Method of forming a seal over a cork in a necked bottle

Information

  • Patent Grant
  • 6655115
  • Patent Number
    6,655,115
  • Date Filed
    Thursday, November 2, 2000
    24 years ago
  • Date Issued
    Tuesday, December 2, 2003
    21 years ago
Abstract
An apparatus and an automated method are disclosed by which embossed seals are created in the necks of corked bottles. A die is employed with an image bearing die surface. The bottle moves along an automated bottle track. Molten seal material is introduced into the cavity above the cork in the neck of the bottle. The image bearing surface of the seal embossing mechanism is superimposed over the mouth of the bottle containing the molten seal material. The seal embossing mechanism is centered relative to the top of the bottle. The die surface is extended from the seal embossing mechanism into contact with the surface of the molten seal material. The mechanism is motivated along an automated seal track coincident with the movement of the bottle along the automated bottle track with the image bearing die surface in contact with the molten seal material until the material has cooled so that the die impression will be retained by the sealing material. The image bearing die surface is then retracted.
Description




BACKGROUND OF THE INVENTION




The present invention relates generally to sealing corked bottles, and, more particularly, to automated methods and apparatus by which seals having high quality embossed images are formed in necked bottles.




Current methods for sealing the tops of corked bottles have various drawbacks. A common method involves the use of metal foils secured over the entire mouth and some of the neck of the bottle. Although this method provides a tamper resistant seal, the metal foils have been commonly made of lead, which has been shown to leave traces of the poisonous chemical on the glass surface of the mouth of the bottle. The more recent adoption of nontoxic metal foils has not been fully successful and better methods of sealing the neck of the bottle are still desired.




Another current method involves the insertion of a preformed thermoplastic disc in the cavity in the neck of the bottle above the cork. In order to create a seal over the cork, the neck of the bottle is heated to a point at which the thermoplastic material will melt. The heating of the bottle, especially to a temperature at which the thermoplastic disc will fully liquify, presents problems when the contents of the bottle are heat sensitive, such as wine. Additionally, the heating of the bottle may produce imperfections in the bottle's material, thus creating potential weak points in the neck of the bottle.




The present invention provides a means for creating an aesthetically pleasing seal over the corks of necked bottles without compromising the integrity of the bottle or its contents. Additionally, this method deals solely with thermoplastic materials which are safe if traces remain on the mouth of the bottle.




SUMMARY OF THE INVENTION




The present invention is directed to an apparatus and an automated method by which embossed seals are created in the necks of corked bottles. A die is employed with an image bearing die surface. The bottle moves along an automated bottle track. Molten seal material is introduced into the cavity above the cork in the neck of the bottle. The image bearing surface of the seal embossing mechanism is superimposed over the mouth of the bottle containing the molten seal material. The top of the bottle is centered relative to the seal embossing mechanism. The die surface is extended from the seal embossing mechanism into contact with the surface of the molten seal material. The mechanism is motivated along an automated seal track coincident with the movement of the bottle along the automated bottle track with the image bearing die surface in contact with the molten seal material until the material has cooled so that the die impression will be retained by the sealing material. The image bearing die surface is then retracted.




In the preferred embodiment of the present invention, the mouth of the bottle is generally centered below the seal embossing mechanism by lowering a cone shaped centering member over seal embossing mechanism the mouth of the bottle before the molten seal material is allowed to cool in the neck of the bottle. The seal embossing mechanism is then centered more accurately by inserting a circular centering piston into the mouth of the bottle. The die surface on which there is a die image is then lowered from the seal embossing mechanism into contact with the surface of the molten seal material. Contact between a seal embossing surface and the surface of the molten seal material is maintained while the bottle and a seal embossing mechanism are simultaneously motivated down the track. Contact between a seal embossing surface and the surface of the molten seal material is maintained for a period of time long enough to allow for the seal material to cool to a state in which the seal impression will be maintained.




