Filler device sub-assembly and associated method

Information

  • Patent Grant
  • 6655109
  • Patent Number
    6,655,109
  • Date Filed
    Thursday, May 31, 2001
    23 years ago
  • Date Issued
    Tuesday, December 2, 2003
    21 years ago
  • CPC
  • US Classifications
    Field of Search
    • US
    • 053 281
    • 053 2845
    • 053 300
    • 053 306
    • 053 308
    • 053 310
    • 053 312
    • 053 365
    • 053 287
    • 053 346
    • 053 347
    • 053 355
    • 053 356
    • 053 357
    • 053 367
  • International Classifications
    • B65B300
    • Term Extension
      61
Abstract
A filler device sub-assembly comprising: a first cap gripping arm and a second cap gripping arm, wherein each of the first and second cap gripping arms include a second end, and wherein the second ends of the first and second cap gripping arms cooperatively define a cap retaining region; a pivot opening associated with each of the first and second cap gripping arms, wherein the first and second cap gripping arms are pivotable about the pivot opening; and means for guiding a cap into the cap retaining region, wherein the cap guiding means facilitates outward pivoting of at least one of the first and second cap gripping arms by a cap which results in directing a cap into the retaining region toward retention thereof.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates in general to a filler device sub-assembly, and more particularly, to a filler device sub-assembly, which among other things, substantially precludes air and/or other matter from undesirably entering an associated container upon and/or prior to filling of the same and/or which facilitates reliable uncapping, capping, and/or recapping of the container.




2. Background Art




Filling assemblies for use in association with filler devices have been known in the art for years and are the subject of numerous patents including: U.S. Pat. No. 5,845,683; U.S. Pat. No. 5,740,844; U.S. Pat. No. 5,690,151; U.S. Pat. No. 5,533,552; U.S. Pat. No. 5,531,253; U.S. Pat. No. 5,450,882; U.S. Pat. No. 5,402,833; U.S. Pat. No. 4,848,381; U.S. Pat. No. 4,437,498; U.S. Pat. No. 4,219,054; U.S. Pat. No. 3,774,658; U.S. Pat. No. 3,568,734; U.S. Pat. No. 3,430,639; EP Pat. No. 568,121 A1; and EP Pat. No. 554,951 A1. While the above-identified fill assemblies have become commercially available for use in association with filler devices, problems associated with precluding air and/or other undesirable matter from entering an associated container before filling as well as uncapping, capping, and/or recapping at an operatively acceptable speed remain largely problematic. In addition, problems associated with replacing a stock or common cap associated with a pre-filled and/or pre-capped container with a different, specialized cap have been identified.




It is therefore an object of the present invention to provide a reliable, filler device sub-assembly for use in association with any one of a number of filler devices, including rotary fillers, which remedies the detriments and/or complications associated with conventional filler assemblies known in the art.




These and other objects of the present invention will become apparent in light of the present specification, claims, and drawings.




SUMMARY OF THE INVENTION




The present invention is directed to a filler device sub-assembly comprising: (a) a first cap gripping arm and a second cap gripping arm, wherein each of the first and second cap gripping arms include a second end, and wherein the second ends of the first and second cap gripping arms cooperatively define a cap retaining region; (b) a pivot opening associated with each of the first and second cap gripping arms, wherein the first and second cap gripping arms are pivotable about the pivot opening; and (c) means for guiding a cap into the cap retaining region, wherein the cap guiding means facilitates outward pivoting of at least one of the first and second cap gripping arms by a cap which results in directing a cap into the retaining region toward retention thereof.




In a preferred embodiment of the present invention, the cap guiding means further includes an extending surface associated with at least one of the first and second cap gripping arms, wherein the extending surface facilitates the outward pivoting of the associated cap gripping arm upon contact by a cap. In this embodiment, each of the first and second cap gripping arms may include an extending surface.




In another preferred embodiment of the present invention, each second end of the first and second cap gripping arms is configured so that the defined retaining region substantially matches the configuration of a cap.




In yet another preferred embodiment of the present invention, the filler device sub-assembly further comprises means for biasing each of the first and second cap gripping arms toward each other. In this embodiment, the biasing means may comprise at least one spring attached to each of the first and second cap gripping arms.




