The present disclosure relates to a novel insert for an actuator of a pressurized aerosol valve and, more particularly, to a dual component insert which comprises both a support insert and a separate insert disk which has a uniform and well-defined discharge orifice which is designed to discharge the product to be dispensed in a fine mist spray pattern.
Pressurized aerosol products typically comprise a container, usually a cylindrical metal can, containing both a propellant gas or compressed air along with the desired product to be dispensed and a valve assembly and actuator for controllably dispensing of the product as an aerosol. One end of the container is closed by a metal dome which is crimped and sealed to the upper side wall of the container and has a central opening for receiving a metal mounting cup which is crimped and sealed to the dome. The mounting cup, in turn, has a central pedestal with a central opening for mounting a conventional valve assembly thereto. A first end of a dip tube is connected with a lower portion of the valve assembly. The valve assembly provides a controllable flow passage from an inlet, formed in a second free end of the dip tube which extends downward and communicates with the product to be dispensed, typically located in the bottom portion of the aerosol container, to an outlet formed at a remote end of a valve stem which extends through the central opening in the pedestal and supports an actuator. The actuator, in turn, generally has a flow passage, extending from the outlet of the valve stem, through the body of the actuator and to a discharge outlet formed in the actuator. The discharge outlet typically accommodates a discharge member, normally in the form of an insert, which is sized and shaped to engage with the discharge outlet and provide the desired discharge spray pattern for the product when dispensed. The actuator, when depressed, moves vertically downward, with respect to the valve assembly and the pedestal, and actuates the valve assembly to open the valve so that the product to be dispensed can then flow through and along the controllable flow passage of the valve assembly and the actuator and eventually be dispensed through the discharge outlet of the actuator.
When the actuator is released, the valve assembly is biased, by a spring, back into its normally closed position to prevent further dispensing of product though the valve assembly. Such biasing action of the spring also, in turn, returns the actuator back to its normally extended position, with respect to the pedestal, so that the actuator is then repositioned to be again depressed, by an operator, and thereby facilitate further dispensing of product from the container.
Known actuators and inserts are typically formed from molded plastics and the like. One problem which frequently occurs with such known actuators and inserts is that it is often very difficult to manufacture inserts with small diameter orifices—in a consistent, reliable, and uniform manner—through which the product can be dispensed in a desired spray pattern.
Wherefore it is an object of the present disclosure to overcome the above-mentioned shortcomings and drawbacks associated with the prior art actuators and inserts with smaller dispensing orifices.
The present disclosure relates to a dual component insert for use with a spray actuator for dispensing a pressurized product, the dual component insert comprising: a support insert comprising: a base wall having a support discharge orifice formed therein; a cylindrical wall being formed integral with and extending from the base wall so as to define an insert cavity; an insert disk having a disk discharge orifice; a diameter of the disk discharge orifice being smaller than a diameter of the support discharge orifice; and the insert disk being received and captively retained within the insert cavity such that the disk discharge orifice is axially aligned with the support discharge orifice.
The present disclosure also relates to an actuator for dispensing a pressurized product, the actuator comprising both: a dual component insert comprising: a support insert comprising: a base wall having a support discharge orifice formed therein; a cylindrical wall being formed integral with and extending from the base wall so as to define an insert cavity; an insert disk having a disk discharge orifice; a diameter of the disk discharge orifice being smaller than a diameter of the support discharge orifice; and the insert disk being received and captively retained within the insert cavity such that the disk discharge orifice being axially aligned with the support discharge orifice; a spray actuator comprising: a housing having an inlet communicating, via a passageway, with an actuator discharge cavity; the actuator discharge cavity being opened at one end and having a cylindrical post located therein supporting a mechanical break-up on an end face; and the dual component insert being received and captively retained within the actuator discharge cavity of the spray actuator so as to seal the opened end of the actuator discharge cavity and facilitate dispensing of product through the mechanical break-up and the axially aligned disk and support discharge orifices.
Yet another aspect of the present disclosure relates to an actuator for dispensing a pressurized product, the actuator comprising both: a dual component insert comprising: a support insert comprising: a base wall having a support discharge orifice formed therein; a cylindrical wall being formed integral with and extending from the base wall so as to define an insert cavity; an insert disk having a disk discharge orifice and the disk discharge orifice having a diameter ranging from about 0.002 of an inch to about 0.010 of an inch; the insert disk having an insert disk diameter ranging from about 0.100 of an inch to about 0.160 of an inch, and the insert disk having a thickness ranging from about 0.003 of an inch to about 0.007 of an inch; a diameter of the disk discharge orifice being smaller than a diameter of the support discharge orifice; the insert disk being received and captively retained within the insert cavity such that the disk discharge orifice being axially aligned with the support discharge orifice; a spray actuator comprising: a housing having an inlet communicating, via a passageway, with an actuator discharge cavity; the actuator discharge cavity being opened at one end and the actuator discharge cavity having a cylindrical post located therein supporting a mechanical break-up on an end face thereof; the cylindrical post supporting a plurality of spaced apart fins, and each of the plurality of spaced apart fins extending radially and axially from the cylindrical post; the dual component insert being received and captively retained within the actuator discharge cavity so as to seal the opened end of the actuator discharge cavity and facilitate dispensing of product through the mechanical break-up and the axially aligned disk discharge orifice and the support discharge orifice; and the spray actuator being supported by a valve stem which is coupled to a valve assembly, an inlet of the valve assembly supporting a dip tube for conveying the product to be dispensed to the valve assembly, and the valve assembly being secured to a mounting cup.