In accordance with the preferred embodiment of the invention, the seal embossing mechanism for forming the embossed seal in the neck of the bottle includes an actuator guide block and a die holder coupled with the actuator guide block using an actuator spring. The die holder is moveable relative to the actuator guide block between a rest position and a compressed position. The actuator spring is compressed in the compressed position to bias the die holder toward the rest position. The die holder includes a die stem having a die support portion and a spring seat. A centering member may be coupled with the spring seat by an engagement spring, if necessary, and would thus be movable relative to the spring seat between a rest position and a compressed position.











The novel features which are characteristic of the invention, as to organization and method of operation, together with further objects and advantages thereof will be better understood from the following description considered in connection with the accompanying drawings in which a preferred embodiment of the invention is illustrated by way of example. It is to be expressly understood, however, that the drawings are for the purpose of illustration and description only and are not intended as a definition of the limits of the invention.




BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a cross-sectional view of a neck of a corked bottle which has been sealed with a thermoplastic material in accordance with the teachings of the preferred embodiment of the present invention;





FIG. 2

is a perspective view of the seal of

FIG. 1

;





FIG. 3

is a front elevation view of a bottle sealing apparatus in accordance with an embodiment of the present invention;





FIG. 4

is a side elevation view of the bottle sealing apparatus of

FIG. 3

;





FIG. 5

is a rear elevation view of the bottle sealing apparatus of

FIG. 3

;





FIG. 6

is a front elevation view of a die truck assembly in accordance with an embodiment of the present invention;





FIG. 7

is a side elevation view of the die truck assembly of

FIG. 6

with partial cross sections;





FIG. 8

is a cross sectional view of the die truck assembly of

FIG. 6

taken along line I—I;





FIG. 9

is a side elevation view of the die truck assembly of

FIG. 6

illustrating the compression of the actuator spring;





FIG. 10

is a side elevation view of the die truck assembly of

FIG. 6

illustrating the compression of the engagement spring;





FIG. 11

is a side elevation view of the die truck assembly of

FIG. 6

illustrating the compression of the die stem spring;





FIG. 12

is a side elevation view of the die truck assembly of FIG.


6


and the bottle neck and cork of

FIG. 1

;





FIG. 13

is a side elevation view of the die truck assembly of FIG.


6


and the bottle neck and cork of

FIG. 1

illustrating the initial centering of the die truck assembly over the neck of the bottle;





FIG. 14

is a side elevation view of the die truck assembly of FIG.


6


and the bottle neck and cork of

FIG. 1

illustrating the further centering of the die truck assembly over the neck of the bottle; and





FIG. 15

is a side elevation view of the die truck assembly of FIG.


6


and the bottle neck and cork of

FIG. 1

illustrating the insertion of the die surface of the die truck assembly into the neck of the bottle.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS




The preferred embodiment of the bottle sealing method and apparatus of the present invention employs a die having a die surface with a die image of a logo or design. The die surface is used to form a seal with a logo or design in a bottle cavity in the neck of the bottle over the cork. The seal is formed by first introducing an amount of molten seal material into the bottle cavity. The die having a die surface with a die image is then brought into contact with the molten seal material in the bottle cavity. The molten seal material cools while in contact with the die surface having a die image and thus an embossed surface is created on the upper surface of the seal material.





FIG. 1

illustrates a bottle neck


10


with cork


12


disposed therein. A seal


22


provided by the preferred embodiment of the method and apparatus of the present invention is disposed in a bottle cavity


14


in the bottle neck


10


above cork


12


. The seal material is typically a thermoplastic material such as an organic polymer material, a synthetic thermoplastic material, or beeswax which melts when heated but which is a solid at room temperature. The top surface


20


of seal


22


facing outward and away from cork


12


is embossed to provide a design which is indicative of origin of the wine, or decorative, or both.

FIG. 2

shows the seal material


22


with the embossed surface


20


.




