Dispenser cap with piercer

A cap for receptacles, particularly bottles made of plastic in a blow molding process which are filled and closed in the blow mold and which have a bottle neck, is placed on the bottle neck. The cap has, adjoining the section for receiving the neck, a section which forms one piece with the neck receiving section and which is designed as a dropper or other dispenser and a piercer.

FIELD OF THE INVENTION 
The present invention relates to a cap for receptacles, particularly 
bottles made of plastic in a blow molding process in which the bottles are 
filled and closed in the blow mold and have a neck on which the cap is 
placeable. The cap includes a dispenser for the bottle contents, and a 
piercer for opening a closure. 
BACKGROUND OF THE INVENTION 
Plastic bottles, with a neck and an outer thread on the neck, can be closed 
at the free end of the neck by a closure forming one piece with the neck. 
A piercer for piercing the closure is conventionally provided on the 
inside and at the center of a cap screwed onto the neck. When the cap is 
removed after the piercing of the closure, the liquid in the bottle can 
then be delivered through the opening formed in the closure by the 
piercer. 
A thread on the bottle neck and/or on the cap in not being of optimum 
shape, or the piercer in not being of optimum shape can cause the opening 
made by the piercer to extend at an incline to the longitudinal axis. 
Additionally, after removal of a partial amount and subsequent screwing-on 
of the cap, a second opening can be pierced. The inclined and/or multiple 
piercing results in the liquid flowing out in a direction deviating from 
the longitudinal axis, possibly at several points, which is troublesome. 
The pressure exerted on the liquid determines whether the liquid is 
delivered in larger or smaller drops or in the form of a jet. Furthermore, 
the size of the opening may change in the course of time if, after removal 
of a partial amount of the contents of the bottle, the neck is closed 
again by the cap and the piercer is introduced into the opening again. 
Therefore, obtaining the correct dosage of the amount to be removed is 
difficult. 
Additionally, conventional dispensing caps with piercers have flow channels 
extending in different directions which are difficult to form and require 
complex molds. 
SUMMARY OF THE INVENTION 
Objects of the present invention involve providing a cap for a receptacle 
enabling problem-free removal of the liquid contents of the receptacle 
either in the form of single drops of a defined size or in the form of a 
jet. 
Other objects of the present invention involve providing a dispenser cap 
with a piercer which is simple and economical to form. 
The foregoing objects are obtained by a cap for receptacles, particularly 
bottles made of plastic in a blow molding process which are filled and 
closed in a blow mold and have a bottle neck. The cap comprises a first 
section having coupling means for receiving the bottle neck, and a second 
section formed as one piece with the first section and having dispensing 
means. The second section has an inside end face and a piercer tapering 
from the inside end face. The piercer has a circumferential surface and a 
pointed tip extending inside the first section. A flow channel extends 
through the dispensing means and the piercer, and includes an intermediate 
section having a substantially constant cross-sectional configuration and 
an end section which opens on the circumferential surface. The 
intermediate section extends along a first longitudinal axis. The end 
section extends from the intermediate section and along a second 
longitudinal axis parallel to the first longitudinal axis, and has a 
cross-sectional configuration wholly within an axial extension of the 
cross-sectional configuration of the intermediate section. 
With the second section of the cap of the present invention being designed 
as a dropper or other dispenser, the dosing during delivery of the liquid 
contents of the bottle is not carried out or controlled by an opening 
formed by the bottle neck. The dosing is controlled by the dropper or 
other dispenser of the cap. This dropper or dispenser can be designed 
without any problems such that, independently of the prevailing pressure, 
the dropper or dispenser forms drops of a reproducible size and reliably 
excludes delivery in the form of a jet, or brings about delivery in the 
form of a jet. 
The bottle closure can be pierced by the piercer as in the known caps 
having a piercer. As the dropper or dispenser carries out the dosing, the 
opening need not be formed exactly at the center and coaxially in the 
closure and its size can deviate from the set value. 
In order that the piercer can have a sharp point, the flow channel end 
section leads into or opens on the circumferential surface of the piercer. 
The end section comes to rest within the bottle neck when the cap is 
screwed completely onto the neck. With the end section extending parallel 
to the intermediate section and having a cross-sectional configuration 
wholly within an axial extension of the cross-sectional configuration of 
the intermediate section, the entire flow channel can be simply and 
reliably formed by a single, axial movable member without any relatively 
movable parts, such as a calibrating mandrel. 
