Embodiments of the invention relate to dispensing devices for flowable products, and more particularly to a dispensing assembly including an interchangeable and/or refillable additive mixing device which introduces and mixes an additive ingredient into a dispensed flow of a standard base formulation. Each mixing device may contain a different additive ingredient so that the customer may easily change the resulting dispensed product.
Consumers continually drive the need for novel dispensing devices which provide more functionality and better options for a variety of products.
The present disclosure is directed to a novel additive mixing head which is capable of both introducing and mixing an additive ingredient into a flow of a base formulation with each dispensing cycle. Consider for example, a consumer that needs to carry multiple different SPF sunscreen lotions. Currently, a mother traveling to the beach with her children may need to carry several different full bottles of sunscreen lotion. One SPF lotion for herself and a higher SPF lotion for the children. The sunscreen lotion bottles are large, heavy and expensive, and the situation would be greatly improved if only one bottle were required.
The present disclosure provides a dispensing system including a container containing a flowable base formulation to be dispensed, at least one additive mixing device, and an actuable pump engine which draws the flowable base formulation from the container and pumps it through the mixing device. In the context of a complete system, a plurality of interchangeable additive mixing devices may be provided, each including a different additive ingredient which can be dispensed with the base formulation. For example, different SPF formulations for mixing with a base sunscreen lotion or oil.
The flowable base formulation may include liquids, lotions, oils, gels, etc. Any formulation which is capable of being pumped with an actuable pump engine. The pump engine may include any type of depressible pump or sprayer such as used for lotions, oils or perfume or trigger pumps or sprayers, such as used for liquid cleaning products.
The additive mixing device includes a body with an internal cavity, an additive ingredient disposed within the cavity, or impregnated or mixed within a carrier material disposed within the cavity, and a mixing structure or passage within the cavity between an input and an output of the cavity.
In some embodiments, the additive ingredient is mixed with a carrier material similar to the base formulation, such as a liquid or an oil or a gel, or with a carrier material which is soluble with the base formulation. In some embodiments, the additive ingredient is impregnated into a solid material, which may include crystals, small pills or balls, or larger shapes which fill the cavity and have through holes, apertures, slots or other flow structures, to provide for increased surface area for fluid flow and contact with the additive ingredient. In still other embodiments, the additive ingredient is simply filled into the cavity and metered into the base flow with each dispensing cycle.
The mixing structure may, for example, be an absorbent sponge material which fills the internal cavity of the mixing device. The sponge would hold a quantity of the additive ingredient and its carrier material within its pores, while also providing a complex labyrinth of passageways to force mixing of the additive material with the base formulation as it is forced through the sponge structure. In other embodiments, the solid crystals may fill the cavity or be contained within a replaceable netting material placed within the cavity. The uneven shapes and structures of the crystals creates the necessary turbulent pathways to cause sufficient mixing of the additive ingredient into the flow of the base formulation. Still other embodiments may include a separate mixing passage with interior baffles or other structures adjacent to the cavity output to create a turbulent mixing of the base formulation and additive ingredient as the combined materials pass through the mixing passageway to the output.
With each pump of the device, the base formulation is forced through the additive mixing device, where the additive ingredient is introduced into, and mixed with, a flow of the base formulation traveling through the mixing device.
In some exemplary embodiments, the additive mixing device is on the output side of the pump engine so that the base formulation remains within the pump engine ready to be pumped through the mixing device without being mixed with the additive ingredient. The additive ingredient mixing devices can be readily interchanged on the output side of the pump engine without tainting the base formulation.
In other exemplary embodiments, the additive mixing device is located between the container and the pump engine where the base formulation is drawn from the container through the additive mixing device and then the mixed formulation is pumped through the pump engine. This embodiment requires that the pump engine be integrated with the additive mixing device and becomes part of the interchangeable mixing head.
In still further exemplary embodiments, the additive mixing device is a secondary pump which co-acts with the primary base product pump to simultaneously pump both the base product formulation and the additive ingredient into a flow stream.
