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Title:
MACHINE AND METHOD FOR AUTOMATICALLY CAPPING CONTAINERS, AND PACKAGING LINE COMPRISING SAID MACHINE
Document Type and Number:
WIPO Patent Application WO/2020/161759
Kind Code:
A1
Abstract:
Apparatus for capping containers (101), comprising a plurality of mobile transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H), rotatably positioned around a main axis of rotation (Z), and configured to pick up caps (102) individually fed by a feed line (103) and to deposit each of them on a respective container (101) to be capped and advancing on a transport line (109), wherein each transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) comprises a gripping head (30) to grip the caps (102), able to be driven into rotation on itself around an axis of longitudinal development (T), and the apparatus also comprises at least two movement groups (13; 14), driven by respective motor members (28, 29), and each configured to move a respective group of said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) between a retracted condition (R), in which the transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12FI) are closer to the main axis of rotation (Z), and an extended condition (E), in which the transport units (12A, 12C, 12E, 12G, 12B, 12D, 12F, 12H) are more distant from the main axis of rotation (Z).

Inventors:
SASSI FABIO (IT)
PAPPALARDO GIACINTO FRANCESCO (IT)
Application Number:
PCT/IT2020/050021
Publication Date:
August 13, 2020
Filing Date:
February 05, 2020
Export Citation:
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Assignee:
IMA INDUSTRIA MACCH AUTOMATICHE SPA (IT)
International Classes:
B65B7/28; B65B25/00; B65B35/58; B65B59/00
Domestic Patent References:
WO2010140079A12010-12-09
Foreign References:
US4498275A1985-02-12
US20110016828A12011-01-27
US20150121815A12015-05-07
Attorney, Agent or Firm:
PETRAZ, Davide Luigi et al. (IT)
Download PDF:
Claims:
CLAIMS

1. Capping machine for capping containers (101), comprising:

- a line (103) to feed caps (102),

- a line (109) to transport said containers (101),

- an apparatus (10) comprising a plurality of transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H), mobile with continuous rotary motion around a main axis of rotation (Z), and a main actuator (38) configured to drive said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) in rotation around said main axis of rotation (Z), said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) being configured to pick up caps (102) individually fed by said feed line (103) and to deposit each of them on a respective container (101) to be capped and advancing on said transport line (109), wherein each transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) comprises a gripping head (30) to grip the caps (102), the apparatus also comprising at least two movement groups (13; 14) each configured to move a first or second group of said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) according to an oscillating movement along a displacement directrix having at least one radial component (L) with respect to said main axis of rotation (Z), between a retracted condition (R), in which said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12E1) are closer to the main axis of rotation (Z), and an extended condition (E), in which said transport units (12A, 12C, 12E, 12G, 12B, 12D, 12F, 12H) are more distant from the main axis of rotation (Z), each of said at least two movement groups (13; 14) comprising a plurality of articulated movement devices (25) each moving a respective one of said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) according to an alternate movement between said retracted condition (R) and said extended condition (E), in succession first into a pick-up position (PI) where the cap (102) is picked up, and subsequently into a delivery position (P2) where the cap (102) is delivered onto a respective container (101); wherein the pick-up (PI) and delivery (P2) positions of a cap (102) are located, with reference to said radial component (L), between said retracted condition (R) and said extended condition (E); and wherein transport units (12A, 12C, 12E, 12G) comprised in said first group are disposed alternately with transport units (12B, 12D, 12F, 12H) comprised in said second group, so that two consecutive transport units (12A, 12C, 12E, 12G, 12B, 12D, 12F, 12H) are respectively constrained to a different movement group (13; 14), and

- a programmable control and management unit (45), which is configured to control, in a coordinated manner, the movement of said apparatus (10) with the movement of said feed line (103) of the caps (102), and possibly with the movement of said transport line (109) of the containers (101),

the capping machine being characterized in that it comprises at least one detection device (108) configured to detect the position and/or orientation of the caps (102) on said feed line (103), and in that said apparatus comprises at least two motor members (28; 29) each configured to drive a respective one of said movement groups (13; 14) in order to move said articulated movement devices (25) so as to take said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) in succession into said pick-up (PI) and delivery (P2) positions of the cap (102).

2. Machine as in claim 1, characterized in that it comprises a support device (11) which extends around said main axis of rotation (Z) and comprises a fixed base (15) and a support member (16), mobile with respect to said base (15) and rotating around said main axis of rotation (Z), being driven in rotation by said main actuator (38).

