The present invention relates to the field of personal care products.
For many people, adults and children alike, taking a bubble bath is an enjoyable and/or therapeutic experience.
A soap bubble is a thin film of soapy water that encloses air.
There is provided, in accordance with some embodiments of the present invention, apparatus for use in a bathtub containing water. The apparatus includes an outer shell, a soap holder, configured to hold a liquid soap, at least one set of blades, and a motor disposed within the outer shell and coupled to the set of blades. The motor is configured to form soap bubbles by spinning the set of blades such that the blades lift the water from the bathtub, and pass the lifted water, together with liquid soap from the soap holder, through air.
In some embodiments, the apparatus further includes a suction holder coupled to the outer shell, the suction holder being configured to couple the outer shell to a wall of the bathtub.
In some embodiments, the apparatus further includes a mesh configured to couple to the outer shell over the set of blades.
In some embodiments, each of the blades is shaped to define one or more apertures passing from one face of the blade to an opposite face of the blade.
In some embodiments, when the outer shell is partly submerged in the water with a longitudinal axis of the outer shell being parallel to a surface of the water, the set of blades is partly submerged in the water.
In some embodiments, an axis of rotation of the set of blades is parallel to the longitudinal axis of the outer shell.
In some embodiments, the soap holder includes a receptacle shaped to define one or more apertures and configured to couple to the outer shell such that, as the motor spins the set of blades, the soap drips from the receptacle via the apertures.
In some embodiments, the soap holder is configured to couple to outer shell such that the soap drips, via the apertures, onto the blades.
In some embodiments, the soap holder is configured to couple to outer shell such that the soap drips, via the apertures, into the bathtub.
In some embodiments, the apparatus further includes a buoyant cover configured to cover the set of blades.
In some embodiments, the buoyant cover is shaped to define the soap holder.
In some embodiments, the buoyant cover includes a sponge.
In some embodiments, the buoyant cover is shaped to define a plurality of cover-apertures configured to facilitate passage of the water through the buoyant cover.
In some embodiments, the outer shell is buoyant.
In some embodiments, the outer shell is shaped to define an aperture positioned behind the set of blades and in fluid communication with the soap holder, such that, as the motor spins the set of blades, the soap drips, via the aperture, onto the set of blades.
In some embodiments, the soap holder is at least partly contained within the outer shell.
There is further provided, in accordance with some embodiments of the present invention, apparatus for use in a bathtub containing water. The apparatus includes an outer shell, shaped to define one or more apertures, an impeller disposed within the outer shell, a soap holder, contained within the outer shell and configured to hold a liquid soap, at least one set of blades, and at least one motor disposed within the outer shell and coupled to the set of blades and to the impeller. The motor is configured to form soap bubbles while the apertures are submerged in the water, by turning the impeller such that the impeller draws the water, via the apertures, into the soap holder, thus forming a mixture of the water and the liquid soap, and spinning the set of blades such that the blades lift the mixture from the soap holder, and pass the mixture through air.
In some embodiments, the set of blades is at least partly contained within the soap holder.
In some embodiments, an axis of rotation of the set of blades is perpendicular to a longitudinal axis of the outer shell.
There is further provided, in accordance with some embodiments of the present invention, an apparatus including a bathtub, which includes a plurality of walls surrounding a bathing chamber. At least one of the walls is shaped to define a side chamber in fluid communication with the bathing chamber. The apparatus further comprises one or more sets of blades disposed within the side chamber, a soap holder, configured to hold a liquid soap, and at least one motor coupled to the sets of blades. The motor is configured to form soap bubbles by spinning at least one of the sets of blades such that the blades of the at least one of the sets lift water from the side chamber, and pass the lifted water, together with liquid soap from the soap holder, through air.
In some embodiments, the apparatus further includes a mesh that divides between the side chamber and the bathing chamber.
In some embodiments, the one or more sets of blades include a vertically-arranged plurality of sets of blades.
In some embodiments, the soap holder includes a receptacle shaped to define one or more apertures and configured to couple to the bathtub such that, as the motor spins the at least one of the sets of blades, the soap drips from the receptacle, via the apertures, into the side chamber.
In some embodiments, the one of the walls is further shaped to define the soap holder and a passage passing from the soap holder to the side chamber, such that, as the motor spins the at least one of the sets of blades, the soap drips from the soap holder, via the passage, into the side chamber.
There is further provided, in accordance with some embodiments of the present invention, a method that includes, using a motorized set of blades, lifting water from a bathtub, and, using the set of blades, forming soap bubbles by passing the lifted water, together with liquid soap from a soap holder, through air.
In some embodiments, forming the soap bubbles includes forming the soap bubbles by passing the lifted water though the air while receiving the liquid soap from the soap holder.