Other exemplary embodiments include a primary base product pump engine and a co-acting dispensing head having a nozzle, an additive ingredient chamber and a mixing chamber therebetween. Actuation of the pump engine draws the flowable base formulation from the container and pumps it through the mixing chamber where the additive ingredient is introduced into and mixed with the base formulation with each actuation.
Further exemplary embodiments include spider valves within the inlet and outlet ports, and an external cover which actively reduce leakage during shipping, handling and storage.
While the specification concludes with claims particularly pointing out and distinctly claiming particular embodiments of the present invention, various embodiments of the invention can be more readily understood and appreciated by one of ordinary skill in the art from the following descriptions of various embodiments of the invention when read in conjunction with the accompanying drawings in which:
Certain exemplary embodiments will now be described to provide an overall understanding of the principles of the structure, function, manufacture, and use of the device and methods disclosed herein. One or more examples of these embodiments are illustrated in the accompanying drawings. Those skilled in the art will understand that the devices and methods specifically described herein and illustrated in the accompanying drawings are non-limiting exemplary embodiments and that the scope of the present invention is defined solely by the claims. The features illustrated or described in connection with one exemplary embodiment may be combined with the features of other embodiments. Such modifications and variations are intended to be included within the scope of the present disclosure. Further, in the present disclosure, like-numbered components of the embodiments generally have similar features, and thus within a particular embodiment each feature of each like-numbered component is not necessarily fully elaborated upon. Additionally, to the extent that linear or circular dimensions are used in the description of the disclosed systems, devices, and methods, such dimensions are not intended to limit the types of shapes that can be used in conjunction with such systems, devices, and methods. A person skilled in the art will recognize that an equivalent to such linear and circular dimensions can easily be determined for any geometric shape. Further, to the extent that directional terms like top, bottom, up, or down are used, they are not intended to limit the systems, devices, and methods disclosed herein. A person skilled in the art will recognize that these terms are merely relative to the system and device being discussed and are not universal.
The present disclosure is generally directed to a novel additive mixing device or mixing head which is capable of both introducing and mixing an additive ingredient into a flow of a base formulation with each dispensing cycle.
In some exemplary embodiments, the additive mixing device is on the output side of the pump engine so that the base formulation remains within the pump engine ready to be pumped through the mixing device without being mixed with the additive ingredient. The additive ingredient mixing devices can be readily interchanged on the output side of the pump engine without tainting the base formulation.
In other exemplary embodiments, the additive mixing device is located between the container and the pump engine where the base formulation is drawn from the container through the additive mixing device and then the mixed formulation is pumped through the pump engine. These embodiments may require that the pump engine be integrated with the additive mixing device and becomes part of the interchangeable mixing head.
In other exemplary embodiments, primary and secondary dispensing pumps are co-active to dispense both the base formulation and the additive ingredient into a single combined stream with a single pump stroke.
In further exemplary embodiments, a pump engine and a dispensing head are co-active with each dispensing cycle.
Turning to
The flowable base formulation 910 may include liquids, lotions, oils, gels, foams, volatile perfume base formulations, etc. Any and all formulations which are capable of being pumped with an actuable pump engine 104 are contemplated. The pump engine 104 may include any type of depressible pump or sprayer such as used for lotions, oils or perfume, or trigger pumps or sprayers, such as used for liquid cleaning products.
Referring back to
The mixing device body 106 may be formed from two complementary parts 106A, 106B which may snap or screw together to form the body and cavity. The separable body parts 106A, 106B permit the additive ingredient 114, carrier 116 and mixing structure 118 to be installed into the cavity and allow for the additive ingredient to be replaced when depleted.