Bottle Sealing Apparatus





FIGS. 3 and 4

illustrate the preferred embodiment of a bottle sealing apparatus


30


for sealing corked bottles by forming the seals


22


of

FIGS. 1 and 2

in an automated process. Apparatus


30


includes an upper main support frame


32


connected with and supported above lower support frame


34


. Mounted on upper support frame


32


is an endless drive chain


36


, which travels along a path which includes a generally horizontal upper path portion


38


and a generally horizontal lower path portion


40


which are each generally straight. At the ends of path portions


38


and


40


chain


36


traverses a drive sprocket


42


and a guide sprocket


44


to form an oval-shaped carousel.




A plurality of die truck assemblies such as assembly


50


(only two are shown) are spaced along and coupled with endless drive chain


36


, which is driven to move the die truck assemblies continuously in a clockwise direction in the front elevation view of FIG.


3


. Each die truck assembly


50


includes a die cavity. Die truck assemblies


50


are desirably evenly spaced along endless drive chain


36


. Die truck assemblies


50


.are disposed with the die cavities oriented upward along upper path portion


38


of drive chain


36


, and are disposed with the die cavities oriented downward along lower path portion


40


.




A bottle conveyor


64


is provided below and disposed generally parallel to lower path portion


40


for conveying bottles


66


along a track in the same direction as die truck assemblies


50


along lower path portion


40


. While bottles


66


move along conveyor


64


, the speed of drive chain


36


is synchronized with the speed of conveyor


64


to generally align each die truck assembly


50


with the neck of one bottle. Upper support frame


32


includes a wheel track


68


, as best seen in

FIG. 3

, which generally tracks the path of drive chain


36


for guiding assemblies


50


. Wheel track


68


includes an offset portion along lower path portion


40


of drive chain


36


. The offset portion is offset in the downward direction, thereby guiding the actuation portions of die truck assemblies


50


downward to engage with the necks of bottles


66


over a portion of travel of endless drive chain


36


along lower path portion


40


.




Prior to engaging die truck assemblies


50


with bottles


66


, applicator


70


is provided near the start of lower path portion


40


for introducing an amount of molten seal material through nozzle


71


into the cavity in the neck of each bottle


66


, as seen in

FIGS. 3 and 5

. A reciprocator


72


is desirably provided for cyclically moving applicator


70


to follow the movement of each bottle


66


for a deposition time and to introduce the molten seal material into the cavity of the bottle


66


during the deposition time period. Reciprocator


72


begins at a first position and moves applicator


70


to a position to maintain nozzle


71


of applicator


70


in general alignment with the cavity of bottle


66


. Upon reaching the specified position, reciprocator


72


separates applicator


70


from bottle


66


and returns it to the first position to meet the next bottle


66


and begin the next cycle of reciprocating movement. The reciprocating motion can be generated by, for example, a rotating cam. In one embodiment, the deposition time is about 40-50 milliseconds for a travel distance of about 2 inches.




To ensure that the spacing between bottles


66


on conveyor


64


matches the spacing between die truck assemblies


50


on drive chain


36


for proper alignment and engagement of bottles


66


with assemblies


50


, a bottle guide


76


is provided near the start of conveyor


64


to guide bottles


66


onto conveyor


64


with spacing which matches the spacing between assemblies


50


. As best seen in

FIGS. 3 and 5

, the bottle guide in the embodiment shown is a timing screw


76


with a specific pitch. Rotating timing screw


76


advances bottles


66


and feeds them onto conveyor


64


. The speed of rotation of timing screw


76


is synchronized with the speed of drive chain


36


to generally align the necks of bottles


66


as they travel on conveyor


64


with die truck assemblies


50


.