In a preferred embodiment of the present invention, the filler device sub-assembly further includes means for sensing at least one of the presence or absence of a cap within the holding region. In this embodiment, the sensing means may comprise a proximity sensor.




In accordance with the present invention, the filler device sub-assembly may further comprise: (a) a first rim gripping arm and a second rim gripping arm, wherein each of the first and second rim gripping arms include a second end, and wherein the second ends of the first and second rim gripping arms cooperatively define a rim retaining region, and further wherein the first and second rim gripping arms are pivotable about the pivot opening and; (b) means for guiding a rim of a container into the rim retaining region, wherein the rim guiding means facilitates outward pivoting of at least one of the first and second rim gripping arms by a rim of a container which results in directing the rim of a container into the rim retaining region toward retention thereof.




The present invention is also directed to a filler device sub-assembly comprising: (a) a first rim gripping arm and a second rim gripping arm, wherein each of the first and second rim gripping arms include a second end, and wherein the second ends of the first and second rim gripping arms cooperatively define a rim retaining region; (b) a pivot opening associated with each of the first and second rim gripping arms, wherein the first and second rim gripping arms are pivotable about the pivot opening; and (c) means for guiding a rim of a container into the rim retaining region, wherein the rim guiding means facilitates outward pivoting of at least one of the first and second rim gripping arms by a rim of a container which results in directing the rim of a container into the retaining region toward retention thereof.




In another aspect of the invention, the invention comprises a filler device sub-assembly for filling a container with product. The container includes an inner surface, an inner volume, a rim and a cap. The sub-assembly comprises means for retaining a rim of a container, means for substantially sealing rim and means for manipulating the cap. The substantial sealing means substantially seals at least one of the product and a portion of the inner surface of the container against a rim of the container, to, in turn, substantially preclude the ingress to and egress from the volume of the container. The manipulating means manipulates the cap of the container, to in turn, remove the cap from the rim of the container, and, to re-engage the cap onto the rim of the container. The removal and re-engagement of the cap occurs when the substantial sealing means actively substantially seals the volume of the container.




The present invention is also directed to a filler device sub-assembly having a means for manipulating a cap. The cap manipulating means includes a rotation post, first and second cap gripper arms and a cam. The rotation post includes a follower attached thereto. The first and second cap gripper arms are capable of retaining the cap in a gripped orientation. The first and second cap gripper arms are pivotally associated with the rotation post. The cam is associated with the follower such that the cam actuates the follower to, in turn, impart rotation of the rotation post and associated cap gripper arms a predetermined arcuate distance upon movement of the rotation post in either of a substantially upward and substantially downward movement.




In another aspect of the invention, the cam may include an upper cam portion and a lower cam portion. The cam actuates the follower. In turn, the cam through the follower imparts rotation of the rotation post and associated cap gripper arms a predetermined arcuate distance upon movement of the rotation post in one of substantially upward and substantially downward movement. Subsequently, the cam imparts rotation of the rotation post a further predetermined arcuate distance in the same direction upon movement of the rotation post in the other of the substantially upward and substantially downward movement. As a result, continued upward and downward movement directs the rotation post through a full circular rotation.











BRIEF DESCRIPTION OF THE DRAWINGS




The invention will now be described with reference to the drawings wherein:





FIG. 1A

of the drawings is a fragmentary top view of a filler device sub-assembly in accordance with the present invention showing, in particular, the cap manipulating means;





FIG. 1B

of the drawings is a fragmentary top view of a filler device sub-assembly in accordance with the present invention showing, in particular, the rim retaining means;





FIG. 2

of the drawings is a fragmentary side elevational view of a filler device sub-assembly in accordance with the present invention taken partially along line A—A and partially along line B—B of

FIG. 1B

;





FIG. 3

of the drawings is a fragmentary side elevational view of a filler device sub-assembly in accordance with the present invention taken along line A—A of

FIG. 1B

;





FIG. 4

of the drawings is a fragmentary side elevational view of a filler device sub-assembly in accordance with the present invention taken along line A—A of

FIG. 1B

showing, among other things, an upper end thereof;





FIG. 5

of the drawings is a perspective view of a filler device sub-assembly in accordance with the present invention;





FIG. 6

of the drawings is a fragmentary side elevational view of an embodiment of a cap manipulation means in accordance with the present invention;





FIG. 7

of the drawings is a perspective view of an embodiment of a cap manipulation means in accordance with the present invention;





FIG. 8

of the drawings is a side elevational view of a filler device in accordance with the present invention; and





FIG. 9

of the drawings is a fragmentary top view of a filler device in accordance with the present invention.











