Rotary-type capping machine

Abstract

A rotary capping machine for containers with screw caps includes a central and fixedly mounted support around which a rotary carrier having capping arrangements can be driven to rotate rotation by a first motor. The capping arrangements have capping tools that can be lifted and lowered and that can be rotated by a second motor. Each has, on its underside, a capping head for receiving screw caps. The support central includes a bottom support, the top end of which is connected to a middle support that forms a bearing section and that has a rotary bearing. The middle support releasably connects to a top support, which releasably connects to a head plate. The drive gear's rotation axis and that of the first motor are parallel to the machine axis. The drive gear meshes with a crown gear formed on the rotary carrier. The second motor's drive gear is parallel to the machine axis and meshes with a crown gear formed on the control element.

Claims

1. An apparatus comprising a capping machine for screwing a screw-closure onto a container, said capping machine being a rotary capping machine that rotates about a machine axis, said capping machine comprising a support element, said support element being a central and fixedly-mounted support element that is configured to be rotated by a first motor and around which a rotary support having capping arrangements is arranged, each of said capping arrangements comprising a capping tool that is configured to be raised and lowered and to be rotated by a second motor that is controlled independently of said first motor, each of said capping tools having, on an underside thereof, a capping head for receiving screw closures, said support element comprising a carrier that comprises a bottom support, wherein a top end of said carrier connects to a middle support that forms a bearing section that comprises a first rotary bearing and a rotary support, wherein said middle support is configured to transition between being connected to a top support and being released from said top support, a control element mounted so as to rotate about said machine axis and configured to be rotated by said second motor, wherein said second motor interacts with said capping tools to transfer controlled rotation to said capping heads, a head plate that connects to said support element, wherein said top support is configured to transition between being connected to said head plate and being released from said head plate, and a control link, said control link being a non-rotating control link that is mounted on at least one of said support element and said head plate for raising and lowering said capping heads during rotation of said capping arrangements about said support element, wherein said first and second motors comprise corresponding first and second drive-gear wheels, wherein said first drive-gear wheel rotates about an axis of rotation that is parallel to said machine axis and meshes with a first crown-gear wheel that is arranged at said rotary support and wherein said second drive-gear wheel is oriented parallel to said machine axis and meshes with a second crown-gear wheel that is formed on said control element, wherein said top support encloses an inner space that contains said machine axis and wherein a greater part of said first drive-gear wheel is arranged inside said inner space, and wherein said top support is open over a machine sector in which said first drive-gear wheel meshes with said crown-gear wheel of said rotary support.

2. The apparatus of claim 1, further comprising a shaft guide that extends parallel to said machine axis, said shaft guide being a shaft guide of one of said first and second motors.

3. The apparatus of claim 1, further comprising a flange, wherein, as a result of said flange, said middle support transitions between being secured to said bottom support and being released from said bottom support.

4. The apparatus of claim 1, wherein said top support is detachable from said heat plate, said middle support is detachable from said top support, and said bottom support is detachable from said middle support.

5. The apparatus of claim 1, wherein said control element is mounted at one of said top support and said rotary support and wherein said control element is able to rotate after having been so mounted.

6. The apparatus of claim 1, wherein said control element is mounted on said rotary support.

7. The apparatus of claim 1, wherein a shaft guide of said first motor extends inside said inner space and wherein said inner space is enclosed by said top support.

8. The apparatus of claim 1, wherein said top support comprises vertical support braces that are arranged around said machine axis and that are parallel to said machine axis.

9. The apparatus of claim 1, further comprising a runner that extends along an upper side of said rotatable capping tools, wherein said runner runs along said control link.

10. The apparatus of claim 1, further comprising a screw flange, wherein said screw flange connects said bottom support to said middle support at a location that is beneath said rotary support, said location being separated from said rotary support by between five centimeters and thirty centimeters.

11. The apparatus of claim 1, further comprising a screw flange, wherein said screw flange connects said bottom support to said middle support at a location that is beneath said rotary support, said location being separated from said rotary support by no more than forty centimeters.

12. The apparatus of claim 1, wherein said bottom support element is a column that has a polygonal cross section and wherein said column is concentric with said machine axis.

13. The apparatus of claim 1, wherein a motor selected from the group consisting of said first and second motors is secured to said head plate, wherein said motor's shaft guide extends vertically downward toward said respective drive-gear wheel along a direction parallel to said machine axis.

14. The apparatus of claim 13, wherein said shaft guide extends into a ring-shaped region between said top support and said capping arrangements.

15. The apparatus of claim 13, wherein said second drive-gear wheel extends into a ring-shaped region between said top support and said capping arrangements.

16. The apparatus of claim 1, further comprising a shaft guide that extends parallel to said machine axis and projects as far as said middle support, said shaft guide being a shaft guide of one of said first and second motors.

17. The apparatus of claim 1, wherein said control element is mounted at said rotary support and wherein said control element is able to rotate independently of said rotary support after having been so mounted.

18. The apparatus of claim 1, wherein said capping machine is configured to be dismantled from above starting with said head plate.

19. The apparatus of claim 1, wherein said second crown-gear wheel carries an inner crown gear on a radially-outward surface thereof and wherein said second drive-gear wheel engages said inner crown gear.

