This invention relates to pressurized containers, and more particularly to pressurized containers having an internal container, such as a bag, for dispensing contents through a nozzle.
Some conventional aerosol can assemblies include a can body, a cap coupled to the can body, a nozzle disposed in the cap, and an inner container, such as a bag. A product is disposed in the bag, and the plenum outside of the bag is pressurized. Accordingly, upon creating an opening by actuating the nozzle, product is dispensed out of the can. In many popular configurations, an end of the bag is disposed in the coupling or seam between the nozzle and the cap, and in other prior art references the bag is disposed in the coupling or seam between the cap and the can body.
Bags are often formed of a nylon material having good barrier properties to common propellants, such as propane or isobutene. Because conventional bags are prone to damage if not within a particular humidity range, the bags may be damaged while being inserted through the top opening in the cap, which typically is smaller than the bag diameter. Also, conventional bags are prone to being ruptured in some conventional processes in which bags are formed as part of a seam or crimp—either between the cap and nozzle assembly or between the cap and body.
A pressurizable can assembly, which is capable of dispensing a product disposed therein, includes a body including a body sidewall and a seam portion; an enclosed lower portion disposed at a bottom of the body; and a cap including a cap sidewall and a seam portion. The body seam portion and the cap seam portion form a seam for securing the body to the cap. Also, a nozzle assembly is disposed at an upper portion of the cap. A portion of the body and a portion of cap form a throat formed therebetween. The throat, which may include an annulus that is separated from the main portion of the container by a constriction, generally terminates proximate or at the seam. An inner container, such as a bag, is disposed at least partly in the can body and includes peripheral thickened portion at an upper edge thereof. The thickened portion is disposed in the throat and spaced apart from the seam.
Preferably, the body includes a neck and the cap includes a neck, and the throat is formed between the body neck and the cap neck. The bag flange terminates in a bulb such that the bulb is disposed in the annulus. The bulb is larger than the opening of the constriction, which prevents the bag flange from pulling out of the throat.
The bag preferably is formed by a thermoforming process, including the steps of heating a billet, disposing the billet into mold, deforming a portion of the billet to form the flange of the inner container, and deforming another portion of the billet to form the body of the inner container. The step deforming the portion of the billet includes deforming a periphery of the billet between a top mold flange and a bottom mold flange. A space between the top mold flange and bottom mold flange has a shape corresponding the bulbous end of the inner container flange. At least one of the top mold flange and the bottom mold flange are movable to enable removal of the thermoformed bag. Conventional stretching and blow molding steps may also be employed.
Accordingly, a method of forming a can assembly according to the above components and methods are also encompassed.
As illustrated in
Body 12 includes a sidewall 22 and a neck 24. Preferably, body sidewall 22 is cylindrical and, in transverse cross section (not shown in the figures), circular.
In some configurations, such as end 16a shown in
As shown in
Cap 14 includes a cap sidewall 28 and a cap neck 30. Preferably, cap 14 is circular in transverse cross section (not shown in the Figures) so as to mate to body 12, and dome-shaped. As shown in
As shown in
In a typical embodiment, bag body 50 has a wall thickness of approximately 0.006 inches, thickened portion 54 has a wall thickness of approximately 0.020 inches, and bulb 56 is partly substantially circular with a diameter of approximately 0.032 inches, and bag 20 is approximately 5.5 inches tall and 1.52 inches diameter in the body and 1.86 inches diameter at the outermost portion of flange 52. Bag 20 is preferably formed of a nylon or other conventional material, as will be understood by persons familiar with aerosol container technology and consistent with the particular propellant employed. The particular material, configuration, and thicknesses of bag 20, however, may be chosen to suit the particular parameters (such as composition of propellant and product contents, design internal pressure within the plenum and bag, design shelf life, and the like, as will be understood by persons familiar with aerosol container technology and engineering).