DETAILED DESCRIPTION OF THE INVENTION




While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and described herein in detail several specific embodiments with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the invention to the embodiments illustrated.




It will be understood that like or analogous elements and/or components, referred to herein, are identified throughout the drawings by like reference characters.




Referring now to the drawings and collectively to

FIGS. 1A-4

in particular, schematic representations of a filler device sub-assembly


10


are shown, which generally comprises housing


11


, means


12


for retaining a rim of a container, means


14


for manipulating a cap of a container, means


16


for substantially sealing a portion of a container against a rim of a container, means


18


for ejecting a rim of a container, and means


19


for sensing the presence or absence of at least one of a cap or a rim of a container. It will be understood that

FIGS. 1-9

are merely schematic representations of a filler device sub-assembly. As such, some of the components have been distorted from their actual scale for pictorial clarity.




Referring now to

FIGS. 8 and 9

, filler device sub-assembly


10


is primarily intended for use in association with filler device


200


, which is capable of filling associated containers and/or bags with any one of a number of materials (i.e. product) in solid, liquid, and/or gaseous states.




Housing


11


is shown in

FIGS. 1A-4

collectively as comprising base


22


, upper plate


24


, and riser posts


26


,


28


,


30


, and


32


. As will be understood, housing


11


provides a structure for the attachment and operation of the remainder of the filler device sub-assembly components. For example, base


22


includes opening


34


and upper plate


24


includes opening


36


for receiving and retaining cap manipulating means


14


and rim retaining means


12


. Similarly, and as will be explained in greater detail herein, riser posts


30


and


32


provide a shaft upon which substantial sealing means


16


is linearly slidable. Housing


11


generally comprises a stainless steel material which is resistant to corrosion. Of course, other materials, such as aluminum and nonmetals are likewise contemplated for use. Indeed, the housing is not limited to any particular material, and various materials may be utilized depending on the particular application.




Rim retaining means


12


is shown in FIGS.


1


B and


3


-


5


collectively as comprising first gripper arm


40


, second gripper arm


42


, pivot axle


41


, means


43


for biasing the first gripper arm and the second gripper arm toward each other, and means


45


for guiding the rim into a desired gripped orientation. As is shown in

FIG. 1B

, first gripper arm


40


includes first end


44


, second end


46


and pivot opening


48


. Similarly, second gripper arm


42


includes first end


50


, second end


52


and pivot opening


54


. The two gripper arms combine to define rim retaining region


49


, which accommodates and retains the rim of a particular container. The gripper arms are pivotally associated with pivot axle


41


which is fixed to opening


36


of upper plate


24


of housing


11


. The pivot openings of the gripper arms are positioned about pivot axle


41


so that the gripper arms can pivot thereabout. In a grasping position, the first ends


44


,


50


are in abutment and in contact with a stop, such as stop


150


(

FIGS. 3 and 4

) and the second ends are substantially in abutment. In the extended position, the first ends are away from the stop, and the second ends are separated so as to be ready to receive a rim.




Gripper arm biasing means


43


is shown in

FIGS. 3 and 4

as comprising extension springs


56


,


58


which are releasably attached to each of the gripper arms. In a steady state condition, the springs are extended, and, in turn, biased such that the second ends of the gripper arms are forced toward and into contact with each other. An external force is required to overcome springs


56


,


58


, to, in turn, separate the ends of the gripper arms


40


,


42


from each other. In other embodiments, the retaining means may comprise compression springs which operate individually on each of the gripper arms. Of course other retaining means, such as gripper arms which utilize a hydraulic force or a pneumatic force to retain a rim are likewise contemplated for use.