In some embodiments,
the liquid soap drips into the bathtub, thus forming a mixture with the water,
lifting the water includes lifting the water by lifting the mixture from the bathtub, and
forming the soap bubbles includes forming the soap bubbles by passing the mixture though the air.
In some embodiments, the set of blades is covered by a mesh, and forming the soap bubbles includes forming some of the soap bubbles in a space between the set of blades and the mesh.
In some embodiments, the liquid soap, when contained in the soap holder, is not mixed with water.
There is further provided, in accordance with some embodiments of the present invention, a method that includes drawing water from a bathtub into a soap holder that holds a liquid soap, thus forming a mixture of the water and the liquid soap, and forming soap bubbles by spinning a set of blades such that the blades lift the mixture from the soap holder and pass the mixture though air.
The present invention will be more fully understood from the following detailed description of embodiments thereof, taken together with the drawings, in which:
Embodiments of the present invention facilitate the quick and inexpensive generation of bubble baths, using any suitable liquid soap of the user's choosing.
Embodiments described herein include a soap spinner, configured to generate soap bubbles in a bathtub. In some embodiments, the soap spinner comprises at least one set of rotary blades, and a motor configured to spin (or “rotate”) the set of blades around a common central axis. The spinner is coupled to the side wall of the bathtub, or is allowed to freely float within the bathtub, such that the set of blades is partly submerged within the water in the bathtub, and is partly exposed to the air above the water. As the blades spin, a liquid soap is fed to the blades (and/or to the bathwater in the vicinity of the blades), such that the blades become covered with soapy water. For example, the soap spinner may comprise a soap dripper, positioned above the set of blades, which drips soap onto the blades (and/or into the bathwater) as the blades spin. As the blades pass through the air, soap bubbles are formed from the soapy water on the blades.
In other embodiments, the spinner comprises an internal soap chamber, which is prefilled with liquid soap, and an impeller. The spinner is coupled to the side of the bathtub, or is allowed to freely float within the bathtub, such that the impeller continuously draws water from the bathtub into the soap chamber, thus forming soapy water. The set of rotary blades is partly submerged within the soap chamber and partly exposed to air, such that, as the blades spin, the blades lift soapy water from the soap chamber into the air, thus forming bubbles from the soapy water.
In yet other embodiments, the bathtub comprises an integrated soap-spinning system. The system comprises one or more sets of motorized rotary blades contained within an open recess in the wall of the bathtub, along with a soap dripper configured to drip liquid soap onto the blades, and/or into the bathwater in the vicinity of the blades.
Typically, each of the blades is shaped to define a plurality of apertures passing from one face of the blade to the opposite face of the blade. Such embodiments have at least two advantages. First, the apertures facilitate greater access to air, such that more bubbles may be formed from a given quantity of soapy water. Second, the apertures reduce resistance to the spinning of the blades, such that a greater rotation speed of the blades—and hence, greater and/or faster bubble formation—may be achieved.
In summary, using embodiments described herein, a large number of bubbles may be quickly generated, using a relatively small amount of any type of liquid soap.
Reference is initially made to
Typically, set 27 is disposed at the end of outer shell 24, with the axis of rotation 31 of set 27 being parallel to the longitudinal axis 48 of outer shell 24. (In the context of the present application, including the claims, a “longitudinal axis” of an object is an axis that runs along the length of the object, e.g., through the radial center of the object.) It is noted, however, that other configurations are included within the scope of the present disclosure.
Typically, apparatus 20 comprises a suction holder 30 coupled to outer shell 24, which couples the outer shell to the wall of the bathtub. Alternatively, apparatus 20 may comprise another type of coupling mechanism for coupling the apparatus to the wall of the bathtub, or apparatus 20 may be allowed to freely float in water 38, e.g., as described below with reference to
Motor 42 is activated using an activation mechanism 44, comprising, for example, a push button or self-locking switch. Activation mechanism 44 may be disposed, for example, at the opposite end of outer shell 24 from set 27. In some embodiments, the apparatus comprises a printed circuit board (PCB) (not shown), disposed within the outer shell near the activation mechanism, and connected to the motor via wires. In addition to facilitating the activation (and deactivation) of the motor via activation mechanism 44, the PCB may comprise temperature-control circuitry, configured to deactivate the motor if the motor (atypically) begins to overheat.
Typically (for all embodiments described herein), soap 34, when contained in soap holder 28, is not mixed with water, aside from any water from the bathtub that might splash into the soap holder during operation of the apparatus. In other words, apparatus 20 typically does not require the provision of a bubble bath mixture, or any other mixture of soap and water; rather, normal liquid soap may be used.
