 70 degrees from the top portion 118. Most preferably, the angled inner surface 152 is at an angle of about 30 degrees off vertical from the top portion 118. Preferably, the outer surface 154 is oriented substantially perpendicular to the top portion 118. The outer flange 150 can have a cross-sectional shape of a right triangle with the inner angled surface being the hypotenuse.
The inner flange 140 can be relatively rigid compared to the outer flange 150 and have an outer angled surface 142. The inner flange 140 can have a triangular cross-sectional shape. The outer angled surface 142 of the inner flange 40 is preferably at an angle of about 40 to 85 degrees from the top portion 118. More preferably, the outer angled surface 142 is at an angle of about 60 degrees from the top portion 118. The inner flange 140 can have a cross-sectional shape of an isosceles triangle.
The inner flange 140 and outer flange 150 each have a height which is the distance that they depend from the top portion 118. In one embodiment, the inner flange 140 and outer flange 150 have the same height. In another embodiment, the inner flange 140 has a greater height than the outer flange 150. In another embodiment, the inner flange 140 has a lesser height than the outer flange 150.
The inner flange 140 and outer flange 150 define a channel 166 between them. Preferably, the channel 166 is capable of receiving a part of the distal segment 136 of the neck 122. The distal segment 136 can be composed of PET and be relatively inflexible. When received, the inner flange 140 biases the distal segment 136 that is in the channel 166 against the outer flange 150. The inner flange 140 can act like a backstop that causes part of the distal segment 136 of the 122 to become wedged in the channel 166. Preferably, the distal segment 136 is biased against the inner surface 152 of the outer flange 150. Preferably, the outer wall 138 of the distal segment 136 forms a surface seal with the inner surface 152 of the outer flange 150. To allow for the surface seal, it is preferred that the inner surface 152 has a slope that is about 0 to 6.0 degrees offset from the slope of the outer wall 138. More preferably, the inner surface 152 has a slope that is about 1.0 to 3.0 degrees offset from the slope of the outer wall 138. The inner wall 139 of the distal segment 136 of the neck 122 may form a surface seal with the inner flange 140.
The closure 10 can be comprised of a variety of different materials that are known in the art. The closure 10 can be comprised of plastic including the specific plastic PET. The container 20 can be comprised of a variety of different materials, including plastic.
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Number | Date | Country | |
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20080169262 A1 | Jul 2008 | US |