As shown in

FIG. 5

, a single drive motor


80


is desirably provided for driving drive sprocket


42


, reciprocator


72


, and timing screw


76


in synchronism for forming seals


22


on bottles


66


. Drive motor


80


is typically a variable speed motor, and rotates main drive shaft


82


. Drive shaft


82


is coupled with gearbox


84


which is in turn coupled to sprocket drive belt


86


which drives drive sprocket


42


and drive chain


36


in rotation. The preferred embodiment employs a pair of horizontally spaced drive chains


36


which move in unison and provide a more secured connection with die truck assemblies


50


by coupling the two sides of assemblies


50


. Main drive shaft


82


also drives reciprocator


72


through reciprocator drive belt


94


rotating a cam. Main drive shaft


82


further drives timing screw


76


through timing screw drive belt


98


.




Drive belts


86


,


90


,


94


,


98


, and gearbox


84


preferably provide the proper rotational reductions and gear ratios so as to synchronize the movement and speed of drive sprocket


42


, reciprocator


72


, and timing screw


76


. This ensures that timing screw


76


feeds bottles


66


with the same spacing to match those between die truck assemblies


50


, and that reciprocator


72


moves applicator


70


at the same speed as each bottle


66


over the deposition time period. In this way, the process rate of the entire apparatus


30


can be easily changed by simply adjusting the speed of single drive motor


80


while preserving the synchronism of the various components.




In the preferred embodiment, apparatus


30


is easily adjustable to process bottles


66


of different heights. As shown in

FIG. 5

, drive chain


36


, drive sprocket


42


, applicator


70


, reciprocator


72


, and drive motor


80


are attached to upper support frame


32


. Timing screw


76


and bottle conveyor


64


are attached to lower support frame


34


. The vertical position of upper support frame


32


is adjustable relative to lower support frame


34


via a pair of jacking screws


102


. The height adjustment of upper frame


32


varies the vertical spacing between die truck assemblies


50


and bottle conveyor


64


, thereby adapting apparatus


30


to processing bottles


66


with different heights.




Die Truck Assembly





FIGS. 6-15

show details of die truck assembly


50


. Assembly


50


includes carrier plate


120


which is connected to drive chain


36


. Carrier plate


120


includes a U-shaped recess


121


and a pair of holes


123


. Actuator guide block


126


is generally fixed to carrier plate


120


by fastener


128


and includes grease fitting


129


, as seen in FIG.


7


. Actuator guide tube


130


is disposed through the opening


127


of guide block


126


and the U-shaped recess


121


of carrier plate


120


. Guide pin


132


is connected to guide tube


130


and constrained to move generally vertically along guide slot


134


in guide block


126


, thereby restricting the movement of guide tube


130


to the vertical direction relative to guide block


126


(FIGS.


6


and


7


).




As best seen in

FIGS. 6 and 7

, wheel bracket


136


is coupled to the top of guide tube


130


by fasteners


131


at one end and to actuator wheel


138


at the other end through spacer


140


. Inner wheel support


142


is coupled in the interior of wheel


138


by retainer clip


144


. Wheel


128


is coupled with wheel track


68


and rolls on the wheel track as assembly


50


is driven by drive chain


38


. As shown in

FIGS. 6-8

, actuator spring


148


is coupled between guide tube


130


and guide block


126


, and is compressible from the rest position shown to allow guide tube


130


to move downward relative to guide block


126


.




Spring seat


150


is attached to guide tube


130


, as best seen in FIG.


8


. Die stem


152


is disposed inside guide tube


130


and is slidable relative thereto generally in a vertical direction. Attached to the upper end of die stem


152


is stop


154


which defines the limit of downward movement of die stem


152


relative to guide tube


130


. At the lower end of die stem


152


is die support portion


156


for supporting die


157


having a die surface


159


with a die image for forming embossed surface


20


on seal


22


(FIGS.


