1. Technical Field
The present invention relates generally to valves for fluid control valves and more particularly to valve devices and methods flow liquid product and propellant gas in a liquid product dispensing device.
2. Background Art
Devices for dispensing liquids are generally known in the art. Such conventional devices generally include a container for storing a liquid product and a means for ejecting the liquid product from the container through a dispensing head or a nozzle. Such conventional delivery means often include a reservoir of pressurized gas stored in the container. The pressurized gas serves as a propellant for forcing the liquid product out of the container.
Such conventional devices often include a dispenser head including a depressible pump or actuator for manual manipulation by a user. By depressing the dispenser head, a user may selectively open a valve or other mechanism that allows the pressurized gas, or gas propellant, to force the liquid product through the valve and out of the dispensing head for application or use. Such conventional devices are commonly used to store and dispense liquid products including cosmetic products. A cosmetic product, or a cosmetic liquid, may be referred to as a hair spray, a deodorant, a foam, a gel, a coloring spray, a sunscreen, a skin care agent, a cleaning agent or the like.
In some applications, it is generally desirable to provide a dispensing device for a liquid product, such as a cosmetic product, that achieves an atomized spray of the liquid product upon ejection from the dispensing device. Generally, it is preferable to provide an atomized spray of fine particles that are relatively small and uniformly sized. Conventional dispensing devices for delivery of cosmetic products are inadequate because such devices do not provide a uniform dispersion of atomized particles having optimal small sizes. Instead, conventional dispensing devices often provide atomized liquid dispersions or sprays that include non-uniformly sized particles.
Another problem associated with conventional dispensing devices for liquid products includes clogging of the channels in the dispensing device. For example, it is generally known in the art that atomized sprays can be generated to include smaller particles by providing a smaller diameter orifice at a spray nozzle exit. However, by reducing the dimensions of the spray nozzle exit, the more likely it is that the exit orifice will become clogged by the liquid product. This is especially true for liquid products that have adherent properties, such as cosmetic products, hair sprays, skin sprays, fragrance sprays, deodorant sprays, paints, glues, pesticides, etc.
In order to overcome the problems associated with conventional devices and methods for delivering a liquid product from a dispensing device as an atomized spray, it may be necessary to initiate the flow of gas prior to initiating flow of the liquid product and to also terminate flow of liquid prior to termination of flow of gas. However, conventional delivery valves do not provide such sequential delivery and termination of liquid product and gas propellant.
What is needed then are improvements in valve devices and methods for sequential delivery of liquid products and gas propellants in the form of an atomized spray.
An object of the present disclosure is to provide a sequential delivery valve and associated methods for providing sequential delivery of gas propellant and liquid product from a container into a dispensing head for ejection of an atomized spray from the dispensing head.
A sequential delivery valve may include a product that is combined with a dispensing head and a container to form a dispensing device having a sequential delivery capability.
A sequential delivery valve may prevent clogging of a dispensing head by providing a flow of gas propellant into the dispensing head prior to allowing liquid product to flow into the dispensing head upon actuation of the dispensing head. The gas propellant may clear any debris from the dispensing head or establish necessary gas flow patterns for liquid product atomization prior to introduction of the liquid product into the dispensing head.
Similarly, upon release of the dispensing head, a sequential delivery valve may terminate flow of the liquid product into the dispensing head prior to terminating flow of the gas propellant into the dispensing head. By allowing the gas propellant to flow into the dispensing head after liquid product flow is terminated, the gas may clear out any residual liquid product that could otherwise remain in and block the dispensing head.
In some embodiments, the present disclosure provides a sequential delivery valve apparatus for sequentially delivering a gas propellant and a liquid product to a dispensing head from a container for ejecting an atomized spray of the liquid product from the dispensing head. The valve includes a primary housing defining a primary chamber, the primary housing including a primary housing end wall and a primary housing exit, the primary housing also including a gas port configured for introduction of the gas propellant into the primary chamber from the container. The valve also includes a pusher disposed in the primary housing, the pusher being axially moveable relative to the primary housing, the pusher including a pusher bore, the pusher bore including a pusher port open to the secondary chamber. The valve also includes a primary seal disposed between the pusher and the primary housing end wall. A secondary housing defines a secondary chamber. The secondary housing is positioned at least partially inside the primary chamber. The secondary housing is axially moveable relative to the primary housing and the pusher. The secondary housing also includes a liquid port configured for introduction of the liquid product into the secondary chamber from the container. A secondary seal is disposed between the pusher and the secondary chamber. The pusher includes a first axial position wherein the primary seal engages both the pusher and the primary housing end wall, and wherein the secondary seal blocks the pusher port. The pusher includes a second axial position wherein the primary seal is disengaged from the primary housing end wall, and wherein the secondary seal blocks the pusher port. The pusher also includes a third axial position wherein the primary seal is disengaged from the primary housing end wall, and wherein the secondary seal is disengaged from the pusher port.
