Improved anvil and spigot arrangement for cap applicator unit

Abstract

Apparatus (10) is for use in a cap applicator unit (12). The apparatus (10) comprises a spigot (14) comprising an elongate body (16) and a head (18) connected to one end of the elongate body (16), and an anvil (20) provided with a hole (22) therein, the elongate body (16) of the spigot (14) mounted in the hole (22) of the anvil (20). The size of the hole (22) of the anvil (20) is sufficiently greater than the size of the elongate body (16) of the spigot (14) to permit angular movement of the spigot (14) relative to the anvil (20). The apparatus (10) further comprises at least one tensioning device (24) and (36) arranged to provide a force tensioning the spigot (14) against the anvil (20).

Claims

1. Apparatus (10) for use in a cap applicator unit (12), the apparatus (10) comprising: a spigot (14) comprising an elongate body (16) and a head (18) connected to one end of the elongate body (16), and an anvil (20) provided with a hole (22) therein, the elongate body (16) of the spigot (14) mounted in the hole (22) of the anvil (20), wherein the size of the hole (22) of the anvil (20) is sufficiently greater than the size of the elongate body (16) of the spigot (14) to permit angular movement of the spigot (14) relative to the anvil (20) and the apparatus (10) further comprises at least one tensioning device (24, 36) arranged to provide a force tensioning the spigot (14) against the anvil (20).

2. Apparatus according to claim 1, wherein the anvil (20) is further provided with a cavity (26) connected to and in longitudinal alignment with the hole (22) in the anvil (20), the cavity (26) containing the tensioning device (24).

3. Apparatus according to claim 1 or 2, and further comprising a locking ring (28) mounted on the elongate body (16) of the spigot (14) at the opposite end of the elongate body (16) to the head (18) of the spigot (14), wherein the at least one tensioning device (24) is arranged to provide its tensioning force through the locking ring (28).

4. Apparatus according to claim 1, 2 or 3, and further comprising a two-part spherical bearing (30) provided with a hole (32) therein, the elongate body (16) of the spigot (14) mounted in the hole (32) of the two-part spherical bearing (30) and the two-part spherical bearing (30) engaging the anvil (20) on one side and the head (18) of the spigot (14) on the other side.

5. Apparatus according to any preceding claim, wherein the spigot (14) is of two part construction, with the elongate body (16) of the spigot (14) connected to the head (18) of the spigot by a central screw (34).

6. Apparatus according to any preceding claim, wherein the tensioning device comprises either a spring (24) or a compressible cylinder.

7. Apparatus according to any preceding claim, wherein the tensioning device in the form of a sealing device comprises one of a compressible O-ring (36), a quad-ring or a compressible cylinder.

8. Apparatus according to any preceding claim, and further comprising a second tensioning device (24, 36) arranged to provide a force tensioning the spigot (14) against the anvil (20).

9. A method of operating apparatus (10) for use in a cap applicator unit (12), the apparatus (10) comprising a spigot (14) comprising an elongate body (16) and a head (18) connected to one end of the elongate body (16), and an anvil (20) provided with a hole (22) therein, the elongate body (16) of the spigot (14) mounted in the hole (22) of the anvil (20), wherein the size of the hole (22) of the anvil (20) is sufficiently greater than the size of the elongate body (16) of the spigot (14) to permit angular movement of the spigot (14) relative to the anvil (20) and the apparatus (10) further comprises at least one tensioning device (24, 36) arranged to provide a force tensioning the spigot (14) against the anvil (20), the method comprising: locating a screw cap arrangement (40) adjacent to a partially formed container (42), locating the anvil (20) adjacent to the screw cap arrangement (40), and applying pressure from a horn (46) onto the screw cap arrangement (40) and the partially formed container (42) to seal the screw cap arrangement (40) to the partially formed container (42), whereby the spigot (14) moves angularly relative to the anvil (20) so that the head (18) of the spigot (14) is in alignment with the horn (46).

10. A method according to claim 9, and further comprising mounting the screw cap arrangement (40) on the head (18) of the spigot (14) and moving the anvil (20) relative to the partially formed container (42) to locate the screw cap arrangement (40) through a hole (44) in the partially formed container (42).