Very good reproducibility of the drop size and reliable prevention of 
jet-shaped delivery of the bottle contents are achieved with a flow 
channel of the dispenser in which a section expands conically in the 
discharge direction and adjoins a cylindrical section. These sections are 
preferably calibrated during manufacture by a calibrating mandrel. 
The cap can be arranged on the neck with a close sliding fit. However, the 
section of the cap receiving the neck will be provided with an inner 
thread which corresponds in design to an outer thread on the bottle neck. 
In a preferred embodiment, a closure part is removably placed on the cap 
section designed as dropper. The closure part is provided to protect the 
flow channel of the dropper. This closure is preferably designed as a 
pot-shaped hood with an inner thread corresponding to and mating with an 
outer thread on the cap section designed as dropper. A plug which is 
sealingly introducible into the flow channel of the dropper can be formed 
at the center of the inside surface of the bottom of this hood. 
Other objects, advantages and salient features of the present invention 
will become apparent from the following detailed description, which, taken 
in conjunction with the annexed drawings, discloses preferred embodiments 
of the present invention.

DETAILED DESCRIPTION OF THE INVENTION 
As illustrated in FIG. 1, the plastic cap of the first embodiment of the 
present invention, designated in its entirety as 1, comprises a first, 
hollow, cylindrical section 2 receiving neck 3 of a bottle. In the 
illustrated embodiment, the bottle is made from plastic in a blow molding 
process and filled and closed in the blow mold. The bottle is formed with 
a plate-shaped closure 4 closing neck 3 and formed unitarily, as one piece 
with the neck 3, and can be an ampule. 
Neck 3 of the bottle is provided with an outer thread 5. Between bottle 
body 3' and the end of outer thread 5, but lying closer to or adjacent 
outer thread 5, neck 3 has a cylindrical section 6. The outer diameter of 
neck cylindrical section 6 is chosen such that it is identical with that 
of the outer thread 5. Adjoining the end of neck cylindrical section 6 
facing the bottle body 3' is a toroidal ring 7. Ring 7 projects radially 
outwardly to a slight extent over or beyond cylindrical section 6. The 
outer diameter of toroidal ring 7 is slightly larger than the inner 
diameter of the zone forming the free end of first section 2. 
Section 2 is provided with an inner thread which corresponds to and mates 
with outer thread 5 of neck 3. The inner thread does not extend into the 
zone forming the free end section. 
Adjoining section 2, on the side facing away from the bottle body 3' is a 
second section of the cap designed as a dispenser in the form of a dropper 
8. Dropper 8 has the same longitudinal axis as section 2, and is formed 
unitarily as one piece with section 2. The section designed as dropper 8 
is provided with an outer thread 9. The free end of dropper 8 is rounded 
off to define semispherical shape. 
A conical piercer 10 is formed at the center of the inside end face 8' of 
the dropper 8. Inside end face 8' is at the transition from section 2 to 
dropper 8. The tip of piercer 10 points into the interior of section 2. 
Except for end sections 11 of the flow channel extending through the 
dropper 8, the dropper flow channel has the same axis as the piercer 10. 
End sections 11 lead into the circumferential surface of piercer 10. 
Joining end sections 11, the flow channel has a cylindrical middle section 
12 connecting the end sections to a conical section 13. Conical section 13 
expands to the semispherical end of the dropper 8. Both the middle section 
12 and the conical section 13 are calibrated during manufacture by a 
calibrating mandrel. 
As illustrated in FIG. 1, the transverse cross-sectional diameter of the 
middle section 12 is considerably smaller than its axial length. This 
characteristic also applies to the conical section 13 which has a 
relatively small cone angle. In the illustrated embodiment, the cone angle 
is approximately 8.degree.. 
The design of the flow channel, particularly its two sections 12 and 13, 
may be different. The design depends on the characteristics of the liquid, 
for example, its viscosity and surface tension, as well as the size of the 
drops, and on whether delivery is desired in the form of drops or a jet. 