In a further embodiment, the present disclosure provides a valve apparatus for sequentially delivering a gas propellant and a liquid product from a container to a dispensing head for ejecting the liquid product from the dispensing head in the form of an atomized spray. The valve includes a primary housing defining a primary chamber and a secondary housing defining a secondary chamber. A pusher includes a pusher disk disposed in the primary chamber and a pusher head disposed in the secondary chamber. The pusher includes a secondary seal disposed between the pusher disk and the pusher head. When the pusher is axially translated toward the container, gas propellant is allowed to travel through the valve into the dispensing head before liquid product is allowed to travel through the valve into the dispensing head.
In yet another embodiment, the present disclosure provides a method of preventing clogging of a dispensing head on a dispensing device. The method includes the steps of: (a) providing a sequential delivery valve between a container and a dispensing head, the container including a gas propellant and a liquid product; and (b) introducing the gas propellant through the sequential delivery valve into the dispensing head from the container before introducing the liquid product through the sequential delivery valve into the dispensing head.
Another object of the present disclosure is to provide a sequential delivery valve that provides sequential delivery of gas propellant and liquid product to a dispensing device head for achieving a flow blurring interaction between the liquid and gas for atomization of the liquid.
Numerous other objects, advantages and features of the present invention will be readily apparent to those of skill in the art upon a review of the following drawings and description of a preferred embodiment of the invention.
Referring now to the drawings,
Although the figures illustrate an embodiment of a dispensing device including spray direction oriented at a right angle relative to the actuation direction of the dispensing head, other embodiments not illustrated encompassed within the scope of the present invention include spray directions that are oriented at other angles relative to the actuation direction. For example, in additional embodiments, the device is configured to spray an atomized liquid product at any angle relative to the actuation direction of the dispensing head or parallel with the direction of actuation of the dispensing head.
Referring now to
During use, a user may manually depress dispensing head 104 along an actuation direction, indicated by the arrow in
Dispensing head 104 includes an actuator 118. Actuator 118 generally forms a region of dispensing head 104 that a user manually engages with one or more of the user's fingers in some embodiments. An actuator stem 116 extends from the actuator 118 through the collar opening, as seen in
A valve 12 is attached to actuator 118. In some embodiments, valve 12 may be referred to as a sequential delivery valve. Valve 12 may be attached to collar 108 or container 102 in some embodiments. As seen in
As seen in
A pressurized gas may be stored in container 102 above liquid 78. The pressurized gas may form a gas propellant for forcing liquid 78 upwards through liquid tube 36 and may include a single gas or a gas mixture. A gas tube 72 also extends downward from valve 12. Gas tube 72 allows gas stored in container 102 to enter valve 12. Gas tube 72 may be inserted in a gas port 88 on valve 12 in an interference fit in some embodiments. In other embodiments, gas tube 72 may be attached to a gas tube fitting extending from or attached to valve 12.
In some embodiments, as seen in
In some embodiments, the depth of liquid 78 and the dimensions of container 102 and gas tube 72 are such that gas tube opening 80 does not contact liquid 78 in any orientation of container 102.
Referring to
Primary chamber 30 is closed at its lower end by primary housing cap 20. At the opposite end, primary chamber 30 includes a primary chamber opening 74. Primary chamber opening 74 is partially blocked by a primary seal 26 in some embodiments. Primary seal 26 includes a substantially flat annular seal and generally engages primary housing end wall 18 in some embodiments. Primary seal 26 forms a gas-tight seal between primary chamber end wall 18 and primary seal 26 such that gas stored in primary chamber 30 may not pass freely between primary seal 26 and primary chamber end wall 18 when primary seal 26 engages primary chamber end wall 18. Additionally, when primary seal 26 engages primary chamber end wall 18, gas cannot freely travel through primary chamber 30 into primary housing exit 74.