Typically, soap holder 28 comprises a receptacle 33, shaped to define a plurality of apertures 40, which holds the liquid soap. Receptacle 33 is configured to couple to outer shell 24 (e.g., via an arm 36) such that the receptacle is positioned above the blades; hence, as the motor spins the set of blades, the soap drips, via the apertures, onto the blades.
In some cases, water may splash into receptacle 33, thus mixing with the soap within the receptacle. This mixing may expedite the generation of further soap bubbles.
Typically, the rotating blades do not present a hazard to the occupants of the bathtub. Nevertheless, as an extra precaution, apparatus 20 may comprise a protective mesh 23, which couples to outer shell 24 over the set of blades. Mesh 23 is shaped to define openings 37 large enough for passage therethrough of the soap and water, but small enough to inhibit a finger from passing therethrough, such that the finger does not contact blades 26. Additional soap bubbles may form in the space between the mesh and the blades. In some embodiments, apparatus 20 comprises more than one set 27 of blades. For example, apparatus 20 may comprise two sets of blades, one set at each end of a cylindrical outer shell 24, and motor 42 may spin both sets of blades simultaneously. In such embodiments, apparatus 20 may comprise two soap holders 28, each one being positioned above a respective one of the sets of blades.
In some embodiments, each blade 26 runs along the length of a common central cylindrical shaft that is rotated about axis of rotation 31, such that the length of each blade is parallel to axis of rotation 31. Typically, each blade 26 is shaped to define one or more apertures 25, which pass from one face of the blade to an opposite face of the blade. (In this context, the “faces” of the blade refer to the two surfaces of the blade that are normal, or approximately normal, to the instantaneous velocity vector 35 of the blade as the blade spins. The area of each of these surfaces, including the surface area of any apertures in the surface, is typically greater than that of any non-face surface of the blade.) Apertures 25 may have any suitable shape, such as, for example, a wholly or partly rectangular shape, and/or a wholly or partly circular shape. In some embodiments, as shown in
Reference is now made to
As noted above with reference to
Cover 78 is shaped to define a frontal opening 82. Prior to placement of apparatus 20 in the bathtub, cover 78 is passed over the blades (and/or the blades are inserted into the cover), such that the blades enter the cover via frontal opening 82. Typically, the diameter of frontal opening 82 is slightly less than the diameter of outer shell 24, such that cover 78, which is typically made of a resilient material, couples to outer shell 24 by squeezing outer shell 24. Alternatively or additionally, any suitable clips, hooks, or other fasteners may hold the cover to the outer shell.
Typically, cover 78 is shaped to define a plurality of cover-apertures 80, which are typically arranged along the sides and bottom of cover 78. Cover-apertures 80 facilitate passage of the bathwater to the set of blades. (Nevertheless, typically, cover-apertures 80 are narrow enough to inhibit the passage of fingers therethrough.) In some embodiments, cover 78 comprises wings 84, which contribute to the buoyancy of the cover.
Reference is now made to
Apparatus 20a is similar to apparatus 20, in that apparatus 20a comprises an outer shell 24 (which, for example, may be cylindrically shaped), a soap holder 28, a set 27 of blades 26 (which are typically shaped to define apertures 25), and a motor 42 disposed within outer shell 24 and coupled to set 27. (In
Notwithstanding the above, apparatus 20a differs from apparatus 20, as shown in
Inner wall 51 surrounds a central chamber 62, which is typically located at the radial center of the outer shell. Apparatus 20a comprises an impeller 54, comprising, for example, a plurality of blades 56 coupled to a central shaft 58, which is disposed within central chamber 62. For example, one product that embodies impeller 54, as generally shown in
Outer shell 24 is shaped to define one or more apertures 64, each of which is in fluid communication with central chamber 62 via a respective passageway 66. Typically, passageways 66 are not in direct fluid communication with soap holder 28; rather, passageways 66 are only in indirect fluid communication with soap holder 28, via central chamber 62.
Prior to use of apparatus 20a, soap holder 28 is filled at least partly with liquid soap 34. (The soap may rise above the top of inner wall 51.) Apparatus 20a is then placed in water 38, such that apertures 64 are submerged. The orientation of apparatus 20a, when disposed in the water, is typically upright, with longitudinal axis 48 being perpendicular to the water level. (In contrast, apparatus 20, as shown in
Subsequently, the impeller, as it is turned by the motor, draws water, via the apertures, into the soap holder. For example, the impeller may draw water into central chamber, such that the water rises, within the central chamber, toward a roof 70 of the central chamber. Below roof 70, inner wall 51, or a separate structure 72 that comprises roof 70 and hence closes the top of the inner wall, may be shaped to define a plurality of inner apertures 68. The water passes through inner apertures 68 and into soap holder 28, thus mixing with the soap in soap holder 28. This mixture of soap and water then rises toward set 27 of blades. As blades 26 spin, as indicated by a third spin indicator 76, the blades lift the soapy water (i.e., the mixture of soap and water) from the soap holder, and then pass the soapy water through the air, thus forming soap bubbles.