In some embodiments, the additive ingredient 114 is mixed with a carrier material 116 which is similar to the base formulation, such as a liquid or an oil or a gel, or with a carrier material which is soluble within the base formulation 910. In this regard, the mixing structure 118 may, for example, be an absorbent sponge material (
The pump engine 104 is mounted onto the neck of the container 900 and presents a depressible neck actuator button 120 having an output orifice 122. A dispensing pump of the type described in US Patent Publication No. 20170197226 is exemplary, the entire contents thereof being incorporated herein by reference. The mixing device 102 includes a complementary shape with an overcap 124 which fits over the pump neck 120 and centrally located input tube 126 which is received into the pump output 122.
Referring to
The solid crystals 216 may fill the cavity 208 or be contained within a replaceable netting material (not shown) and placed within the cavity 208. The uneven shapes and structures of the crystals 216 creates the necessary turbulent pathways to cause sufficient mixing of the additive ingredient 214 into the flow of the base formulation 910 as it passes over the crystals 216.
Still other embodiments 300 and 400, such as illustrated in
In the embodiment system 300 illustrated in
With each pump of the illustrated pump engines, the base formulation 910 is forced through the additive mixing device, where the additive ingredient is introduced into, and mixed with, a flow of the base formulation traveling through the mixing device.
Turning to
In
In
Turning to
The base product pump 1002 comprises an accumulator cup 1006 which is secured within the neck of a container 900 with a threaded closure 1008. The accumulator 1006 has a clip tube inlet 1010 formed in the bottom wall thereof. A ball valve 1012, or other fluid valve structure is disposed within the clip tube inlet 1010 and a clip tube 1014 extends from the inlet 1010 to draw base product 910 from the container 900.
A nozzle head 1016 is received on a piston stem 1018 which extends through the closure 1008 and into the accumulator 1006. The piston stem 1018 is axially guided within the accumulator 1006 by a piston guide 1020. The piston stem 1018 extends through the bottom of the piston guide 1020 and a piston seal 1022 is received on the terminal end of the piston stem 1018, forming a seal with the inner walls of the accumulator 1006. A spring 1024 is captured between the piston guide 1020 and the piston stem 1018 to axially bias the head 1016 upwardly.
The nozzle head 1016 includes an upwardly open receptacle 1026 for removably receiving the additive ingredient pump 1004. The receptacle 1026 has a bottom wall 1028 with an aperture 1030 that opens into a mixing chamber 1032 which is in turn received into the exit opening of the piston stem 1018. A cup shaped guide sleeve 1034 is received within the pump head receptacle 1026 and cooperates with the pump head 1016 to define a fluid flow path (see arrow FP) from the mixing chamber 1032 to the discharge nozzle 1036.
The additive ingredient pump 1004 has a body 1038 which contains the additive ingredient 1040 and an axial, spring biased dispensing stem 1042 extending from the body 1038. As noted above, the additive ingredient 140 may be mixed with a carrier material to provide a mixture which can be pumped or sprayed. When received into the pump receptacle 1026, the dispensing stem 1042 is received into an aperture 1044 in the bottom of the guide sleeve 1034 and communicates with the mixing chamber 1032. The body 1038 is guided for axial movement within the guide sleeve 1034 by the walls of the guide sleeve 1034.
In operation, a forcible downward compression of the additive pump 1004 and nozzle head 1016 causes two simultaneous pumping actions. For the additive pump 1004, the dispensing stem 1042 is axially compressed to dispense a metered dose of the additive ingredient 1040 into the mixing chamber 1032. Simultaneously, the same downward compression forces the piston stem 1018 downwardly to pump the base product 910 from the accumulator cup 1006 up through the piston stem 1018 and into the mixing chamber 1032. The final portion of the compression stroke forces the mixed base product and additive ingredient in the mixing chamber 1032 through the flow path (FP) and out through the discharge nozzle 1036.
The pump engine 2002 assembly comprises an accumulator cup 2006 which is secured within the neck of a container 900 (shown in
The dispensing head assembly 2004 is received onto a piston stem 2016 of the pump engine 2002 which extends through an axial opening in the closure body 2008. A spring 2018 is captured between the upper surface of the closure body 2008 and a bottom surface of a guide flange 2020 to axially bias the dispensing head assembly 2004 upwardly.