Referring now to

FIGS. 1B and 5

, rim guiding means


45


comprises rim extending surfaces


53


,


53


′ which are associated with second ends


46


,


52


of the respective first and second gripper arms. The rim extending surfaces are positioned such that upon outside contact, by, for example, a rim of a container, the gripper arms are pivoted away from each other. In addition, the rim extending surfaces are angled toward the rim retaining region such that upon outside contact, by a rim of a container, the rim extending surfaces (that are in contact with the rim) guide the rim toward and into rim retaining region


49


. Preferably, the rim extending surfaces are angled toward the rim retaining region at an angle of about 15 to about 75 degrees. To achieve cooperative operation, the two cap extending surfaces are angled at substantially identical angles.




Cap manipulating means


14


is shown in

FIGS. 1A

,


3


, and


5


collectively, as comprising first cap gripper arm


60


, second cap gripper arm


62


, means


63


for biasing the cap gripper arms toward each other, means


65


for guiding the cap into a gripped orientation, cam


64


, rotation post


66


and lifter shaft


68


. It will be understood that cap manipulating means


14


removes the cap from the container and directs the cap away from the container so that it may be filled. Subsequently, the cap manipulating means returns the cap to the container so that the container can be resealed.




Specifically, as is shown together in

FIG. 1A

, first cap gripper arm


60


includes first end


70


, second end


73


and pivot opening


74


. Similarly, second cap gripper arm


62


includes first end


77


, second end


79


and pivot opening


80


. As with the gripper arms


40


,


42


of rim retaining means


12


, cap gripper arms


60


,


62


likewise define cap gripping region


69


(

FIGS. 1A

,


5


) which is configured to accept and retain caps of a particular configuration.




The cap gripper arms


60


,


62


are arranged so that the pivot openings


74


,


80


are positioned to pivot about the axis of rotation post


66


, from a grasping position to a released position. In a grasping position, the first ends are in abutment and in contact with a stop, such as stop


151


, and the second ends are substantially in abutment. In the extended position, the first ends are away from the stop and the second ends are separated so as to be ready to receive a cap. Specifically, as is shown in

FIGS. 1A

,


4


and


5


, similar to the gripper arms


40


,


42


, biasing means


63


forces cap gripper arms


60


,


62


into a retaining position. Specifically, biasing means


63


includes extension springs


84


,


86


which are releasably attached to each of the cap gripper arms to bias them toward each other. External force is required to overcome the springs so as to separate the ends of the cap gripper arms away from each other.




Cap guiding means


65


is shown in

FIGS. 1A and 5

as comprising cap extending surfaces


71


,


71


′ associated with the respective second ends of the cap gripper arms. As with the rim retaining means, the cap extending surfaces are configured so that contact by, for example, a cap of a container, directs the cap gripper arm (in contact with the cap of a container) in an outward direction and simultaneously guides the cap toward cap gripping region


69


. To achieve this guiding of the cap, the cap extending surfaces are angled at an angle of about 15 to about 75 degrees. To achieve substantially cooperative operation, the two cap extending surfaces are angled at substantially identical angles and at angles substantially identical to the rim extending surfaces


53


,


53


′.




Rotation post


66


is shown in

FIG. 3

as comprising first end


88


, second end


90


and follower


82


. Gripper arms


60


,


62


are attached to first end


88


of rotation post


66


, and follower


82


is attached to second end


90


of rotation post


66


. Lifter shaft


68


includes first end


94


, second end


96


and lifter surface


98


. First end


94


of lifter shaft


68


is rotatably coupled to rotation post


66


by way of coupling


67


. Lifter surface


98


includes roller member


99


which is coupled to second end


96


of lifter shaft


68


.




Cam


64


is shown in

FIG. 3

as comprising proximal end


102


, distal end


104


and cam surface


72


(see also, FIG.


5


). Proximal end


102


of cam


64


is attached to base


22


of housing


11


. Cam


64


comprises a substantially cylindrical member. Rotation post


66


, lifter shaft


68


and cam


64


are positioned such that they have a corresponding longitudinal axis. Cam surface


72


includes a configuration which facilitates the receipt and travel of follower


82


thereon from a lowest position to a highest position. In a lowest position, cap gripper arms


60


,


62


are proximate upper plate


24


of housing


11


. In a highest position, cap gripper arms


60


,


62


are directed away from the upper plate.




