A child-resistant dispensing closure consisting of a one-piece molding of resilient material that comprises an inverted cup-shaped cap having a central dispensing opening and a saucer shaped lid that is integrally hinged to the cap at one edge thereof for movement to and from an inverted, closing position closely overlying the cap. The lid has an element which closes the dispensing opening and engages in telescoping relationship therewith. The cap and lid have overlapping catch means for retaining the lid in closing position. The hinge is double acting and provides not only for angular movement to and from the closing position but also for lateral movement of the lid relative to the cap against the resilience of the engaged element and opening for disengaging the catch means. In a preferred embodiment, the dispensing opening is in the upper end of a nozzle which is an integral part of the cap and the closing element is on the underside of the lid, so that it engages the upper end of the nozzle and closes the nozzle opening.

BACKGROUND OF THE INVENTION 
Because of the fact that many substances found in an average home are 
extremely dangerous and often life threatening, particularly if consumed 
by a child of tender years, much emphasis has been placed on packaging 
many such substances in containers provided with child-resistant caps. For 
examples, many drugs, both prescription and over-the-counter, are so 
packaged, as are some dangerous liquid and particulate substances such as 
anit-freeze for automobiles, drain cleaners, furniture polishes, etc. 
Most of the child-resistant caps which so far have been developed fall into 
either of two general classes. Some of the caps consist of two separate 
parts which must be assembled to each other before being placed upon the 
containers which they are to fit. Others have been so designed as to 
consist of only one integral or unitary piece, thus reducing the cost of 
manufacture by eliminating the necessity for a second mold and for an 
assembly task. 
The most successful of the child-resistant closures usually have had two 
features in common. First, in order to remove or open the closure, it has 
been necessary that two separate and dissimilar movements or actions take 
place. It has been found that a child of tender years, say six or less, 
usually does not readily comprehend how these two dissimilar actions must 
be performed, although an older child or an adult can do so by reading the 
instructions which usually are printed or molded on the closures. 
Secondly, some of the most successful child-resistant closures have also 
had the property of clearly indicating to an observing adult whether or 
not the closure is in child-resistant status or merely has been returned 
to its container without being restored to protective condition. 
Unfortunately, many other substances which commonly are found in domestic 
situations have not yet been provided with satisfactory child-resistant 
closures. For examples, toilet bowl cleaning liquids, dishwashing liquids, 
and others, which usually are packaged in containers having dispensing 
openings, still appear in the market place with closures which an average 
small child can readily open. 
Some closures for such substances have been provided with what might be 
called "snap-caps," i.e., caps which require that they be removed by the 
exercise of a fairly substantial amount of force, as, for example, to lift 
one edge so that the closure can be opened. The cap disclosed in Babiol 
U.S. Pat. No. 4,010,875 would possess some child-resistant features simply 
by reason of the fact that a small amount of force is required to 
disengage the closing lid from the cap body so that it can be swung into 
open position and the content material dispensed from the container. 
However, it also has been found that where but a single movement is 
required, as in the Babiol closure, even a very small child readily can 
open the closure. In many cases, the child holds the container in one hand 
and bites into the cap, whereupon he possesses more than adequate strength 
to open the closure. 
Many prior art child-resistant caps can be replaced upon their containers 
in what seems to be closed position without actually being re-established 
in child-resistant status. As a result, if the user is inattentive or a 
little bit careless, it may seem that the closure is safe although it 
really is not. 
It is, therefore, the principal object of the invention to provide a 
child-resistant dispensing closure particularly designed to be utilized on 
containers of liquid materials which are dispensed in small quantities. 
It is a second and equally important object of the instant invention to 
provide a child-resistant dispensing closure which positively indicates 
whether or not it is in protective status and which automatically returns 
to child-resistant status every time it is closed. 
Yet another object of the instant invention is to provide a child-resistant 
dispensing closure which requires that two completely dissimilar actions 
be simultaneously performed in order to open the closure. 