Still another aspect of the present disclosure is to manufacture the insert disk from a first non-moldable material, such as a metal, and manufacture the support insert from a second moldable material, such as plastic, e.g., acetal.
A further aspect of the present disclosure is to manufacture the insert disk from a relatively thin durable material which can be punched, drilled, machined or otherwise fabricated so as to have a consistent, accurate, uniform and well defined small diameter discharge orifice formed therein which results in discharging of the product to be dispensed as a fine mist spray.
Yet another aspect of the present disclosure is to manufacture the support insert and the insert disk as two completely separate components and from two different materials and, thereafter, subsequently assemble those two components with one another to form the dual component insert.
The above aspects of the disclosure are not meant to be exclusive and other features, aspects, and advantages of the present disclosure will be readily apparent to those of ordinary skill in the art when read in conjunction with the following description, appended claims, and accompanying drawings.
The foregoing and other objects, features, and advantages of the disclosure will be apparent from the following description of particular embodiments of the disclosure, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the disclosure.
Referring first to
The actuator 2, in turn, generally defines a flow passage 18 which extends from the inlet 4, through the body of the actuator 2 to a discharge cavity opening 20 that facilitates conveyance of the pressurized product 22 into a discharge cavity 24 of the spray actuator 2. The discharge cavity 24 is defined by a base surface 26 and an inwardly facing cylindrical side wall 28 of the housing 3. The base surface 26 supports a centrally located cylindrical post 29 which is formed integrally with the base surface 26. The discharge cavity 24 is opened at the end thereof which is opposite the base surface 26. An insert 38, provided with a discharge outlet 48, is captively received, accommodated and retained within the discharge cavity 24 to close the discharge cavity 24. The discharge outlet 48 is sized and shaped to form the desired discharge spray pattern for the product to be dispensed 22 when the product to be dispensed flows into the discharge cavity 24, through a conventional mechanical break-up 40 (only diagrammatically shown) and out through the discharge outlet 48.
A top exterior surface of the spray actuator 2 is provided with a finger recessed area 16, which is typically contoured to facilitate depression of the spray actuator 2 by a finger, e.g., an index finger, of a user. The actuator 2, when depressed by an operator depressing the top finger recessed area 16, moves vertically downward, with respect to the valve assembly 10 and the pedestal, and actuates the valve assembly 10 to open the valve assembly so that the product 22 (see
As shown in
The remote end of the valve stem 8 is received within the product inlet 4 of the spray actuator 2 (
An outwardly facing side wall 32 of the cylindrical post 29 carries a plurality of equally spaced support fins 34, e.g., three or possibly four or more equally spaced support fins. A portion of each one of the support fins 34, adjacent the base surface 26, is provided with a radially extending stop shoulder 36 while the opposite end of the fins 34 is each provided with a chamfer 37 which facilitates receiving an insert 38 with the discharge cavity 24. The support fins 34 are located, sized and shaped to facilitate centering of the insert 38 as the insert 38 is received within the discharge cavity 24. The shoulders 36 are designed to prevent over-insertion of the insert 38 into the discharge cavity 24.
The discharge orifice 48 is formed centrally in an inwardly facing planar base surface 50 of the insert 38 and the discharge orifice 48 extends completely through the base wall 49 to an outwardly facing planar base surface 51 thereof. A cylindrical side wall 52 extends normal to a peripheral edge of the base wall 49. An inwardly facing cylindrical side wall 58 generally mates, e.g., has a slight interference fit, with the fins 34 when the insert 38 is received within the discharge cavity 24. An outwardly facing surface of the cylindrical side wall 52 supports an outwardly facing annular lip 54 (see
The axial length of the side wall 52 of the insert 38 and/or the axial height of the shoulders 36 of the fins 34 are selected such that when the insert member 38 is fully inserted into and received by the discharge cavity 24, an end face 56 (see
According to previous insert arrangements, it is difficult to reliably, consistently and accurately manufacture smaller diameter discharge orifices 48, e.g., less than 0.010 of an inch and more preferably less than 0.0055 of an inch for example, which have a uniform and well defined cylindrically shaped discharge orifice 48 formed in a base wall of the insert 38. That is, following release from the mold, the partially cooled plastic material, from which the insert 38 is manufactured, is still generally partially molten and flowable. As the insert 38 continues cooling, following ejection from the mold, the molten material defining the sidewall of the discharge orifice has a tendency to modify/deform/alter the originally manufactured size and shape, e.g., typically cylindrical, of the discharge orifice 48. Due to the relatively small size of the discharge orifice 48, even a small amount of modification/deformation/alteration of the sidewall, defining the discharge orifice 48, can significantly alter the flow characteristics of the product flowing through the discharge orifice 48 and thereby the discharge characteristics of the fine particle spray emitted from the discharge orifice 48.