1


and


2


). Die


157


is desirably made using a minting process which produces a high quality die with consistency and long life at a relatively low cost. Blocking member


158


, shown in

FIG. 8

as including a pair of jam nuts, is attached to die stem


152


and spaced below spring seat


150


by a distance. Guide tube


130


and die stem


152


form a die holder for supporting die


157


. The movements of guide tube


130


and die stem


152


facilitate formation of embossed seal portion


16


in die truck assembly


50


.




Centering member


160


is coupled with die stem


152


near die support portion


156


and is slidable generally vertically relative to die stem


152


. Centering member


160


has a generally conical shape enlarging in a direction away from spring seat


150


. As seen in

FIG. 8

, the conical inner surface of centering member


160


conveniently centers the cavity above cork


12


in neck


10


of bottle


66


with respect to die


157


of die truck assembly


50


when die stem


152


is moved downward to engage with the bottle.




Die truck assembly


50


also includes inner cone


161


, as illustrated in

FIG. 12

, for further centering of the assembly with bottle. Inner cone


161


is a cylindrical shaft which is contained within the upper section of centering member


160


. Inner cone


161


is in operable contact with die stem


152


and is able to move in a vertical direction within centering member


160


. Contained within inner cone


161


is die


157


.




Centering member


160


desirably includes a plurality of openings


162


to facilitate cooling of bottle neck


10


to hasten the solidification of molten seal material


14


therein to form seal


22


. Centering member


160


includes retaining portion


164


which limits the downward movement of centering member


160


relative to die stem


152


and prevents it from separating from die stem


152


. Inner wall


165


of centering member


160


is disposed around die


157


which is recessed from the edge of inner wall


165


to form the die cavity for making embossed seal portion


16


.




Engagement spring


166


is coupled between spring seat


150


on guide tube


130


and centering member


160


and inner cone


161


. The compression of engagement spring


166


from its rest position shown in

FIG. 8

allows centering member


160


to move upward relative to guide tube


130


and die stem


152


. The upward movement also provides tolerance in movement of centering member


160


to adapt assembly


50


to bottles


66


having slightly varying heights. As best illustrated in

FIGS. 13 through 15

, the compression of engagement spring


166


and upward movement of centering member


160


is the initial step in a process culminating in contact between die surface


159


and molten seal material


22


.




As centering member


160


is brought into contact with bottle neck


10


, die truck assembly


50


is generally aligned with the bottle neck (FIG.


13


). Further compression of engagement spring


166


causes inner cone


161


to lower itself into the cavity above cork


12


in bottle neck


10


(FIG.


14


). Lower edges


163


of inner cone


161


are angled outward so that as the inner cone is lowered into bottle neck


10


, the bottle neck becomes exactly centered below die truck assembly


50


. As illustrated in

FIG. 15

, after inner cone


161


has centered assembly


50


, die surface


159


is lowed from inside cylindrical inner cone


162


and brought into contact with molten seal material


22


.




Die stem spring


170


is coupled between spring seat


150


on guide tube


130


and blocking member


158


on die stem


152


. The compression of die stem spring


170


from its rest position as shown in

FIG. 8

permits upward movement of die stem


152


relative to guide tube


130


. This upward movement allows die stem


152


to adapt to corks


12


of slightly varying depths from the openings of necks


10


of bottles


66


so as to exert a generally consistent pressure on molten seal material


14


to form finished seal


22


regardless of cork depth.




Note that actuator spring


148


, engagement spring


166


, and die stem spring


170


may be relaxed but are typically in slight compression in the rest position shown in

FIGS. 6-8

to bias the components of die truck assembly


50


in specific positions relative to each other.




The triple telescoping action of die tuck assembly


50


is illustrated in

FIGS. 9-11

. Carrier plate


120


is attached to a pair of guide tracks


174


which are connected with drive chain


36


to travel around the path of the drive chain. In a preferred embodiment, apparatus


30


includes a pair of parallel drive chains


36


supporting the two sides of carrier plate


120


through the pair of guide tracks


174


and moving in unison to transport assemblies


50


. For the purposes of the following discussion, carrier plate


120


serves as a reference for vertical movements of the various components of assembly


50


. In

FIG. 9

the offset portion of wheel track


68


along lower path portion


40


of drive chain


36


pushes actuator spring


148


against guide block


126


. The downward movement of these components forming the actuation portion of assembly


50


causes die stem


152


and centering member


160


to move downward with guide tube


130


.