20. The apparatus of claim 1, wherein said carries an outer crown gear on a radially-outer surface thereof and wherein said second drive-gear wheel engages said outer crown gear.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is described hereinafter on the basis of the schematic drawings, in which

(2) FIG. 1 is a perspective partially sectional view of a capping machine with an inner tooth arrangement,

(3) FIG. 2 is an enlarged section in the middle region of the capping machine from FIG. 1, and

(4) FIG. 3 is a perspective view of an alternative capping machine with an outer tooth arrangement.

DETAILED DESCRIPTION

(5) FIG. 1 shows a capping machine 10 having a bottom support 12 that extends along a machine axis. In the illustrated embodiment, the bottom support 12 is implemented as a polygonal support column having a screw flange 14 at an upper end thereof.

(6) The capping machine 10 also includes a middle support 16 that is screwed onto the screw flange 14. An outer circumferential surface of the middle support 16 features a first rotary bearing 38 for a rotary support 32. An outer surface of the rotary support 32 carries capping arrangements 56.

(7) A top support 18 that is screwed onto the middle support includes vertical support braces 20 that are spaced apart from each other equidistantly around the machine axis. The vertical support braces 20 delimit an inner space 64 through which the machine axis extends. Securing screws 23 screw an upper end of the vertical support braces 20 to a head plate 22. The head plate 22 carries a first motor 24, a shaft guide 26 of which extends through the inner space 64.

(8) A drive gear wheel 40 arranged under the first motor's shaft guide 26 meshes with a crown gear-wheel 42. The crown gear wheel 42 securely connects to the rotary support 32. This prevents relative rotation between the crown gear wheel 42 and the rotary support 32. As a result, the first motor 24, the rotary bearing 32, and the capping arrangements 56 rotate at an adjustable speed.

(9) The head plate 22 also carries a second motor 28, a shaft guide 30 of which extends downward to the second motor's drive gear wheel 48. This drive gear wheel 48 meshes with another crown gear wheel 50 at a control element 46.

(10) In the illustrated embodiment, the crown gear wheel 50 is an inner crown gear. However, in some embodiments, the crown gear wheel 50 is an outer crown gear. In such embodiments, the shaft guide 30 and the drive gear wheel 48 are arranged to engage the radially outward surface of the crown gear wheel 50, as shown in FIG. 3.

(11) A second rotary bearing 44 mounts the control element 46 on the rotary support 32. As a result, the control element 46 rotates independently of the rotary support 32 even though it is mounted to the rotary support 32.

(12) The control element 46 includes an outer crown gear wheel 54 that meshes with an outer tooth arrangement 60 at capping tools 58 of the capping arrangements 56. As a result, the second motor 28 causes controlled rotation of the capping tools 58, which then transfer this controlled rotation to capping heads 59 arranged at the bottom ends of the capping tools 58. These capping heads 59 carry screw caps.

(13) Vertical braces connect the rotary bearing 32 to a container carrier 34. At its outer surface, the container carrier 34 comprises container receivers 35 that receive containers 66. The container carrier 34 holds the containers 66 beneath corresponding capping heads 59.

(14) Each capping tool 58 has a top end that connects to a runner 62. The runner 62 runs along a control curve of a control link 52. In some embodiments, the control link 52 connects to the head plate 22. In others it connects to the vertical support braces 20. In yet others, it connects to both. In each case, the connection is a secure connection that prevents relative rotation between the control link and whatever it connects to. As a result, the capping tools 58 and the capping heads 59 undergo defined vertical motion. This permits them to both place screw caps onto containers 66 and to also screw them tightly, all in a single capping procedure.

(15) As a result of the foregoing construction, it is a simple matter to dismantle the capping machine 10 from the head plate 22. Once the head plate 22 and either the top support 18 or the vertical support braces 20 have been dismantled, it is easy to then dismantle the first motor's shaft guide 26, the second motor's shaft guide 30, the first motor's drive gear wheel 40, and the second motor's drive gear wheel 48 from the rotary support 32 and the control element 46. This makes it easy to dismantle the capping machine 10 and to replace its individual components.

(16) The screw flange 14 is vertically offset from the rotary support 32 by no more than about thirty centimeters. As a result, when the capping machine 10 is being dismantled, it is not necessary to provide the rather large space that would otherwise be needed to accommodate the length of the bottom support 12.

(17) An advantage of the foregoing construction arises because all major components of the capping machine 10 can be dismantled from the head plate 22 as far as the flange 14. It is also unnecessary to dismantle the bottom support 12 to access the major components of the capping machine 10.

(18) An alternative embodiment, shown in FIG. 3, is similar to that shown in FIGS. 1 and 2 but with the notable exception of the drive being provided by the second motor 28.

(19) In the embodiment shown in FIG. 3, the head plate 22 carries a second motor 28, which has been omitted from the figure for clarity. The second motor's shaft guide 30 extends down to the second motor's drive gear wheel 48. The second motor's drive gear wheel 48 meshes with a crown gear wheel 50 at the control element 46. In the illustrated embodiment, the crown gear wheel's teeth face radially outward. Therefore, the shaft guide 30 and the drive gear wheel 48 are both disposed outside the circle defined by the crown-gear wheel 50 to engage these teeth.