Description

[0014] Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

[0015] FIG. 1 is a perspective view of a cap applicator unit,

[0016] FIG. 2 is a side view of the cap applicator unit,

[0017] FIG. 3 is an exploded side view of components of apparatus for use in the unit of FIGS. 1 and 2,

[0018] FIGS. 4a and 4b are cross-sections through the apparatus of FIG. 3,

[0019] FIG. 5 is an exploded side view of a second embodiment of components of apparatus for use in the unit of FIGS. 1 and 2, and

[0020] FIGS. 6a and 6b are cross-sections through the apparatus of FIG. 5.

[0021] FIGS. 7 to 13 show further embodiments of the apparatus.

[0022] FIG. 1 shows apparatus 10 for use in a cap applicator unit 12. The purpose of the unit 12 is to apply a screw cap arrangement 40 to a partially formed container 42, through a hole 44 in the partially formed container 42 (from the inside). The unit 12 shown in FIG. 1 is a double indexing machine, which means that two partially formed containers 42 are fitted with the screw cap arrangements 40 at the same time. The main components of the unit 12 are an anvil 20 which carries four spigots 14 and an ultrasonic horn 46, which welds the screw cap arrangements 40 to the partially formed containers 42. The unit 12 in this preferred embodiment has four spigots 14 and is double indexing, but other arrangements are possible, for example with one, two or eight spigots 14 and being single indexing rather than double indexing.

[0023] Two screw cap arrangements 40 are loaded onto two of the four spigots 14, which are then rotated and/or lowered into the two waiting partially formed containers 42. The anvil 20 moves forward to locate the screw cap arrangements 40 in the holes 44 in the partially formed containers 42, with a flange of the screw cap arrangements 40 remaining inside the partially formed containers 42. The ultrasonic horn 46 is then brought into contact with the screw cap arrangements 40 and the partially formed containers 42 and pressure is applied on both sides by the anvil 20 and the horn 46 in order to complete the sealing process using pressure in addition to the ultrasound.

[0024] Once the sealing has been completed, the horn 46 is withdrawn, as is the anvil 20 which is then raised and/or rotated to exit the interior of the partially formed containers 42 which are then moved away to another station in a larger form-fill-seal machine. The entire process of fitting the screw cap arrangements 40 to the partially formed containers 42 takes under a second. This process continues continually with two new screw cap arrangements 40 being loaded onto the unused spigots 14 of the anvil 20 and then brought into position inside the partially formed containers 42 and sealed into position by the ultrasonic horn 46 with pressure from the horn 46 and the anvil 20.

[0025] FIG. 2 shows a side view of the cap applicator unit 12. The anvil 20 has been rotated and/or lowered into the top of the partially formed containers 42 and moved forwards so that the screw cap arrangements 40 are located within the holes 44 of the partially formed containers 42. The horn 46 is ready to move forward and perform the ultrasonic welding while pressure is applied (usually by the horn 46 alone). In order to achieve the best possible seal, the distance between the anvil 20 and the horn 46 has to be adjusted, the contact pressure has to be optimised (which is usually in the range of 1000 to 2000 N) and the anvil 20 and the horn 46 have to be in alignment.

[0026] As can be seen from this Figure, the continual application of pressure by the horn 46 onto the anvil 20 will put enormous strain on the arm of the anvil 20. The operation of the components will result in pressure being applied, for example for half a second in every second. Over time this will tend to lead very slightly to deformation of the anvil 20 and this will increase the risk that the anvil 20 and the horn 46 are not in parallel alignment when they are brought together. If the alignment between these parts is not correct, the possibility of unreliable seal of the screw cap arrangements 40 to the partially formed container 42 is possible, which is extremely undesirable.

[0027] FIG. 3 shows more detail of the components that make up the anvil 20 and spigot 14. The apparatus 10 comprises the spigot 14 which has an elongate body 16 and a head 18 connected to one end of the elongate body 16, and the anvil 20 which is provided with a hole 22 therein, where the elongate body 16 of the spigot 14 is mounted in the hole 22 of the anvil 20 when the apparatus 10 is in use. The apparatus 10 also further comprises a tensioning device 24 (in the preferred embodiment this is a spring) which in use is arranged to provide a force tensioning the spigot 14 against the anvil 20.