And yet another object of the instant invention is to provide a 
child-resistant dispensing closure having the foregoing features which 
readily can be manufactured as a single, unitary piece of resilient, 
resinous material such as polypropylene or the like, thus enabling 
high-speed production in multi-cavity molds in order to minimize cost. A 
further object of the instant invention is to provide a unitary 
child-resistant dispensing closure, the parts of which have exteriors so 
designed that the closures may be placed upon containers by the use of 
conventional automatic capping machines.

DESCRIPTION OF PREFERRED EMBODIMENTS 
A first embodiment of a child-resistant dispensing closure according to the 
invention is illustrated in FIG. 1-9, inclusive. The closure, generally 
indicated by the reference number 20, is a unitary structure and is shown 
in FIGS. 1-7, inclusive, as being in position on a container 21 which has 
a threaded neck. 
The closure 20 comprises an inverted, cup-shaped cap 22 and a lid 23 which 
are hingedly connected to each other by a double-acting hinge, generally 
indicated by the reference number 24. 
The cap 22 also has an inner, co-axial skirt 28 which is connected at its 
upper end to the upper end of the outer skirt 25 by an annular web 29. A 
lower, inwardly-directed web 30 is integral with the lower edge of the 
inner skirt 28, and its inner, circular edge defines an opening into the 
lower end of an axially extending nozzle 31, which is integral therewith. 
The nozzle 31 protrudes upwardly beyond the top web 29 and has a 
dispensing orifice 32 at its upper end. 
The lid 23 has a disc-like top 33 and, in the illustrated embodiment, is 
generally saucer-shaped, having a conical rim 34. A nozzle closing element 
35 is formed on the inner surface of the lid 33, as best can be seen in 
FIG. 5. 
The lid 23 is integrally connected to the cap 22 by the double-acting hinge 
24, which has two leaves 36 and 37. The hinge 24 is located in an 
inwardly-extending recess 38, formed partly in the top 33 of the lid 23 
and in the rim 34 thereof. The hinge leaf 36 is connected to the edge of 
the cap 22 by a narrow, flexible web 39. The leaf 36 is connected to the 
leaf 37 and, in turn, the leaf 37 connected at its opposite side to the 
lid top 33 by thin, flexible portions 40 and 41. 
Angular movement of the lid 23 from the fully open position illustrated in 
FIGS. 3 and 4 is accomplished by swinging the lid 23 over to a position 
above the cap 22, the web 39 providing for this movement. 
When the lid 23 approaches the closed position of FIGS. 1 and 5, engagement 
takes place between lid catch means on the lid 23 and the cap 22. These 
catch means consist of an arcuate, over-hanging lip 42, erected above the 
top web 29 at the side opposite the hinge web 39, and an undercut, 
complementary rib on the inner side of the lid rim 34, which also is 
located opposite the web 39. 
As can best be seen by reference to FIG. 7, when the lid 23 is moved toward 
closed position illustrated in FIGS. 1 and 5, engagement between the lip 
42 and rib 43 pulls the lid 23 over (to the left in FIG. 7), flexing the 
hinge 24 at the web 39 and the flexible portion 40. Because the closing 
element 35 already has telescoped over the upper end of the nozzle 31, as 
shown in FIG. 7, the lateral movement of the lid 23 at this point also 
pulls over the upper end of the nozzle 33, flexing either the nozzle 33 or 
the lower web 30, or both. 
Immediately thereafter the lid 23 is moved downwardly its last increment of 
arcuate movement to the closed position of FIGS. 1 and 5, the resiliency 
of the nozzle 31, web 30, and hinge 24 pulling the lid 23 back (to the 
right in FIG. 7) snapping the rib 43 beneath the lip 42, to the position 
illustrated in FIG. 5. 
It will be appreciated, of course, that in order for the just described 
actions to occur when the lid 23 is moved from its fully open position of 
FIGS. 3 and 4 to its fully closed position of FIGS. 1 and 5, the material 
from which the closure is fabricated must be a resilient material, for 
example, polyethylene or the like. 
The rib 43 and lip 42 function as a child-resistant catch means to retain 
the lid 23 in the closed position of FIGS. 1 and 5, and, as can be seen in 
those figures, the outside circumference of the lower margin of the lid 
rim 34 and the hinge web 36 are such that they are no larger than, and 
preferably the same size as, the diameter and circumference of the outer 
edge of the cap top web 29. The coincidence of the edges of the lid 23 and 
the cap 24 thus disguises the functioning described above and also 
practically eliminates the possibility that one can open a closure 
embodying the invention merely by swinging the lid 23 from from the closed 
position to the open, or dispensing, position. 