The dispensing head assembly 2004 comprises a nozzle body 2022 with an upwardly open receptacle which co-axially receives a nozzle core 2024 and an inverted cup shaped piston 2026. A cap 2028 is removably received onto the nozzle body 2022 over the open receptacle. The nozzle body 2022 has an outer side wall 2030 and a bottom wall 2032 which is recessed up into the interior of the body. This creates an annular channel 2034 into which the nozzle core 2024 and piston 2026 are received.
The outer side wall 2030 of the nozzle body 2022 includes a dispensing orifice 2036 adjacent the upper peripheral edge thereof. The bottom wall 2032 of the nozzle body 2022 includes a connection port 2038 extending through the bottom wall 2032 and downwardly. As best seen in
The nozzle core 2024 includes a side wall 2040 and a bottom wall 2042 which is also recessed upwardly into the interior of the core creating an annular piston seat 2044 within the nozzle core 2024. The nozzle core 2024 nests within the nozzle body 2022 where the bottom surface of the bottom wall 2042 includes spacing shoulders 2046 to create a narrow base product flow path beneath the upper surface of the bottom wall 2032 of the nozzle body 2022 and the lower surface of the bottom wall 2042 of the nozzle core 2024. The piston 2026 nests within the nozzle core 2024 with its sidewalls 2048 received in the annular piston seat 2044, and its top wall 2050 resting on the bottom wall 2042 of the nozzle core 2024. This creates an active ingredient chamber 2052 above the top wall 2050 of the piston 2026. An active ingredient formulation 2054 (liquid, gel, lotion etc.) may be received into the chamber 2052. The active ingredient formulation 2054 may include a carrier material which facilitates a fluid flow. The cap 2028 is snap received into the upper lip of the nozzle body 2022 where its sidewalls engage the sidewalls of the nozzle core 2024 and retain the nozzle core 2024 in position within the nozzle body 2022. The cap walls and nozzle body lip may include interfitting snap formations to facilitate removal of the cap 2028, as well as filling and refilling of the additive ingredient formulation 2054.
A flow aperture 2056 is provided in the bottom wall 2042 of the core 2024, allowing base product 910 to flow into a lower base product chamber space (best seen in
Referring briefly, to
As the pump engine 2002 is actuated, i.e. by pressing downwardly on the top of the dispensing head 2004, base product 910 flows from the piston stem 2016 beneath the nozzle core 2024 to the dispensing orifice 2036. A small amount of base product also flows through the flow aperture 2056 to the lower chamber space beneath the piston 2026. With each actuation, a lower base product chamber 2060 is created beneath the piston 2026, filling with base product 910 and pushing the piston 2026 upwardly to simultaneously push the active ingredient 2054 from the upper chamber 2052. This flow action will be described further hereinbelow with respect to
Referring now to
Turning to
Turning now to
In some embodiments, the insert 2068 may also be received within the connection port 2038 in the bottom wall 2032 of the nozzle body 2022 (configuration not shown).
Referring to
It is also noted that the dispensing heads in embodiments 2000, 2000A and 2000B can also be removed and interchanged before emptying to provide the same interchangeability as described above with other embodiments. The lower chamber filling 2060 with the base formulation 910 provides a buffer zone preventing the active ingredient 2054 from tainting the base product formulation 910 in the container 900 and allowing free interchange of different dispensing heads.
Referring to
The pump engine 3002 assembly comprises an accumulator cup 3006 which is secured within the neck of a container 900 (shown in
The dispensing head assembly 3004 is received onto a piston stem 3016 of the pump engine 3002 which extends through an axial opening in the closure body 3008. A spring 3018 is captured between the upper surface of the closure body 3008 and a bottom surface of a guide body 3020 to axially bias the dispensing head assembly 3004 upwardly.