When centering member


160


meets neck


10


of bottle


66


, it is pushed upward by neck


10


and toward carrier plate


120


to compress engagement spring


166


, which maintains the engagement between centering member


160


and bottle neck


10


, as shown in FIG.


10


. The upward movement of centering member


160


relative to die stem


152


causes inner cone


161


to protrude from inside centering member


160


and for die


157


to protrude from inside inner cone


161


.




In

FIG. 11

, die stem spring


170


is compressed when die stem


152


is pushed upward by cork


12


and molten seal material


14


in bottle neck


10


. The upward movement allows die stem


152


to adapt to corks


12


of slightly varying depths from the openings of necks


10


, so as to exert a generally consistent pressure to form finished seal


22


regardless of cork depth.




After die truck assembly


50


is disengaged from bottle


66


, the biasing forces of actuator spring


148


, engagement spring


166


, and die stem spring


170


return the components of assembly


50


to the rest position shown in

FIGS. 6-8

. In an alternative embodiment, actuator spring


148


is eliminated so that die truck assembly


50


provides a double telescoping action. Instead of pushing actuator wheel


138


, bracket


136


, and guide tube


130


downward to engage assembly


50


with neck


10


of bottle


66


, bottle


66


is moved upward to meet assembly


50


. In such a system, the third telescoping action of moving guide tube


130


downward to engage with the bottle neck is not needed.




Bottle Sealing Procedure




The bottle sealing process employing apparatus


30


of

FIGS. 3-5

with die truck assembly


50


of

FIGS. 6-11

is described as follows. Referring to

FIGS. 3-5

, drive motor


80


is turned on to drive chain


36


to move die truck assemblies


50


. Assemblies


50


are transported by drive chain


36


to lower path portion


40


.




Before assemblies


50


reach lower path portion


40


, bottles


66


are fed through timing screw


76


to bottle conveyor


64


which are synchronized in movement with assemblies


50


to align necks


10


of bottles


66


with assemblies


50


. The applicator


70


is activated to introduce an amount of the molten seal material into the cavity of each bottle


66


before it is transferred to bottle conveyor


64


. When bottle


66


is aligned with die truck assembly


50


, the offset portion of wheel track


68


on upper support frame


32


pushes the components of assembly


50


except carrier plate


120


and guide block


126


downward to engage the assembly with bottle neck


10


. At this time, the seal material in bottle neck


10


is sufficiently molten to be impressed but may be cooled using cooling nozzles


62


so that it will retain the impression created by the die surface image.




The triple telescoping action provided by actuator spring


148


, engagement spring


166


, and die stem spring


170


of assembly


50


maintains the engagement between centering member


160


and bottle neck


10


along lower path portion


40


of travel of the assembly. A generally consistent pressure is exerted by the die surface


159


of assembly


50


on molten seal material to form finished seal


22


, as illustrated in

FIGS. 9-11

. The molten seal material is sufficiently cooled so that the embossed surface


20


thereon is preserved upon separation of the die surface


159


from embossed surface


20


, and the heat of the molten seal material in the bottle cavity does not cause melting of embossed surface


20


.




During the engagement of die truck assemblies


50


with bottle necks


10


, the offset portion of wheel track


68


keeps the actuation portion of each assembly in the downward position, thereby maintaining continued contact of die


157


with embossed seal portion


16


during the formation of finished seal


22


in bottle neck


10


. This minimizes disturbance of the embossed image on the seal to avoid “blocking” of the die image on die


157


with seal residue by premature movement of the die surface


159


and the embossed surface on the seal.