Because of the telescoping engagement of the upper end of the nozzle 31 and 
the closing element 35 and the resiliency of the material from which these 
parts are fabricated, the lid 23 is snugly retained in its closed position 
by the engagement of the catch means 42 and 43, as described. 
In addition, because there are no parts of the cap 22 or the lid 23 which 
protrude radially beyond the common periphery of the edges thereof, the 
closure readily can be handled by conventional automatic capping 
machinery. 
When an older child or an adult desires to dispense material from the 
container, it is necessary that two simultaneous dissimilar actions be 
performed. First, the person must push the lid 23 from the position 
illustrated in FIGS. 1 and 5 to the position illustrated in FIGS. 2 and 6. 
This is made possible by the flexing of the double-acting hinge 24 on the 
web 39 and flexible portions 40 and 41 as illustrated in FIG. 6 and is 
resisted by the resiliency of those hinge elements as well as the 
resiliency of the nozzle 31 and/or the lower web 30. This action is 
necessary in order to move the rib 43 on the lid 23 outwardly relative to 
the lip 42. As can be seen in FIG. 6, this causes the edge of the lid rim 
34 to protrude laterally beyond the upper edge of the outer cap skirt 25 
so that it can be engaged by the finger of the user. The user may then 
swing the lid upwardly and around the hinge web 39 to the open position of 
FIGS. 3 and 4. 
However, if the lateral pressure on the lid 23 against the resiliency of 
the several elements is released before the now-protruding edge of the cap 
rim 34 is engaged, the lid simply snaps back to the closed position 
illustrated in FIGS. 1 and 5. 
It is this requirement for simultaneous, dissimilar actions and the 
continuing necessity to hold the lid 23 in its laterally displaced 
position against the resiliency of the parts as described before it can be 
swung to the open position, which renders the cap strongly 
child-resistant. Indeed, the degree of resistance to the lateral movement 
of the lid 23 relative to the cap 22 and thus the degree of 
child-resistance may be modified as desired simply by stiffening the 
material from which the cap 22 and lid 23 are molded, either by selection 
of the particular compound or by different thicknesses of the various 
sections of the molded parts. 
In addition, in this embodiment of the invention, means are provided to 
positively retain the entire closure 20 on the neck of the container 21. 
These means consist of cooperating one-way ratchet teeth 44 on the neck of 
the container 21 and 45 on the outer skirt 25 of the cap 20, as shown in 
FIG. 9. 
In the particular embodiment of the invention illustrated in FIGS. 1-9, 
inclusive, it will be noted that the dispensing orifice 32 is not centered 
at the top of the nozzle 31, but is inclined at an angle of 45.degree., 
more or less, so that when the material is dispensed through a closure 
embodying the invention, it can be directed upwardly or laterally. This is 
particularly useful when materials, such as toilet bowl cleaner, are 
packaged in containers having closures embodying the invention. For other 
materials, the dispensing orifice may be located at the peak of the nozzle 
31 and it may be of such size as is desired for that particular material. 
FIGS. 10-12 
FIGS. 10, 11, and 12 show a second embodiment of the invention in which a 
closure 50, like the earlier described embodiment, consists of a threaded 
cap 51 and a lid 52 which is integral therewith. In this embodiment, 
however, the cap 51 has a generally disc-like top 53 in which there is 
molded a central dispensing orifice 54. A double-acting hinge 55 connects 
the lid 52 to the cap 51 and the cap 51 and lid 52 are provided with catch 
means 56 and 57, respectively, as in the earlier embodiment. In this 
structure, the lid 52 has a stopper 58 formed on the under-surface of the 
top of the lid 52, the base of the stopper 58 blending into a thinner 
portion 59 of the lid 52. As can be seen in FIG. 11, in closed position of 
this embodiment, the stopper 58 extends into the orifice 54. 