Nozzle 18 is illustrated schematically in
Referring to
Seam 34, according to the configuration described above, may have an outermost diameter that is smaller than a maximum diameter of can assembly 10, and more preferably, smaller than a diameter of a diameter of body sidewall 22. For example, seam 34 may have an outermost diameter of approximately 1.99 inches. Such a configuration enhances packing of cans. The present invention, however, is not limited by the type of coupling between body 12 and cap 14 (unless so specified in the claims). Seam 34, with respect to both its final structure and to the configuration of the components of the body and cap entering the seamer, preferably is conventional.
A portion of body neck 24 and cap neck 30 are mutually spaced apart to form a throat 40, which includes a constriction 44 at an entrance to throat 40 and an annulus 42. Annulus 42 has a minimum dimension (in longitudinal cross section as shown in
In the embodiment shown in
Constriction 44 is configured such that necks 24 and 30 contact thickened portion 54 in order to form a seal therewith between the propellant on the underside of flange 52 and the product contents inside bag 20. Preferably, constriction 44 defines an opening dimension of approximately 0.018 inches. Accordingly, bag thickened portion 54 is slightly compressed by the portions of neck 24 and 30 to compress bag thickened portion 54. Because bulb 56 has a dimension larger than the opening at constriction 44, bulb 56 prevents bag 20 from being pulled out (that is, radially inwardly) from throat 40. Body sidewall 22 is substantially aligned with cap sidewall 28 so as to transmit downward force, such as may occur during stacking of can assemblies during shipping and handling, without damaging bag 20. Bag 20 being spaced apart from seam 34 diminishes the tendency for a downward force to rupture bag 20. For example, annulus 42 may be configured such that bulb 56 is compressed to a degree less than or approximately equal to the compression of thickened portion 56 at constriction 44, or configured such that bulb 56 is not compressed.
To form bag 20, a billet 48, as schematically shown in
Billet 48, which is heated typically to approximately 400 hundred degrees (although the heating temperature may be chosen according to the desired parameters of the particular application), is disposed in a mold 60 between a pair of matched mold flanges, such as an upper mold flange 62 and a lower mold flange 64. Mold 60 is shown in
Mold flanges 62 and 64 form a cavity that matches the shape of bag flange 52. Accordingly, bulb 56 and thickened portion 54 are formed by the matched mold flanges 62 and 64. The remainder of bag 20, including bag body 50 and possibly a lowermost portion of thickened portion 54 and/or a transition between body 50 and thickened portion 54, is formed during further deformation of billet 48 against an inner surface of mold 60. For example, a stretch rod may downwardly urge against a center of billet 48 to elongate it, after which air may be employed to blow the extended billet outwardly against the mold inner surface.
After thermoforming, upper mold flange 62 may move relative to lower mold flange 64, as indicated by the arrow in
Such a thermoforming process is capable of producing a great number of bags, such as bag 20, compared with conventional extrusion blow molded bags. For example, conventional thermoforming processes may produce 250,000 bags per day compared with a conventional extrusion blow molding process that may produce 15,000 bags per day.
Another embodiment of the can assembly is illustrated in
Cap 114 includes a cap sidewall 128 and a cap neck 130. Preferably, cap 114 is circular in transverse cross section (not shown in the Figures) so as to mate to body 112, and frustoconical shaped to a point where necks in toward its upper curl. As shown in
A portion of body neck 124 and cap neck 130 are mutually spaced apart to form a throat 140, which includes a constriction 144 at an entrance to throat 140 and an annulus 142. Annulus 142 has a height or minimum dimension (in longitudinal cross section as shown in
In the embodiment shown in
Because bulb 56 has a dimension larger than the opening at constriction 144, bulb 156 prevents bag 120 from being pulled out (that is, radially inwardly) from throat 40. Inner thick portion 154 may prevent bag 120 from being forced radially outwardly through a throat 140. The features and, where appropriate, dimensions, of the embodiment shown in
To form can assembly 10, cap 14 is positioned on body 12 such that cap neck 30 is disposed proximate body neck 24. Flanges (not shown in
The configurations disclosed herein illustrate particular embodiments of the present invention. The present invention, however, is not limited to the particular embodiments or configurations shown or explicitly described. Rather, the present invention encompasses numerous variations of the particular structure shown and described herein, as will be understood by persons familiar with conventional aerosol can technology in view of the present disclosure.