Referring further to
Also seen in
A pusher disk 48 extends radially outwardly from pusher 40 below pusher bore fitting 65. Pusher disk 48 generally forms an upper pusher disk surface. Primary seal 26 may rest against pusher disk 48 and particularly against upper pusher disk surface when valve 12 is in a closed position. A primary spring 90 is disposed between pusher 40 and primary housing cap 20 in some embodiments. Primary spring 90 includes a compression coil spring in some embodiments. Primary spring 90 may engage the underside of pusher disk 48, as seen in
Pusher 40 also includes a pusher shaft 56 extending below pusher disk 48. Pusher shaft 56 generally includes a smaller diameter than pusher disk 48. Pusher shaft 56 generally extends downward into secondary chamber 32. Pusher shaft 56 extends through a central hole in secondary seal 28. A pusher shaft groove 60, seen in
A pusher port 58 is defined in pusher 40 extending radially through a portion of pusher shaft 56 near the pusher shaft groove 60. Pusher port 58 is generally open to pusher bore 64 at one end and open to pusher shaft groove 60 at the opposite end. Thus, when secondary seal 28 is seated in the pusher shaft groove 60, pusher port 58 is closed. A pusher head 54, seen in
Pusher shaft 56 together with secondary seal 28 blocks the open end of secondary chamber 32. Thus, when liquid enters secondary chamber 32 via liquid port 86, the liquid may fill secondary chamber 32 but cannot pass through secondary chamber 32 when pusher port 58 is closed by secondary seal 28.
During operation, a user may manually depress dispensing head 104 and cause valve 12 to open. Valve 12 generally has three positions. Normally, when dispensing head 104 is not depressed, valve 12 is in a closed position, and no liquid or gas travels through valve 12. When valve 12 is in the closed position, primary seal 26 engages primary housing 14. When valve 12 is in the closed position, pusher 40 is biased upwardly toward primary housing end wall 18 by primary spring 90.
Pusher 40 may be axially displaced away from primary housing end wall 18 such that primary seal 26 disengages from primary housing end wall 18, causing valve 12 to become partially opened. As seen in
Gas stored in container 102 is generally held under pressure higher than atmospheric pressure such that once valve 12 becomes partially opened, the pressurized gas will begin to flow toward and through gas duct 122. If the force applied to actuator 118 on dispensing head 104 is released, primary spring 90 will bias pusher 40 back toward primary housing end wall 18 and cause primary seal 26 to re-engage primary housing end wall 18, thereby stopping the flow of gas into primary housing exit 74 and gas duct 122.
In some applications, the pressure of gas stored in container 102 may be high enough to cause gas to flow through gas duct 122 at an undesirably high flow rate and pressure when valve 12 becomes partially opened. To control the flow rate and pressure of gas through gas duct 122, a flow restrictor 126 may be disposed in gas duct 122. Flow restrictor 126 includes a tubular member having a central restrictor bore. The central restrictor bore has a smaller diameter than the gas duct inner diameter. As such, gas travelling through gas duct 122 must pass through flow restrictor 126. The ratio of the diameter of the central restrictor bore to the inner diameter of the gas duct will determine the pressure drop across the flow restrictor and the resulting flow rate through the gas duct 122. Flow restrictor 126 may be secured in gas duct 122 in an interference fit in some embodiments.
As seen in
Generally, in some embodiments, when pusher 40 is displaced axially downwardly, other parts in valve 12 undergo corresponding displacement inside primary chamber 30. For example, in some embodiments, when pusher 40 is moved axially away from primary housing end wall 18, other features inside primary chamber 30 including secondary housing 16, secondary housing cap 24, secondary seal 28, and secondary spring 92 also move downward inside primary chamber 30.
A secondary housing seal 38, seen in
Referring further to
Valve 12 may be described as attaining a partially open configuration upon movement of pusher 40 from a first position where primary seal 26 disengages primary housing end wall 18 to a second position where secondary housing shoulder 34 engages primary housing cap 20.
Referring now to
Pusher shaft groove 60 may include a ramped upper edge. In some embodiments, secondary seal 28 is fixed to secondary housing 16 and may not continue to move axially downwardly after secondary housing 16 engages and is stopped by primary housing cap 20. As such, pusher 40 may translate relative to secondary seal 28. When pusher 40 translates axially downwardly relative to secondary seal 28 and secondary housing 16, the ramped upper edge of pusher shaft groove 60 may slidably engage and radially compress secondary seal 28. As such, secondary seal 28 may become temporarily dislodged from pusher shaft groove 60, thereby opening pusher port 58 to secondary chamber 32. When pusher port 58 becomes opened to secondary chamber 32, valve 12 becomes fully opened and liquid may: (1) enter valve 12 through liquid tube 36, (2) pass through liquid port 86, (3) enter secondary chamber 32, (4) travel through secondary chamber 32 around pusher head 54 and into pusher port 58, (5) enter and travel through pusher bore 64 toward liquid duct 124, and (6) enter liquid duct 124 on actuator 118 of dispenser head 104 for ejection from the dispensing device.