As will be explained, cam surface


72


is configured so that each upward travel of lifter shaft


68


will yield a 90 degree rotation (or a rotation sufficient to allow free access to the rim by the fill valve of filler device


200


) of rotation post


66


, and each downward travel will return the rotation post 90 degrees (or other predetermined angle) to the original orientation. Of course other configurations are likewise contemplated which achieve different degrees of rotation.




As is shown in

FIGS. 2 and 5

collectively, substantial sealing means


16


includes pad housing


108


and linear movement means


110


. It will be understood that the substantially sealing means substantially seals the volume within the interior of the container from the outside of the rim of the container prior to and after filling to preclude contamination of the container as the cap is removed and replaced. Pad housing


108


includes fill pad


112


and slidable housing


114


. Slidable housing


114


is slidably positioned on risers


30


,


32


of housing


11


. Linear bearings or the like may be utilized to facilitate the controlled low-friction movement of the slidable housing about risers


30


,


32


.




Linear movement means


110


, is shown in

FIGS. 2 and 5

as comprising, force means


116


for upwardly directing pad housing


108


and means for downwardly directing pad housing


108


which direct slidable housing


114


between from a first position proximate base


22


of housing


11


and a second position proximate upper plate


24


of housing


11


. Upward moving means


116


may comprise a cam actuated by the rotative movement of the sub-assembly relative to the remainder of filler device


200


(FIG.


8


), a pneumatic device, hydraulic device or electric device which is capable of overcoming return springs


118


,


120


(

FIG. 5

) and to direct slidable housing


114


toward upper plate


24


of housing


11


. Return springs


118


,


120


(

FIG. 5

) return the slidable housing toward and preferably into contact with base


22


of housing


11


. Of course, other assemblies which return pad housing


108


from upper plate


24


to base


22


, including fully pneumatic, hydraulic or electric systems are contemplated for use.




Rim ejecting means


18


is shown in

FIGS. 1A and 1B

as comprising lever member


132


, rotation pivot


134


and means


136


for rotating the lever member about the rotation pivot. Lever member


132


includes bar


140


and arm


142


. Lever member


132


is configured so that, upon rotation about the rotation pivot, arm


142


is directed across second ends


46


,


52


of the gripper arms of rim retaining means


12


, to, in turn, dislodge and release a container retained by gripper arms


40


,


42


— as well as an associated cap. Rotating means


136


comprises a cam (not shown) which actuates, to, in turn, rotate the lever member about the rotation pivot. Various means for rotating the lever member are contemplated for use, including, but not limited to, pneumatic, hydraulic, electrical, or mechanical power.




Sensing means


19


is shown in

FIGS. 3 and 4

as comprising at least one sensor positioned upon at least one of the rim retaining means and the cap gripping means. In one embodiment, the at least one sensor comprises a proximity type sensor associated with the cap gripping means and/or the rim retaining means. As such, the sensor facilitates the determination as to the presence or absence of a cap or a rim. Such a system can be alerted to a fault condition, and, in turn, the filling operation can be stopped in the event that a container rim or a cap is not present. Of course, other sensors, such as micro-switches, and/or optical sensors are contemplated for use in accordance with the present invention. While various configurations are contemplated, such sensors may be positioned on one or both of the rim gripping arms and/or the cap gripping arms.




In operation, and as is shown in

FIGS. 8 and 9

, filler device sub-assembly


10


is associated with rotatable filler device


200


. Rotatable filler device


200


includes such assemblies


10


for each of the ten separate fill stations on rotating carousel


210


.




To prepare the assembly for receipt of a container, pad housing


108


of substantial sealing means


16


is placed in a first position wherein slidable housing


114


is positioned away from upper plate


24


and preferably proximate base


22


of housing


11


. Similarly, follower


82


is positioned relative to cam surface


72


so as to be in its lowest position. In such a position, cap gripper arms


60


,


62


are proximate upper plate


24


and substantially aligned with the rim gripper arms.




Once properly configured, a container is supplied via container feed


220


(FIGS.


