[0001] The present invention relates to a liquid applicator for dispensing toiletries to
the skin, and particularly for the application of antiperspirants and deodorants to
the human axilla.
[0002] Liquid applicators in general are well-known in the prior art, particularly the roll-on
type commonly for antiperspirants and deodorants. These are disclosed, for example
in U. S. Patent Nos. 2,749,566; 2,923,957; and 2,998,616. Because of problems with
roll-on type applicators, Berghahn et al., U. S. Patents 4,050,826 and 4,111,567,
devised a liquid applicator comprising a container fitted with a head having a fixed,
shaped form made of a non-flexible, non-deformable, sintered porous synthetic plastic
resin having a controlled porosity and having omni-directional, interconnecting pores.
The liquid overflow problems associated with conventional roll-ons is also present
with this type of head and is solved by the provision of a liquid collecting channel
adjacent the shaped applicator, permitting the excess liquid to drain back via the
channel into an opening through the head into the liquid reservoir. This avoids an
accumulation of liquid on the surface of the applicator and resulting crystallization
of product being delivered.
[0003] In a real sense, the porous plastic applicator of Berghahn et al. resembles the conventional
roll-on applicator except that the applicator is stationary and has a drain channel.
The liquid product being delivered must be brought into contact with the applicator
head in order for the liquid to be delivered to the surface by capillary action. This
requires inverting the container as is true of the roll-on type of head, since there
will always be dead space between the liquid in the reservoir and the applicator head.
Thus, no way is provided for the liquid in the reservoir always to be in contact with
the applicator head.
[0004] In the present invention, the applicator head may be of any suitable configuration,
but a convex outer surface has been found to be particularly suitable for contact
with various parts of the human body. Thus, the applicator head may have a hemispherical
outer surface.
[0005] The materials which are used to make the shaped applicator head are non-flexible,
non-deformable, sintered, porous synthetic resins having a controlled porosity and
having omni-directional interconnecting pores, formed of aggregates of united polymer
particles. The degree of porosity of the porous materials can be controlled in their
manufacture, thus insuring a wide range of porosity to suit a wide range of liquid
products of varying viscosities. Sintered, porous applicator heads may be fabricated
of high-density polyethylene, low-density polyethylene, ultra-high molecular weight
polyethylene, polypropylene, polyvinylidene fluoride, and the like. Products are available
commercially under the trade designations "Porex" porous plastics and "Porous Polv."
The pore size of the applicator may vary widely, depending on the liquid to be delivered.
Low-viscosity liquids, such as perfumes, may best be delivered via a small-pore plastic
applicator, e.g. , one micron or less. In general, the pore size may vary between
about one to 200 microns, and for most purposes, generally about 10-50 microns are
preferred.
[0006] The porous applicator is hollow and fits onto a cylindrical impervious sleeve or
tower which in turn fits into an annular plastic diaphragm spring. The spring in turn,
fits into the top opening of the container which forms a reservoir for the liquid
material to be dispensed. The impervious sleeve and diaphragm spring may also be molded
as a single part. The impervious sleeve serves two functions. First, it locks the
porous plastic applicator head to the diaphragm spring. Second, it directs fluid flow
to the uppermost area of the porous applicator which is the area mainly used for application.
The container can be filled solely with the liquid product. As an alternative, the
reservoir may contain an absorbent material, onto which the liquid to be delivered
is absorbed, and this absorbent material is in direct and intimate contact with the
porous applicator head. This aspect of the invention insures continuous contact of
the liquid with the applicator head and ease of delivery of the liquid on demand by
capillary flow. The absorbent material used in the reservoir may be any material capable
of absorbing the liquid to be delivered, such as cellulose acetate, polyester, cotton,
rayon, nylon, or other suitable material, and capable of transferring the liquid therefrom
continuously on demand by capillary flow (wicking). The absorbent material may take
any suitable shape or form. In one embodiment, the absorbent material is the same
non- deformable, non-flexible, sintered, porous synthetic resin material from which
the applicator head is constructed. The form may vary, but a particularly advantageous
delivery system will consist essentially of a container to hold the contents to be
delivered, fitted with the porous head having a cylindrical porous plastic tube extending
to the bottom of the container, and having a hemispherical top. The diameter of the
cylindrical piece need not be uniform, i.e., the portion extending into the container
is of a lesser diameter than the portion extending out of the container in order to
fit into the annular plastic spring.
[0007] The container may obviously be of any suitable material, such as metal, glass or
plastic.