As briefly alluded to above, conventional inserts are typically formed from polymer resins that are melted, injected into a mold, allowed to partially solidify, and then removed from the mold and subsequently allowed to gradually cool further. These resins require properties such as low friction, wear resistance, high strength, stiffness, impact resistance and the like. The current formation processes for inserts makes it very difficult to achieve a uniform, consistent and accurately sized and shaped discharge orifice 48 for an insert, particularly for a fine mist and spray application.
Referring now to
Also according to the present invention, the spray actuator 2 is typically manufactured from a softer material, such as polyethylene or polypropylene, while the support insert 38′ is preferably manufactured from a relatively harder molded plastic material, such as acetal, than the spray actuator 2.
Turning now to
The support insert 38′ typically has a height that ranges from about 0.100 of an inch to about 0.150 of an inch, and more preferably is about 0.120 of an inch. An inwardly facing cylindrical side wall of the support insert 38′ typically has a diameter (IMD) that ranges from about 0.098 of an inch to about 0.152 of an inch, and more preferably ranges from about 0.141 of an inch to about 0.145 of an inch. As shown in
Turning now to
Now that the features of both the support insert 38′ and the insert disk 64 have been briefly described, assembly of these two components with one another to form the dual component member 38″, as shown in
As noted above, the outer diameter DID of the insert disk 64 is selected to be slightly larger, e.g., typically by 0.001-0.003 of an inch or so, than the diameter IMD of the inwardly facing cylindrical side wall of the support insert 38′. As a result of such slight interference fit, once fully seated, the insert disk 64 is captively and generally permanently retained within the insert cavity 44 of the support insert 38′ and thus does not become separated or dislodged therefrom during subsequent handling and assembly of the dual component member 38″. That is, the insert disk diameter DID is normally sized to have an interference fit with the inwardly facing cylindrical side wall 58 of the support insert 38′ which ensures that the insert disk 64, once suitably received or inserted within the insert cavity 44, will not be inadvertently dislodged therefrom.
According to another embodiment of the dual component member 38″ as generally shown in
In still another embodiment of the dual component member 38″ as shown in
Turning now to
The primary difference between this embodiment and the previous embodiment is the size and shape of the insert discharge orifice 48′. According to this embodiment, the insert discharge orifice 48′ has a larger diameter than the previous embodiment and the shape of the insert discharge orifice 48′ is also modified. Since the insert discharge orifice 48′ has a larger diameter, the thickness of the base wall 49 of the support insert 38′ may be increased to provide additional support for the insert disk 64 and prevent the same from becoming inadvertently deformed or spaced away from the mechanical break-up 40 during dispensing of the product 22 to be dispensed. It is to be appreciated that the overall shape, size and diameter of the insert discharge orifice 48′ can vary, from application to application, as long as the insert discharge orifice 48′ is sufficiently large to facilitate dispensing of the product 22 to be dispensed through the disk discharge orifice 67.
The insert disk 64, is fabricated—not molded—from a material that renders it much easier to uniformly and consistently manufacture the cylindrical side wall which defines the disk discharge orifice. The ability to reproduce accurately controlled and well defined smaller diameter discharge orifice, for an insert, is important for a variety of different applications. The ability to manufacture molded inserts having wider and less consistent discharge orifices considerably reduces costs as well. It is to be appreciated that the overall size, shape and diameter of the disk discharge orifice 67 can vary from application to application without departing from the spirit and scope of the present invention. The important aspect of the disk discharge orifice 67 is that it provides a uniform, well-defined and consistent disk discharge orifice 67 which facilitates dispensing of the product 22 to be dispensed in a fine mist spray pattern.
The inventor hereby states his intent to rely on the Doctrine of Equivalents to determine and assess the reasonably fair scope of his invention as it pertains to any apparatus not materially departing from but outside the liberal scope of the invention as set forth in the following claims.
While the principles of the disclosure have been described herein, it is to be understood by those skilled in the art that this description is made only by way of example and not as a limitation as to the scope of the disclosure. Other embodiments are contemplated within the scope of the present disclosure in addition to the exemplary embodiments shown and described herein. Modifications and substitutions by one of ordinary skill in the art are considered to be within the scope of the present disclosure.