8


and


9


). As the container contacts first and second gripper arms


40


,


42


of rim retaining means


12


, and first and second cap gripper arms


60


,


62


of cap manipulating means


14


, the container rim contacts rim extending surfaces


53


,


53


′ and the cap contacts cap extending surfaces


71


,


71


′. As the container (rim and cap) continue to move, the movement overcomes respective biasing means


43


and


63


and spreads the respective second ends of the gripper arms apart as the rim extending surfaces


53


,


53


′ and the cap extending surfaces


71


,


71


′ center the rim and cap, and, in turn, direct same into the respective retaining regions


49


,


69


. Once the cap and rim are received by the respective receiving regions


49


,


69


defined by the second ends of the gripper arms, the biasing means direct the gripper arms toward each other so as to grasp and retain the rim and cap in a desired engaged position.




After the rim is retained by first and second rim gripper arms


40


,


42


, and after the cap is retained by first and second cap gripper arms


60


,


62


, substantially sealing means


16


maybe activated (Of course, in certain embodiments, the substantial sealing means may be modified and/or omitted from the process entirely). In turn, linear moving means


110


is powered to move pad housing


108


. Specifically, upward moving means


116


of linear moving means


110


overcomes springs


118


,


120


, and moves slidable housing


114


associated with pad housing


108


toward upper plate


24


of housing


11


. As the slidable housing


114


approaches upper plate


24


, fill pad


112


engages the lower surface of the container, which, in turn, engages a lower surface of the rim of the container. However, in certain instances it may be positioned such that the product within the container is displaced by the pad such that the product engages the lower surface of the rim of the container. As the slidable housing is forced upward, the lower surface of the container (or product within the container) becomes engaged with the lower surface of the rim and the volume defined by the container is substantially sealed and/or substantially isolated.




Once a substantial seal is created with the rim, lifter shaft


68


of cap manipulating means


14


is activated by a vertical movement means, which directs the lifter shaft in an upward direction. Upward movement of the lifter shaft directs cap gripper arms


60


,


62


which include the cap within cap gripping region


69


in an upward direction, thereby removing the cap from the rim. Inasmuch as the movement of follower


82


mounted proximate second end


90


of rotation post


66


is controlled by cam surface


72


, as the rotation post moves in an upward direction by the lifter shaft, cam surface


72


imparts rotation to rotation post


66


, thereby providing a rotative movement means. As was explained above, the upward stroke of the lifter shaft imparts a 90 degree (or other angular) rotation of rotation post


66


, and, in turn, the attached cap, away from the rim of the container. Of course, it is contemplated that the cam surface can be configured in various configurations to import varying degrees of rotation.




As or after the rotation post, gripper arms, and cap rotate away from the rim of the container, the fill valve is freely moved into position proximate the rim of the container. Once the fill valve is positioned and once it engages the rim, slidable housing


114


is moved away from upper plate


24


, toward base


22


of housing


11


. At such time, the lower surface of the container (or the product) disengages from the rim thereby placing the volume defined by the container in fluid communication with fill valve. Subsequently, the fill valve is actuated, and the container is filled.




After the container is filled with product as desired, slidable housing


114


may be forced upward by upward moving means


116


until it again substantially seals the lower surface of the container relative to the lower rim of the container or product, to substantially isolate the fill valve from the volume defined by the container. Next, the fill valve is disengaged, and the cap manipulating means cycle is completed by a final downward stroke of the lifter shaft, which causes the cam surface to move follower


82


and rotate rotation post


66


, and cap gripper arms


60


,


62




90


in the opposite direction so that the cap again aligns with the rim and re-engages the rim of the container upon completion of the downward stroke. Once the cap reseals the container, upward moving means


116


is disengaged, and springs


118


,


120


return slidable housing


114


toward base


22


of housing


11


.




Next, the container is removed from the fill assembly by way of rim ejecting means


18


. Specifically, rotating means


136


directs the rotation of lever member


132


about rotation pivot


134


. As lever member


132


rotates, arm


142


pushes against the rim of the container. In turn, the force of the arm against the container overcomes biasing means


43


of rim retaining means


12


and biasing means


63


of cap manipulating means


14


thereby separating first and second gripper arms


40


,


42


, and first and second cap gripper arms


60


,


62


. Once these are separated, the continued rotation of the lever member expels the rim and the cap from the gripper arms. Once disengaged, the container can be removed from the rotating fill device. The lever member is returned to its original position, and the assembly is again ready to accept another container. The cycle is now ready to be repeated.