[0008] The delivery system of the invention may be used to deliver any topical liquid product
to the skin. These may include, for example, after-shave lotions, pre-shave lotions,
skin lubricants or emollients, suntan lotions, fragrances (perfumes, colognes, etc.),
topical theraputics (analgesics, acne formulations, antiseptics, etc.), lip and face
rouge and the like. The delivery system is particularly useful in applying antiperspirants
and deodorants and avoids the problems associated with roll-on applications. Thus,
the invention provides a means of applying a low viscosity, fast drying, non-sticky
solution of aluminum chlorohydrate, avoiding the undesirable features of roll-ons,
pump sprays, and sticks.
[0009] Since the porous plastic materials are hydrophobic and do not "wet" with water, it
may be necessary to add alcohol to an antiperspirant formula to transfer the product
from the container to the applicator head. Crystallization of the solid components
of the solution, such as aluminum chlorhydrate, may be avoided by the addition of
certain esters, such as isopropyl myristate or isopropyl palmitate.
[0010] The invention may be better understood by reference to the drawings in which,
Figure I is a front elevational view of the dispenser with cap removed with parts
broken away to show a cross section of the applicator head, diaphragm spring and liquid
reservoir;
Figure 2 is a side elevational view of the container and cap with cap in cross-section;
Figures 3 and 5 are bottom plan views of the liquid container;
Figure 4 is a partial view of the container shown in Figure 1, in an inverted position,
to show directed liquid flow;
Figures 5, 6 and 7 are respectively top plan view, elevation view in cross-section
and bottom plan view of the diaphragm spring;
Figures 8, 9 and 10 are respectively top plan view, elevational view with parts broken
away and bottom plan view of the impervious sleeve; and
Figures 11, 12 and 13 are respectively top plan view, elevation view with partial
cross-section and bottom plan view of single piece impervious sleeve and diaphragm
spring.
[0011] Referring to the Figures 1 and 2, the liquid delivery system comprises an outer case
10 having a base 12 and a cap 14 which ius attached by means of threads 16 at the
top of case 10. It will be understood that cap 14 could be attached by a friction
fit also. Case 10 contains the liquid product 34 to be dispersed. A porous plastic
applicator head 20 is fitted onto impervious sleeve or tower 17 in fluid tight relationship
by a friction fit. Impervious sleeve 17, in turn fits into an annular elastic spring
35 through central opening 41 of spring 35 by friction fit or by snap lock engagement
as shown at 19. As shown in Figures 8 through 10, sleeve 17 has annular ridges 48
around the periphery of the outer surface at the upper end which are slightly larger
than the inner diameter of the applicator head 20, so that when sleeve 17 is pressed
into head 20, ridges engage the inner surface head 20 to assist in holding head 20
in position on sleeve 17. At the lower end of sleeve 17, there is a flange 49 extending
outwardly which holds sleeve 17 against the lower edge 50 of diaphragm spring 35.
In Figure 1, the head assembly is shown as a split image so that the left half illustrates
diaphragm spring 35 in its raised or relaxed position, and the left half illustrates
head 20 depressed and spring 35 at its lowest limit of travel. Head 20 is designed
so that lower surface 20A has sufficient clearance in the upper position to allow
a full stroke of downward spring 35. In additon, the right half of Figure 1 shows
that diaphragm spring 35 and tower 17 may be made as a single piece unit 47. (See
Figures 11 through 13). This is a production advantage for the part, eliminates an
assembly step and also provides better fluid tight conditions. The one piece sleeve
and diaphragm spring 47 consists of spring portion 52 which is basically similar to
spring 35 of Figures 5 through 7, and sleeve 53 which is basically similar to sleeve
17 of Figures 8 through 10. Since sleeve portion 53 is an integral part of the diaphragm
spring, it will be made of the same plastic material. Thus, while a unitary structure
offers certain advantages as discussed above, it might also be desirable that the
sleeve be of a different material to obtain different characteristics. Thus the use
of the two piece diaphragm spring and sleeve may be advantageous sometimes. The single
piece sleeve and spring 47 has ridges 48 on sleeve portion holding to applicator head
20. Spring portion 52 has an inward taper 58 on the lower end of the outer cylindrical
segment 54 to facilitate insertion into container 10. An abutment 55 is provided at
the base of sleeve 53 where it leads into the inner cylindrical segment 56 of spring
52. Abutment 55 is to aid in positioning applicator head 20 on the sleeve. Flange
57 is provided around the upper edge of outer spring segment 54 and seats on upper
edge 42 of container 10. Applicants' head 20 has an inner cylindrical portion 44 which
fits within outer cylindrical segment 36. The applicator head-spring and tower assembly
is inserted into container 10 and the other segment 36 of spring 35 forms a fluid