The downward stroke of pusher 40 is stopped in some embodiments when a structure on dispensing head 104 engages a structure on container 102. In some embodiments, an actuator shoulder 128 is positioned above collar 108 when valve 12 is in a closed position, as seen in
It is noted that in other embodiments, downward travel of pusher 40 may be stopped by other structural features such as components within valve 12. For example, in some embodiments, pusher disk 48 may engage the top of secondary housing cap 24 to stop downward travel of pusher 40. In other embodiments, pusher head 54 may engage secondary housing 16 to stop both downward travel of pusher 40 and flow of liquid from liquid port 86 into secondary chamber 32.
In various applications, it is generally desirable to provide a dispenser device 100 capable of releasing stored propellant gas into the dispenser head before allowing stored liquid product to enter the dispensing head. By initiating gas flow prior to liquid flow, the gas flow may operate to clear any occlusions or other debris in the dispensing head downstream of the valve 12 prior to liquid ejection from valve 12.
Similarly, it is desirable in many applications to terminate ejection of the atomized spray by first terminating emission of the liquid from the valve and subsequently terminating emission of the gas flow from the valve. Allowing the gas to flow from the valve through the dispensing head after the liquid flow has been shut off will clear the dispensing head of leftover liquid that might otherwise clog the dispensing head. This sequential valve operation reduces the likelihood that residual liquid will settle in the dispensing head and clog the device.
To achieve sequential delivery of first gas and then liquid to the dispensing head, and corresponding sequential termination of first liquid and then gas flows to the dispensing head, a sequential delivery valve is provided. In some embodiments, the present disclosure provides a sequential delivery valve, 12, seen for example in an embodiment in
During use, a user may manually depress the dispensing head 104 in the actuation direction to initiate a spray of the liquid product from the dispensing head. The dispensing head 104 in some embodiments includes at least three axial positions, or axial position ranges, along the actuation direction. A first axial position is illustrated in
From the first axial position, the dispensing head may be depressed to a second axial position, or range of second axial positions, nearer the container than the first axial position, as seen for example in
Following delivery of a desired amount, or dose, through the valve 12, the user may release the applied force on the dispensing head 104. Due to primary and secondary springs 90, 92 housed in valve 12, the dispensing head 104 will be biased away from the container 102 and will return toward the first axial position. As the dispensing head returns toward the first axial position, the dispensing head will necessarily pass through the second axial position range at which time the secondary chamber 32 will cease to be in fluid communication with the dispensing head 104. As this occurs, fluid flow through secondary chamber 32 into dispensing head 104 will stop, however gas flow through primary chamber 30 will continue until the dispensing head 104 reaches the first axial position and primary seal 28 re-engages primary housing 14.
In some applications, it is generally desirable to provide a modular dispensing head 104 that includes an actuator 118 and a nozzle insert 130, seen in
Nozzle insert 130 can be configured to produce a spray with desired characteristics. In some embodiments, nozzle insert 130 is configured to provide a violent, or turbulent interaction between a gas propellant travelling through dispensing head 104 and a liquid product travelling through dispensing head 104. A violent interaction may result in turbulent mixing between the gas and the liquid prior to ejection from the dispensing head and may result in production of an atomized spray having uniformly sized particles in a desired size range.
Referring to
A pressure chamber exit orifice 162 is defined on the distal end of pressure cap 150. The distal end of pressure cap 150 is located on the end of pressure cap 150 positioned away from actuator 118. As seen in
A pressure cap seal 180 is disposed around the outer perimeter of pressure cap 150 and is positioned between actuator 118 and pressure cap 150 when pressure cap 150 is installed in actuator socket 120. Pressure cap seal 180 may include an annular sealing ring such as an o-ring in some embodiments. Pressure cap 150 may provide a recessed region wherein pressure cap seal 180 is seated so that pressure cap seal 180 does not inadvertently roll axially along pressure cap 150 when pressure cap 150 is inserted into actuator socket 120.
As seen in
Referring again to
A liquid supply channel 158 is formed axially through liquid conduit 152. Liquid supply channel 158 extends through nipple 166 and is open at one end to liquid duct 124. Liquid supply channel 158 includes a liquid supply channel exit opening 160 at the opposite end open to pressure chamber 164. As such, liquid travelling through liquid duct 124 will enter directly into liquid supply channel 158 of liquid conduit 152.
Also seen in
In some alternative embodiments, liquid conduit 152 is integrally formed as part of actuator 118 and provides an integral liquid supply channel 158 extending toward pressure chamber exit orifice 162 on pressure cap 150.