At the end of lower path portion


40


, wheel track


68


exits the offset portion and allows springs


148


,


166


, and


170


to raise the actuation portions of die truck assemblies


50


in a generally vertical direction to disengage them from bottles


66


, as shown in

FIGS. 3 and 5

.




The methods and apparatus of the present invention permit the sealing of corked bottles at ambient temperature. The formation of the embossed seal is initiated by injecting molten seal material into the cavity above the cork in the neck of the bottle. While contact is maintained between the die surface


159


and the top layer of the molten seal material, an image is created on the seal material. Moreover, it is possible to form a seal with a “squeeze-up” finish having a hand-made look by squeezing up the molten seal material around the edge. The amount of squeeze up can be controlled by varying the temperature and/or volume of molten seal material


14


applied in the cavity of the bottle neck.




While a preferred embodiment of the present invention has been disclosed by way of example, it is evident that modifications and adaptations of that embodiment will occur to those skilled in the art. It is to be expressly understood that such modifications and adaptations are within the spirit and scope of the present invention, as set forth in the following claims.



Claims
  • 1. An automated method of forming a seal over a cork in a necked bottle as the bottle moves along an automated bottle track using a die with an image bearing die surface contained within a seal embossing mechanism, the method comprising:providing a molten seal material which is in a molten state outside of the bottle; introducing the molten seal material in the molten state from outside the bottle into the cavity above the cork in the neck of the bottle; superimposing the image bearing surface of the seal embossing mechanism over the mouth of the bottle containing the molten seal material; centering the top of the bottle relative to the seal embossing mechanism; extending a die surface having a die image from the seal embossing mechanism into contact with the surface of the molten seal material; motivating the seal embossing mechanism along an automated seal track coincident with the movement of the bottle along the automated bottle track with an image bearing die surface in contact with the molten seal material until the molten material has cooled so that the seal impression will be retained by the sealing material; and retracting the image bearing die surface away from the surface of the cooled molten seal material.
  • 2. The method of claim 1 wherein the molten seal material comprises a molten thermoplastic material.
  • 3. The method of claim 1 wherein the seal embossing mechanism includes a centering cone, and wherein the centering step includes lowering the centering cone over the neck of a bottle so as to generally center the mouth of the bottle with the seal embossing mechanism.
  • 4. The method of claim 1 wherein the seal embossing mechanism includes a circular centering/sealing piston, and wherein the centering step includes extending the circular centering/sealing piston into the mouth of the bottle so as to fully center the mouth of the bottle below the seal embossing mechanism.
  • 5. The method of claim 4 wherein the extending step includes lowering the image bearing die surface through the circular centering/sealing piston into contact with the surface of the molten seal material in the neck of a bottle.
  • 6. The method of claim 5 wherein the retracting step includes raising the image bearing die surface away from the mouth of the bottle through the circular centering/sealing piston.
  • 7. An automated method of forming a seal over a cork in a necked bottle, the method comprising:providing a molten seal material which is in a molten state outside of the bottle; introducing the molten seal material in the molten state from outside the bottle into a cavity above the cork in the neck of the bottle; extending a die surface into contact with the surface of the molten seal material; maintaining contact with the molten seal material until the molten material has cooled; and retracting the image bearing die surface away from the surface of the cooled molten seal material.
Parent Case Info

This application is a continuation-in-part of and claims priority from U.S. patent application, Ser. No. 09/384,904, filed Aug. 27, 1999 now U.S. Pat. No. 6,205,744, and U.S. patent application, Ser. No. 09/480,917, filed Jan. 11, 2000 now U.S. Pat. No. 6,349,524, the disclosures of which are incorporated herein by reference in their entirety.

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Entry
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Continuation in Parts (2)
Number Date Country
Parent 09/480917 Jan 2000 US
Child 09/705459 US
Parent 09/384904 Aug 1999 US
Child 09/480917 US