A pot-shaped protective hood 14, like the cap 1, is formed of plastic. The 
hood covers dropper 8. The protective hood 14 is provided with an inner 
thread corresponding to and mating with outer thread 9 of dropper 8, and 
extends almost as far as the outside shoulder of cap 1 formed at the 
transition from section 2 to dropper 8. A plug 15 is integrally formed at 
the center of the bottom or closed end of the protective hood 14, on the 
inside, surface of the closed end. The plug 15 engages and is received in 
conical section 13 and seals the conical section when the protective hood 
14 is fully screwed onto the dropper 8. 
If the bottle is marketed with cap 1, cap 1 is screwed onto bottle neck 3 
until the free end of section 2 extends as far as toroidal ring 7 of neck 
3, as illustrated in FIG. 1. This position is easily recognized by the 
fact that when cap 1 is screwed further onto bottle neck 3, section 2 
comes into contact with the toroidal ring 7, and hence an increased torque 
has to be applied. When cap 1 is screwed onto bottle neck 3 as far as 
toroidal ring 7, piercer 10 is in contact with or almost in contact with 
bottle closure 4. 
When the contents of the bottle are to be removed, cap 1 is screwed fully 
onto the neck 3. As piercer 10 pierces bottle closure 4 and the toroidal 
ring 7 is overcome, a clearly discernible increased torque has to be 
applied. The increased torque does not create any difficulties because of 
the longitudinal ribbing on the outside circumferential surface of section 
2. When piercer 10 has completely pierced bottle closure 4, the outer end 
face of the bottle closure rests against end face 8' of dropper 8 carrying 
piercer 10. In this position, end sections 11 of the flow channel of the 
dropper extend into the interior of the neck 3. Protective hood 14 now 
only needs to be screwed off of dropper 8 to enable removal of the 
contents of the bottle in the form of single drops of a defined, 
reproducible size. However, if the flow channel is designed for delivery 
of the liquid in the form of a jet of a defined size, the liquid is 
delivered in the form of a jet. 
FIGS. 2 and 3 illustrate a cap dropper 8 with conical piercer 10 having a 
flow channel according to a second embodiment of the present invention. In 
this second embodiment, the flow channel has a flow channel intermediate 
section 21 in the form of a constant right circular cylinder extending 
along a longitudinal axis which is coaxial with the longitudinal axes of 
the cap and piercer. Section 21 terminates just above inside end face 8', 
and corresponds to section 12 of the first embodiment. A end section 22, 
in the form of a right circular cylinder extends from section 22 as a 
direct and straight prolongation of section 21, but with a small 
cross-sectional configuration. Specifically, section 22 has a smaller 
transverse cross-sectional diameter than section 22, and a cross-sectional 
configuration wholly within an axial extension of the cross-sectional 
configuration of section 21. The longitudinal axis of section 22 is 
laterally spaced from and is parallel to the longitudinal axis of section 
21 such that sections 21 and 22 are eccentrically offset. Section 22 forms 
an opening 23 on side or circumferential surface 24 of piercer 10, spaced 
from the piercer tip. 
FIGS. 4-6 illustrate cap dropper 8 with conical piercer 8 having a flow 
channel according to a third embodiment of the present invention. In this 
third embodiment, flow channel intermediate section 31 is in the form of a 
constant right circular cylinder extending along a longitudinal axis which 
is coaxial with the longitudinal axes of the cap and piercer. Section 31 
terminates just above inside end face 8', and corresponds to section 12 of 
the first embodiment. An end section 35, having a substantially constant 
cross-sectional configuration of a three-pointed star, extends coaxially 
from and as a prolongation of section 31. Each of the three portions 36 of 
end section 35 extends radially outwardly from a central portion 
terminating inside said piercer to form three spaced apart openings 33 on 
side or circumferential surface 34 of piercer 10, spaced from the piercer 
top. Portions 36 are angularly offset by equal angles to space openings 33 
equally. The cross-sectional configuration of end section 35 is wholly or 
entirely within an axial extension of the circular cross-sectional 
configuration of section 31. 
The flow channels at FIGS. 2-6 can be simply and accurately formed by a 
one-piece calibrating mandrel. This mandrel need only be moved axially 
within the mold forming the cap. A mandrel with multiple movable parts or 
a multiple step forming process is not required. 
While various embodiments have been chosen to illustrate the invention, it 
will be understood by those skilled in the art that various changes and 
modifications can be made therein without departing from the scope of the 
invention as defined in the appended claims.