The dispensing head assembly 3004 comprises a nozzle body 3022 with an upwardly open receptacle which co-axially receives a nozzle core 3024 and an inverted cup shaped piston 3026. A cap 3028 is removably received onto the nozzle body 3022 over the open receptacle. The nozzle body 3022 has an outer side wall 3030 and a bottom wall 3032 which is recessed up into the interior of the body. This creates an annular channel into which the nozzle core 3024 and piston 3026 are received.
The outer side wall 3030 of the nozzle body 3022 includes a dispensing orifice 3036 adjacent the upper peripheral edge thereof. The bottom wall 3032 of the nozzle body 3022 includes an inlet port 3038 extending through the bottom wall 2032 and downwardly. As best seen in
The nozzle core 3024 includes a side wall 3040 and a bottom wall 3042 which is also recessed upwardly into the interior of the core creating an annular piston seat within the nozzle core 3024. The nozzle core 3024 nests within the nozzle body 3022 where the bottom surface of the bottom wall 3042 includes spacing shoulders 3046 to create a narrow base product flow path beneath the upper surface of the bottom wall 3032 of the nozzle body 3022 and the lower surface of the bottom wall 3042 of the nozzle core 3024. The piston 3026 nests within the nozzle core 3024 with its sidewalls 3048 received in the annular piston seat, and its top wall 3050 resting on the bottom wall 3042 of the nozzle core 3024. This creates an active ingredient chamber 3052 above the top wall 3050 of the piston 3026. An active ingredient formulation 3054 (liquid, gel, lotion etc.) may be received into the chamber 3052. The active ingredient formulation 3054 may include a carrier material which facilitates a fluid flow. The cap 3028 is snap received into the upper lip of the nozzle body 3022. The cap walls and nozzle body lip may include interfitting snap formations to facilitate removal of the cap 3028, as well as filling and refilling of the additive ingredient formulation 3054.
A flow aperture 3056 is provided in the bottom wall 3042 of the core 3024, allowing base product 910 to flow into a lower base product chamber space 3059 (best seen in
As the pump engine 3002 is actuated, i.e. by pressing downwardly on the top of the dispensing head 3004, base product 910 flows from the piston stem 3016 beneath the nozzle core 3024 to the dispensing orifice 3036. A small amount of base product also flows through the flow aperture 3056 to the lower chamber space beneath the piston 3026. With each actuation, a lower base product chamber 3060 is created beneath the piston 3026, filling with base product 910 and pushing the piston 3026 upwardly to simultaneously push the active ingredient 3054 from the upper chamber 3052. This flow action will be described further hereinbelow with respect to
With each actuation, the lower base product chamber 3060 is increased in size beneath the piston 3026 (
Referring now to
As a further measure of protection, the present embodiment 3000 is provided with an external flexible cover 3068 having an arcuate wall portion 3070 extending slightly more than 180 degrees around the nozzle body 3022, a cup portion 3072 sized to be received over the nozzle 3066, and a sealing pin 3074 configured to be received into an exit opening 3076 in the nozzle 3066 (See
It can therefore be seen that the present disclosure provides for a novel dispensing system wherein multiple additive mixing devices or heads can be selectively installed onto a container with a pump engine to mix the additive with a base formulation in the container. The base formulation is drawn from the container and forced through the additive mixing head to create a custom product with each pump actuation.
Having thus described certain particular embodiments of the invention, it is understood that the invention defined by the appended claims is not to be limited by particular details set forth in the above description, as many apparent variations thereof are contemplated. Rather, the invention is limited only be the appended claims, which include within their scope all equivalent devices or methods which operate according to the principles of the invention as described.
Filing Document | Filing Date | Country | Kind |
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PCT/US20/62487 | 11/27/2020 | WO |
Number | Date | Country | |
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Parent | 16699176 | Nov 2019 | US |
Child | 17777178 | US |
Number | Date | Country | |
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Parent | 16617581 | Nov 2019 | US |
Child | 16699176 | US |