[0028] In use, a locking ring 28 is mounted on the elongate body 16 of the spigot 14 at the opposite end of the elongate body 16 to the head 18 of the spigot 14, with the tensioning device 24 is arranged to provide its tensioning force through the locking ring 28. A screw 34 holds the locking ring 28 in place. The apparatus 10 also comprises a two-part spherical bearing 30 provided with a hole 32 therein, where in use, the elongate body 16 of the spigot 14 mounted in the hole 32 of the two-part spherical bearing 30 and the two-part spherical bearing 30 engages the anvil 20 on one side and the head 18 of the spigot 14 on the other side. A compressible O-ring 36 is provided that is located between the spherical bearing 30 and the anvil 20.

[0029] The apparatus 10 is configured so that the size of the hole 22 of the anvil 20 is sufficiently greater than the size of the elongate body 16 of the spigot 14 to permit angular movement of the spigot 14 relative to the anvil 20. The anvil 20 and spigot 14 arrangement provide automatic correction of any misalignment between the anvil 20 and the horn 46 since the hole 22 in the anvil 20 through which the spigot 14 is located is sufficiently greater in size than the elongate body 16 of the spigot 14, which therefore permits angular movement of the spigot 14 relative to the anvil 20. The permitted angular movement may be very small, for example only up to 2 degrees, but this range of movement is sufficient to provide the necessary level of correction needed to compensate for any misalignment.

[0030] A cross-section through the apparatus 10 in use is shown in FIGS. 4a and 4b. As can be seen in FIGS. 4a and 4b, the anvil 20 is further provided with a cavity 26 connected to and in longitudinal alignment with the hole 22 in the anvil 20, the cavity 26 containing the tensioning device 24 (the spring 24). The screw 34 engages with an internal thread within the body 16 of the spigot 14. Turning the screw 34 forces the locking ring 28 into contact with the spring 24 and as the screw 34 is tightened the spring 24 is compressed and thereby provides the tensioning force between the spigot 14 and the anvil 20.

[0031] FIG. 4a shows the apparatus 10 in its normal position, with the spigot 14 in alignment with the anvil 20. This provides an excellent working sealing position with respect to the horn 46, if the horn 46 and anvil 20 are in correct alignment, with their respective faces in parallel. However, should there be any deviation in the alignment between the anvil 20 and the horn 46, then the structure of the apparatus 10 is able to self-correct for this lack of alignment. This correction is delivered by the ability of the spigot 14 to be able to move angularly with respect to the anvil 20, which is shown in FIG. 4b, in the maximum movement possible (which is only a 2 degrees movement).

[0032] If there is any misalignment between the horn 46 and the anvil 20, then as these two components of the cap applicator unit 12 are brought together, the effect of the large pressure being exerted on these components causes the spigot 14 to move inside the anvil 20, thereby bringing the head 18 of the spigot 14 into alignment with the horn 46, even if the anvil 20 is out of alignment. The floating spigot 14 is able to compensate for small errors in the alignment between the anvil 20 and the horn 46. The force generated between the anvil 20 and the horn 46 overcomes the tension provided by the spring 24 and this allows the spigot 14 to move inside the anvil 20.

[0033] FIG. 5 shows a second embodiment of the apparatus 10. This embodiment is very similar to that of the first embodiment and has the same main components, being the anvil 20, the spigot 14 located in a hole 22 in the anvil 20 and a tensioning device 24 (a spring 24) which creates a tension force between the spigot 14 and the anvil 20. The spigot 14 is of two part construction, with the elongate body 16 of the spigot 14 connected to the head 18 of the spigot by the central screw 34. The spring 14 is located forward of the hole 22 within the anvil 20, whereas in the first embodiment, the spring 14 is located behind the hole 22.

[0034] Cross-sections through the second embodiment of the apparatus 10 are shown in FIG. 6. As before, FIG. 6a shows the apparatus 10 in its normal working condition, assuming that there is no misalignment between the anvil 20 and the horn 46. FIG. 6b shows the maximum movement of the spigot 14 within the anvil 20, which will be caused by any misalignment between the anvil 20 and horn 46 once these two components are brought together. The pressure created as the sealing takes place causes the spigot 14 to move angularly within the anvil 20, thereby correcting any misalignment between the anvil 20 and the horn 46.