Typically, the axis of rotation 74 of the set of blades is perpendicular to longitudinal axis 48. Nonetheless, a single motor 42 may rotate both impeller 54 and set 27. For example, a gear located behind the set of blades (not visible in the figure), coupled to shaft 58 and to the set of blades, may convert the rotational motion of the shaft (as indicated by second spin indicator 60) around an axis of rotation that is parallel to longitudinal axis 48 into rotational motion around axis of rotation 74. Alternatively, apparatus 20a may comprise two motors; one that spins the impeller, and another that spins the set of blades.
In some embodiments, apparatus 20a is reversibly coupled to the floor of the bathtub, e.g., via a suction holder coupled to the bottom 65 of outer shell 24. As yet another alternative, the bathtub may be manufactured to include apparatus 20a as an integral component thereof, with apparatus 20a being fixedly attached to the floor of the bathtub, and, for example, with motor 42 being connected to the electrical infrastructure of the home in which the bathtub is located, or powered by batteries located inside the wall of the bathtub. In such embodiments, apparatus 20a is tall enough such that the set of blades is exposed to air even with a relatively high level of water in the bathtub, yet apertures 64 are low enough such that the apertures are submerged even with a relatively low water level. For example, apertures 64 may be located less than 10 cm from bottom 65.
Reference is now made to
In some embodiments, as shown in
In some embodiments, apparatus 20 further comprises a funnel 86 configured for insertion into the soap holder. Funnel 86 facilitates the pouring of liquid soap into soap holder 28. (The inset portion of
Reference is now made to
Bathtub 22a comprises a plurality of walls surrounding a bathing chamber 98, which may be filled with water 38, and in which individuals may bathe. At least one wall 96 of the walls is shaped to define a side chamber 100 in fluid communication with bathing chamber 98, such that, upon the bathing chamber being sufficiently filled with water 38, some of the water enters side chamber 100. A protective mesh 102 may divide between the side chamber and the bathing chamber.
Bathtub 22a further comprises one or more sets of blades disposed within the side chamber; for example, a plurality of sets of blades may be arranged vertically within the side chamber. As a specific example, bathtub 22a may comprise three sets of blades: a first set 27a, a second set 27b beneath first set 27a, and a third set 27c beneath second set 27b. Each of the sets may be similar to any of the sets of blades shown in, or described above with reference to, any of the previous figures, or may, alternatively, have any other suitable form.
At least one motor 42 is coupled to the sets of blades. For example, a single motor 42 may be coupled to all of the sets via respective gear joints, such that the single motor is configured to spin all of the sets. Alternatively, a separate motor may be coupled to each of the sets, e.g., via a respective shaft 58, such that each of the sets is spun by a different respective motor. Motors 42 may be connected to the electrical infrastructure of the home in which bathtub 22a is located; alternatively, the motors may be powered by batteries located, for example, inside wall 96.
Bathtub 22a further comprises soap holder 28, which is configured to hold liquid soap 34. In some embodiments, soap holder 28 comprises receptacle 33, the bottom of which, as in
In some embodiments, upon the user activating the motors (e.g., by pushing an activation button, or flipping an activation switch), the motors spin all of the sets of blades. Typically, the sets of blades are arranged such that, for any water level within a particular range of water levels, at least one of the sets of blades is partly submerged. (For example, for the water level shown in
In other embodiments, only the set of blades that is partly submerged is spun. For example, each set of blades may be coupled to one or more sensors, which sense whether the set of blades is in contact with water 38. A processor may then receive appropriate signals from these sensors, and, in response to these signals, cause the motors to spin only the topmost set of blades that is in contact with the water.
It will be appreciated by persons skilled in the art that the present invention is not limited to what has been particularly shown and described hereinabove. Rather, the scope of embodiments of the present invention includes both combinations and subcombinations of the various features described hereinabove, as well as variations and modifications thereof that are not in the prior art, which would occur to persons skilled in the art upon reading the foregoing description. Documents incorporated by reference in the present patent application are to be considered an integral part of the application except that to the extent any terms are defined in these incorporated documents in a manner that conflicts with the definitions made explicitly or implicitly in the present specification, only the definitions in the present specification should be considered.
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Number | Date | Country | |
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20190038504 A1 | Feb 2019 | US |