As is illustrated in FIG. 12, when it is desired to open the closure 50, 
the lid 52 is pushed laterally relative to the cap 51 to which it is 
integrally connected by the hinge 55. This flexes the hinge 55 in the 
manner previously described. In this embodiment, because the stopper 58 is 
engaged in the dispensing orifice 54, lateral movement of the lid 52 
flexes the thinner portion 59 of the lid top and resiliently resists the 
lateral movement in the same fashion as the resistance to such movement is 
provided by the structure illustrated in FIGS. 1-9. Again, it is first 
necessary to shift the lid 52 laterally and, while holding it in 
laterally-shifted position against the resiliency of the structural 
elements, to catch its lower protruding edge at the side opposite the 
hinge 55 in order to swing it upwardly to the open position of FIG. 10. 
FIGS. 13-14 
FIGS. 13 and 14 show a closure 60 consisting of a cap 61 and a lid 62. In 
this embodiment, the cap 61 has a top 63 with a protruding nozzle 64 which 
defines a discharge orifice. In common with the earlier embodiments, the 
cap 61 and lid 62 are integrally connected by a double-acting hinge 65. 
The hinge 65 provides not only for swinging movement between a fully open 
position and the closed position illustrated in FIG. 13, but also for the 
lateral movement illustrated in FIG. 14. 
A short nozzle plug 66 is molded on the under-surface of the top of the lid 
62 and is of such size as to fit into the open end of the nozzle 64 in the 
closed position illustrated in FIG. 13. Thus, as best illustrated in FIG. 
14, when the lid 62 is laterally moved to disengage the lid 62 in order 
that the closure may be opened, the resiliency of the nozzle 64 resists 
this movement in the same manner in which the comparable flexible members 
of the embodiments of FIGS. 1-9 and FIGS. 10-12 function. 
In contrast to the embodiments of FIGS. 1-9 and 10-12, the embodiment of 
FIGS. 13 and 14 is retained on the end of a container neck 67 by 
over-lapping, annular rings 68 on the exterior of the neck 67 and 69 
formed on the interior wall of the cap 61. 
FIG. 15 
The embodiment illustrated in FIG. 15 is very similar to that of FIGS. 
13-14. A closure 70 consists of a cap 71 and a lid 72. The cap 71 has a 
top 73 and an integral, protruding nozzle 74 which provides a discharge 
orifice. The cap 71 and lid 72 are connected by an integral hinge 75. 
In this embodiment a closing element 76 is molded on the underside of the 
top of the lid 75 and fits circumjacent the end of the nozzle 74 in the 
same manner as the cup-shaped closing element 35 of FIGS. 1-9. 
In common with the embodiment of FIGS. 13-14, the closure 70 is retained on 
a container neck 77 by inter-engaged rings 78 on the exterior of the 
container neck 77 and 79 on the inner surface of the cap 71. 
FIGS. 16-18 
A closure 80 consists of a cap 81 and a lid 82 similar to those previously 
described. As in earlier embodiments, the cap 81 has a top 83 and a 
protruding nozzle 84 which defines a discharge opening. The cap 81 and lid 
82 are integrally connected by a relatively thin web of material which 
forms a hinge 85. The hinge 85 of this embodiment differs from the hinges 
of earlier embodiments in that it does not have a number of parts with 
intervening thinner portions upon which it flexes, but, by reason of its 
thin section, provides for both the angular swinging motion and the 
lateral release movement, i.e., the movement from the closed position 
shown in FIG. 17 to the initial position illustrated in FIG. 18, which 
disengages the catch means. As in the embodiment of FIGS. 13-14, the lid 
82 has an interior closing element 86 which enters the end of the nozzle 
84 in closed position, and, as earlier described, this engagement provides 
the resilient resistance to the movement from the position of FIG. 17 to 
the position of FIG. 18. 
The embodiment of FIGS. 16-18 (see particularly FIG. 16) is retained on a 
container neck 87 by interengaging rings 88 and 89, as is the case with 
respect to the embodiment of FIGS. 13-14 and 15. 
It will be noted that the particular means by which a closure is retained 
on the neck of a container does not, in itself, constitute a part of the 
instant invention, inasmuch as interengaging threads or interengaging 
rings are well-known conventional means for doing so.