[0035] The self-aligning spigot 14 is able to compensate for different angular errors. In use the spigot 14 and the horn 46 will be parallel. Angle errors are compensated and a self-aligning floating spigot 14 adapts automatically to the existing geometry of the components of the unit 12. The set-up time of the unit 12 is reduced and no mistakes will occur in the set-up, since the self-correction will always mitigate any mis-alignment. Better and more consistent welding results from the self-correcting spigot 14, since an distribution of force between the horn 46 and the screw cap arrangement 40 will be delivered.

[0036] FIGS. 7 and 8 show a further embodiment of the apparatus 10. FIG. 7 shows a cross-section through the apparatus 10 where the spigot 14 and the anvil 20 are in a parallel position, with the longitudinal axes of the spigot 14 and the anvil 20 being parallel. FIG. 8 shows an exploded view of the components of this embodiment of the apparatus 10. This embodiment principally differs from the previous embodiments by the provision of an O-ring 36, which is located between and in contact with the spherical bearing 30 and the anvil 20. The O-ring 36 is compressible and has two main functions. Firstly, the O-ring 36 is a sealing device and provides sealing between the anvil 20 and the spherical bearing 20 and secondly, the O-ring 36 also provides a force tensioning the spigot 14 against the anvil 20 in addition to the spring 24. In fact the force provided by the O-ring 36 is against that of the spring 24, but both provide a force tensioning the spigot 14 against the anvil 20. A cap 38 is also provided to seal the end of the screw 34 and a second O-ring 48 is provided between the cap 38 and the anvil 20. The O-ring 36 could be replaced by a different sealing device such as a quad-ring or a compressible cylinder, either of which could be used to provide the twin functions of sealing and provision of the tensioning force.

[0037] FIGS. 9 and 10 show a yet further embodiment of the apparatus 10. This version differs from the embodiment shown in FIGS. 7 and 8 principally in that the spring 24 is not present. This means that the sole tensioning device in the apparatus 10 is the O-ring 36, which is under a small amount of compression and therefore tends to push the spherical bearing 30 (and hence the spigot 14) away from the anvil 20. The spigot 14 shown in this embodiment is also in the two part form, with a separate head 18 and body 16. The correction provided by the apparatus 10 is achieved by the movement of the spigot 14 within the anvil 20, with the O-ring 36 able to be compressed to allow for angular movement of the spigot 14 relative to the anvil 20.

[0038] FIGS. 11, 12 and 13 show a yet further embodiment of the apparatus 10. This version differs from previous embodiments in that the spigot 14 does not protrude from the surface of the anvil 20. The external face 50 of the spigot 14 is flush with the surface of the anvil 20. The spigot 14 is provided with holes 52 in the face 50. As in all embodiments, the size of the hole 22 in the anvil 20 is sufficiently greater than the size of the elongate body 16 of the spigot 14 to permit angular movement of the spigot 14 relative to the anvil 20 and the apparatus 10 includes a tensioning device 24 (a spring) arranged to provide a force tensioning the spigot 14 against the anvil 20.

[0039] The apparatus 10 of FIGS. 11 to 13 works by providing an internal vacuum that can be used to suck a screw cap arrangement 40 onto the face 50 of the spigot 14. In use, the anvil 20, with the screw cap arrangement 40 fixed to the face 50 of the spigot 14 is brought into contact with the horn 46 of the cap applicator unit 12 and the spigot 14 is able to move relative to the anvil 20 to correct any slight misalignment between the horn 46 and the anvil 20. The apparatus 10 shown in these Figures can also be used in cap applicator units that do not have the screw cap arrangement 40 introduced from the interior of the partially formed container 42. In such unit, the screw cap arrangement 40 is mounted on the horn 46 rather than the spigot 14 and remains external to the partially formed container 42. The anvil 20 and spigot 14 arrangement shown in FIGS. 11 to 13 can be used internally within the partially formed container 42 and are still able to provide correction for any misalignment between the horn 46 and the anvil 20.