In a second embodiment of the invention, a filler device sub-assembly is provided which facilitates the filling of a container and the exchange of the cap of the container during filling. As such, a first cap (present on the container prior to filling) can be removed and, the container can be capped with a second cap upon completion of the filling process.




It will be understood that the cap manipulating means, housing rim retaining means, substantial sealing means, ejecting means and sensing means are contemplated to be substantially identical, or at least analogous in structure and/or function, to those identified with respect to the first embodiment.




In this second embodiment, the cap gripper arms (not shown) are mounted on rotating plate


110


. The particular operation of the gripping arms is substantially the same as in the first embodiment with the exception that gripper arms may be centered upon a pivot axis which does not correspond to the pivot axis of the rotation post.




In the second embodiment, the cap manipulating means


14


includes cam


164


in place of cam


64


and means


169


for lock-step rotation of rotation post


66


relative to lifter shaft


68


.




In particular, as shown in

FIGS. 6 and 7

, cam


164


comprises lower cam portion


166


and upper cam portion


168


. The lower cam portion and upper cam portion are spaced apart a predetermined distance sufficient to permit movement of follower


82


therebetween. Lower cam portion


166


includes cam surface


172


and upper cam portion


168


includes cam surface


172


′. As will be explained, the positioning and spacing of the lower and upper cam portions, follower


82


is capable of traveling the full 360 degrees of cam


164


.




Lock step rotation means


169


, as shown in

FIG. 6

, comprises a lower series of magnets


180


associated with lifter shaft


68


and an upper series of magnets


182


associate with rotation post


66


. The lower series of magnets are positioned circumferentially around the lifter shaft in order of alternating polarity. Similarly, the upper series of magnets are positioned circumferentially around the rotation post in order of alternating polarity.




The upper and lower series of magnets are positioned in close proximity such that the magnetic fields overlap and interact. In particular, if one magnet of the upper series of magnets overlays a magnet of the lower series of magnets of the same polarity, the magnets will repel causing rotation post


66


to rotate into a position wherein interacting magnets of the upper and lower series of magnets are opposite in polarity. In such an orientation, the two series of magnets serve to lock the rotation post and the lifter shaft together until the magnetic force is overcome.




In operation of this embodiment, after the cap and rim are retained and the substantial seal is created between the rim and the lower surface of the container (as described with respect to the first embodiment), the cap manipulating means is activated and directs the lifter shaft in an upward direction. The upward movement first directs the gripper arms away from the rim, thereby removing the cap from the rim.




The continued upward movement directs follower


82


into the cam surfaces


172


,


172


′. Specifically, the follower


82


contacts upper cam surface


172


′ which overcomes the magnetic force of the lock step means and impacts rotation of the rotation post relative to the lifter shaft. As the cam begins to return downward, the lock step means directs further rotation of the rotation post relative to the lifter shaft until an orientation which pairs magnets of opposing polarity is achieved.




At such time, the lifter shaft has returned to its lowest position and the cycle is repeated. In the embodiment shown in

FIGS. 6 and 7

collectively, the upper and lower cam portions and the magnets of the upper and lower series of magnets


180


and


182


, respectively, are configured such that each complete upward and downward movement of the lifter shaft corresponding to 120 degrees of rotation of the rotation post. In particular, the upward stroke overcomes magnetic force and rotates the lifter shaft 60 degrees. Similarly, the downward stoke overcomes magnetic force and rotates the lifter shaft another 60 degrees in the same direction. The magnets serve to urge the lifter shaft into the desired orientation during rotation and to retain the lifter shaft in the desired orientation at the conclusion of each downward stroke.




In such an embodiment, an additional apparatus (not shown) may be incorporated to remove the cap from the respective gripper arms and to replace a second cap into the gripper arms, as it is directed about a complete revolution. In turn, a conventional cap from the container can be removed by the cap manipulating means during one cycle, ejected into a cap collecting container and replaced by a stylized cap in a second cycle, and finally replaced on the container during the third cycle.