tight friction fit with flange 38 resting on the top rim 42 of container 10. In this
position, the inner cylinder 44 of the applicator head 20 extends within outer cylindrical
segment 36 of spring 35. In this arrangement the head 20 can move into the container
10 when pressure is applied to the head and the undulate surface 39 of spring 35 is
deformed. Applicator head 20 may be depressed until the shoulder 22 of head 20 contacts
flange 37 of spring 35 which then acts as a stop. Container 10 is filled with liquid
product 34 and the product is delivered to the surface of head 20 by first wetting
the inner surface 28 by inverting the container as shown in Figure 4, and then by
capillary flow through the pores of head 20. As seen in Figure 4, liquid 34 will be
directed by impervious sleeve 17 to the upper part 26 of the inner surface of applicator
head 20 so that this area only is wetted. This is the area where spreading will be
done and thus unnecessary flow through the sidewalls of head 20 is avoided. After
inversion and wetting of inner surface 26 of head 20, the container may again be held
in an upright position to apply the liquid to a surface, e.g. an antiperspirant to
the underarm area. When the outer surface 24 of head 20 is rubbed against the skin,
liquid product 34 is applied to the skin. The pressure on head 20 pushes the head
into container 10 increasing the pressure in the container, forcing liquid 34 out
through the pores of head 20, thus supplementing the capillary flow and assuring an
adequate flow of liquid product 34 to the outer surface of head 20. Applicator head
20 has a somewhat flattened outer surface 24 with the vertical side section 21 being
thicker than the upper surface 24. The flattened head provides a larger spreading
area for spreading the liquid 24 over a surface. Any liquid that runs down the sides
will be reabsorbed by the thickened area 22 of head 20. An advantageous alternative,
is to provide a slight degree of flexibility to the upper surface 24 of head 20, either
by thinning this area, or by molding the head of a material which will provide this
flexibility.
[0012] To facilitate wetting of applicator head 20, case 10 may be filled with an absorbent
material, not shown, filling container 10 and in contact with inner surface 26 of
applicator head 20.
[0013] As shown in Figures 1 and 2, cap 14 may have an inner absorbent member 59 which fits
closely over outer surface 24 of applicator head 20. Absorbent member 59 absorbs excess
liquid and also vapors which pass through head 20 due to changes in relative pressure
outside and inside the container, and also releases these back into the container.
[0014] A variety of liquid products may be dispensed by means of the invention. Illustrative
products are set forth in the following specific examples:
AFTER SHAVE LOTIONS
Example 1 - after shave lotion
[0015]
Example 2 - after shave lotion (high emollience)
[0016]
Example 3 - after shave lotion (low alcohol, antiseptic)
[0017]
PRE-SHAVE LOTIONS
Example 4 - pre-shave (beard softener and lubricant)
[0018]
Example 5 - pre-shave lotion
[0019]
Example 6 suntan liquid
[0020]
Example 7
[0021]
FRAGRANCE
Example 8 cologne (men's or ladies)
[0022]
1. A liquid applicator suitable for use in the application of liquids to a surface
of the human body comprising a container having a container body adapted for storing
a quantity of said liquid, said container having an opening at the upper end thereof;
annular spring means said annular spring means comprising concentric cylindrical segments
joined by an undulate annular planar member, said spring means being positioned in
said container, sleeve means associated with the inner of said concentric cylindrical
segments, hollow applicator means secured on said sleeve means; said annular spring
and sleeve means forming a liquid tight seal between said applicator means and said
container; said applicator means comprising a non-flexible, non-deformable, sintered,
porous synthetic resin resin structure having a controlled porosity and having omni-directional
interconnecting pores.
2. The liquid applicator of claim 1 wherein the outer cylindrical segment of said
spring means fits in the opening of said container.
3. The liquid applicator of claim 1 wherein said sleeve means is a separate sleeve
fitting within the inner cylindrical segment of said annular spring means.
4. The liquid applicator of claim 1 wherein said sleeve means is an integral part
of said annular spring means, said sleeve extending upwardly from the inner cylindrical
segment of said spring means.
5. The liquid applicator of claim 1 wherein said applicator head fits on said sleeve
means.
6. The liquid applicator of claim 1 wherein the upper edge of inner cylindrical segment
is lower in an axial direction than the upper edge of said outer cylindrical segment.
7. The liquid applicator of claim 1 wherein said undulate planar member has a downward
annular undulation.
8. The liquid applicator of claim 1 wherein said container contains an absorbent reservoir
means for said liquid.
9. The liquid applicator of claim 8 wherein said reservoir means comprises a natural
or synthetic fibrous material.
10. The liquid applicator of claim 2 comprising in addition a cap fitted over said
applicator means.