Referring to
Additionally, as seen in
Referring further to
Referring further to
Dispensing head 104 and nozzle insert 130 may be configured in some embodiments to achieve a flow phenomenon known as flow blurring. Flow blurring requires the nozzle insert to be fed with a liquid flow and pressurized gas stream through separated channels, eventually mixing near the nozzle exit and generating a desired spray.
A flow blurring nozzle insert is defined as a nozzle insert configured to generate a flow blurring interaction between a propellant gas and a liquid product near the nozzle exit. During flow blurring, liquid product 190 travels through liquid supply channel 152 toward liquid supply channel exit opening 160 at a controlled liquid flow rate and liquid pressure, and gas propellant 188 travels through pressure chamber 164 toward pressure chamber exit orifice 162 at a controlled gas flow rate and gas pressure. The liquid and gas flows interact between the liquid supply channel exit opening 160 and the pressure chamber exit opening 162, forming an atomized spray.
As seen in
Referring to
In some embodiments, a flow blurring nozzle insert 130 allows a portion of gas forced through pressure chamber 164 from gas duct 122 to flow upstream into liquid supply channel 158 through liquid supply channel exit opening 160 and to form a reflux cell with the liquid product in liquid supply channel 158 upstream of liquid supply channel exit opening 160. Formation of reflux cell 192 is characteristic of a flow blurring interaction between a liquid product and a propellant gas. Reflux cell 192 includes a region of toroidal vorticity between propellant gas flow 188 and liquid product flow 190 inside liquid supply channel 158. The liquid and gas undergo turbulent flow interactions, forming one or more discrete bubbles of propellant gas in some flow conditions. A plurality of fluid ligaments 194 may be formed extending from reflux cell 192 toward pressure chamber exit orifice 162, and a plurality of atomized droplets 196 are formed downstream of pressure chamber exit orifice 162. The dispenser head 104 or nozzle insert 130 may form atomized droplets 196 in a size range of between about 0.5 and about 100 micrometers in some applications.
As seen in
It is understood, that in other embodiments, dispensing device 100 or dispenser head 104 may include a nozzle insert 130 having a geometry that does not produce flow blurring.
In some embodiments, the dispensing head, including the actuator, the liquid conduit and the pressure cap are formed by injection molding.
In additional embodiments, the present disclosure provides a method of ejecting an atomized spray of a gas propellant and a liquid product from a dispensing head on a dispensing device. The method includes the steps of: (a) providing an actuator having a liquid duct, a gas duct and an actuator socket; (b) providing a pressure cap disposed in the axial socket, the pressure cap forming a pressure chamber between the pressure cap and the actuator and including a pressure chamber exit orifice defined in the pressure cap, wherein the pressure chamber is in liquid communication with the gas duct; (c) providing a liquid conduit member in the pressure chamber between the pressure cap and the actuator, the liquid conduit member including a liquid supply channel defined therein, the liquid supply channel including a liquid supply channel axis and including a liquid supply channel exit opening substantially aligned with the pressure chamber exit orifice; (d) supplying a flow of liquid through the liquid supply channel toward the liquid supply channel exit opening; (e) supplying a flow of a gas from the gas duct through the pressure chamber toward the liquid supply channel axis between the liquid supply channel exit opening and the pressure chamber exit orifice, wherein the gas intercepts the flow of liquid, travels upstream toward the liquid supply channel exit opening and enters the liquid supply channel exit opening; (f) forming a reflux cell inside the liquid supply channel upstream of the liquid supply channel exit opening, wherein the liquid and the gas undergo turbulent mixing in the reflux cell; and (g) ejecting the liquid from the reflux cell through the pressure chamber exit orifice. The method may also includes the step of breaking the liquid up into a plurality of atomized liquid droplets.
The present disclosure also provides a method of emitting a liquid product from a dispensing device, comprising: (a) providing a dispensing device having a container storing the liquid and the gas and including a dispensing head and a sequential delivery valve attached to the container; (b) depressing the dispensing head toward the container from a first axial position to a second axial position, thereby partially opening the valve and allowing gas to pass through the valve from the container into the dispensing head, and blocking liquid from passing through the valve from the container into the dispensing head; (c) depressing the dispensing head further toward the container from the second axial position to a third axial position nearer the container than the second axial position, thereby fully opening the valve and allowing both gas and liquid to pass though the valve from the container into the dispensing head; and (d) emitting the liquid and the gas from the dispensing head. In some embodiments, the method also includes the step of turbulently mixing the liquid and the gas in a reflux cell inside the dispensing head.
Thus, although there have been described particular embodiments of the present invention of new and useful sequential delivery valve apparatus and methods, it is not intended that such references be construed as limitations upon the scope of this invention except as set forth in the following claims.
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