The foregoing description merely explains and illustrates the invention and the invention is not limited thereto except insofar as the appended claims are so limited, as those skilled in the art who have the disclosure before them will be able to make modifications without departing from the scope of the invention.



Claims
  • 1. A filler device sub-assembly, comprising:a first cap gripping arm and a second cap gripping arm, wherein each of the first and second cap gripping arms include a second end, and wherein the second ends of the first and second cap gripping arms cooperatively define a cap retaining region; a pivot opening associated with each of the first and second cap gripping arms, wherein the first and second cap gripping arms are pivotable about the pivot opening; and means for guiding a cap into the cap retaining region, wherein the cap guiding means facilitates outward pivoting of at least one of the first and second cap gripping arms by a cap which results in directing a cap into the retaining region toward retention thereof; and a first rim gripping arm and a second rim gripping arm, wherein each of the first and second rim gripping arms include a second end, and wherein the second ends of the first and second rim gripping arms cooperatively define a rim retaining region, and further wherein the first and second rim gripping arms are pivotable about the pivot opening and; means for guiding a rim of a container into the rim retaining region, wherein the rim guiding means facilitates outward pivoting of at least one of the first and second rim gripping arms by a rim which results in directing a rim of a container into the rim retaining region toward retention thereof, wherein the pivot opening of the first and second cap gripping arms and the pivot opening of the rim gripping arms are substantially coaxial and wherein the cap retaining region and the rim retaining region are substantially coaxial.
  • 2. The filler device sub-assembly according to claim 1, wherein the cap guiding means further includes an extending surface associated with at least one of the first and second cap gripping arms, wherein the extending surface facilitates the outward pivoting of the associated cap gripping arm upon contact by a cap.
  • 3. The filler device sub-assembly according to claim 2, wherein each of the first and second cap gripping arms includes an extending surface.
  • 4. The filler device sub-assembly according to claim 1, further comprising means for biasing each of the first and second cap gripping arms toward each other.
  • 5. The filler device sub-assembly according to claim 4, wherein the biasing means comprises at least one spring attached to each of the first and second cap gripping arms.
  • 6. The filler device sub-assembly according to claim 1, further including means for sensing at least one of the presence and/or absence of a cap within the holding region.
  • 7. The filler device sub-assembly according to claim 6, wherein the sensing means comprises a proximity sensor.
  • 8. The filler device sub-assembly according to claim 1, wherein each second end of the first and second cap gripping arms is configured so that the defined retaining region substantially matches the configuration of a cap.
  • 9. A filler device sub-assembly, having a means for manipulating a cap, comprising:a rotation post having a follower attached thereto; a first and second cap gripper arm capable of retaining a cap in a gripped orientation, the first and second cap gripper arms being pivotally associated with the rotation post; and a cam associated with the follower; wherein the cam actuates the follower to, in turn, impart rotation of the rotation post and associated cap gripper a predetermined arcuate distance upon movement of the rotation post in either of a substantially upward and substantially downward movement.
  • 10. A filler device sub assembly, having a means for manipulating a cap, comprising:a rotation post having a follower attached thereto; a first and second cap gripper arm capable of retaining a cap in a gripped orientation, the first and second cap gripper arms being pivotally associated with the rotation post; and a cam associated with the follower, the cam including an upper cam portion and a lower cam portion; wherein the cam actuates the follower to, in turn, impart rotation of the rotation post and associated cap gripper arms a predetermined arcuate distance upon movement of the rotation post in one of substantially upward and substantially downward movement and a further predetermined arcuate distance in the same direction upon movement of the rotation post in the other of a substantially upward and substantially downward movement, such that continued actuation directs the rotation post through a full rotation.
CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No. 60/208,185 filed May 31, 2000, which is hereby incorporated by reference in its entirety.

US Referenced Citations (8)
Number Name Date Kind
4378665 Crankshaw et al. Apr 1983 A
4498508 Scholle et al. Feb 1985 A
4765119 Aidlin et al. Aug 1988 A
5402623 Ahlers Apr 1995 A
5711411 Zurweller Jan 1998 A
5844677 Dimmick et al. Dec 1998 A
6302172 De Villele Oct 2001 B1
6399901 Nishino et al. Jun 2002 B1
Provisional Applications (1)
Number Date Country
60/208185 May 2000 US