3. Machine as in claim 1 or 2, characterized in that said transport units (12 A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) are supported by a support member (16) of a support device (11), rotating around said main axis of rotation (Z), and comprising a plurality of lobes (17), each intended to support a respective transport unit (12); wherein the latter is pivoted to the respective lobe (17) and moved, in order to carry out said oscillating movement, by means of a respective one of said articulated movement devices (25) connected to a movement member

(23), which is in turn driven into rotation around said main axis of rotation (Z) by said motor members (28; 29) which drive said movement group (13; 14).

4. Machine as in any claim hereinbefore, characterized in that each transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) develops mainly along a respective axis of longitudinal development (T), substantially vertical, and parallel to said main axis of rotation (Z), and comprises an actuator (34) to move the corresponding gripping head (30), which is configured both to slide linearly along, and to rotate around, said axis of longitudinal development (T). 5. Machine as in any claim hereinbefore, characterized in that said gripping head (30) comprises a seating (31) intended to receive a cap (102) and having a shape mating with that of the cap, and also comprises a holding member (32) to hold the cap (102) inside said seating (31).

6. Machine as in claim 5, characterized in that said holding member (32) is configured as a suction cup, and a feed channel (33) is also provided, which puts said holding member (32) in flow communication with a source of air at a pressure lower than atmospheric pressure, suitable to allow the generation of a depression sufficient to guarantee that the cap (102) is held by said gripping head (30).

7. Machine as in any claim hereinbefore, characterized in that said feed line (103) comprises a spacer device (105) and/or one or more positioning members (106) configured to modify the position of the caps (102) on said feed line (103).

8. Machine as in any claim hereinbefore, characterized in that said gripping head (30) for picking up the caps (102) is rotatably mounted around an axis of longitudinal development (T) of the respective transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H).

9. Machine as in any claim hereinbefore, characterized in that in the pick-up and delivery positions (PI, P2) said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) are disposed respectively above the cap (102) to be picked up and the container (101) to be capped, substantially aligned vertically with them.

10. Packaging line able to fill containers with discrete items, for example food items, such as sweets, chocolates, chewing gum, and comprising a station to fill said containers (101) with said items and a capping machine (100) as in any claim hereinbefore.

11. Method for capping containers (101) by means of a capping machine (100), characterized in that it is provided to move caps (102) forward, individually fed, on a feed line (103), to detect the position and/or the orientation of the caps (102) by means of a detection device (108), to drive a plurality of mobile transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H), configured to each pick up one cap (102) in a pick-up position (PI), and to deposit them each in a delivery position (P2), on a respective container (101) to be capped which is advancing on a transport line (109), wherein said drive allows to take said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) in succession firstly into said pick-up position (PI) of the cap (102) and, subsequently, into said delivery position (P2) of the cap (102) on a respective container (101), positions (PI, P2) in which the transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) are disposed respectively above a cap (102) to be picked up and a container (101) to be capped, substantially aligned vertically with them, wherein before said drive it is provided, by means of a control and management unit (45) of said capping machine (100), to determine at least the position that said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) will have to assume in said pick-up position (PI) as a function of the position of said cap (102) as detected by means of said pick-up device (108), and possibly, after said control and management unit (45) has calculated the instant in time when said transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12F1) will reach said pick-up position (PI), to modify the feed speed of the caps (102) on said feed line (103) so that the cap (102) to be picked up and the transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) reach said pick-up position (PI) temporally coordinated with each other, wherein said drive comprises:

- driving into rotating, according to a continuous rotary motion, a plurality of transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) around a main axis of rotation (Z) by means of a main actuator (34),

- possibly rotating on itself a gripping head (30) of the caps (102), comprised in each of said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) by means of an actuator (24) configured to rotate said gripping head (30) around an axis of longitudinal development (T) of the respective transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12FI), as a function of the orientation of the cap (102) as detected by said detection device (108);

- moving respective first and second groups of said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) according to an oscillating movement, by means of at least two movement groups (13; 14), along a displacement directrix having at least one radial component (L) with respect to said main axis of rotation (Z), between a retracted condition (R), in which said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) are closer to said main axis of rotation (Z), and an extended condition (E), in which said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) are more distant from said main axis of rotation (Z), wherein each of said transport units (12 A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) is connected to an articulated movement device (25) comprised in said at least two movement groups (13; 14) in order to move said transport units (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) according to an alternate movement between said retracted condition (R) and said extended condition (E); said moving comprises driving at least two motor members (28, 29) each configured to drive a respective one of said movement groups (13; 14) in order to move said articulated movement devices (25) according to an alternate movement between said retracted condition (R) and said extended condition (E), between which there are, with reference to said radial component (L), said pick-up position (PI) and said delivery position (P2) of a cap (102);

- taking one transport unit (12A, 12C, 12E, 12G) comprised in the first group to the pick-up position (PI) of the cap (102), and at the same time, taking one transport unit (12B, 12D, 12F, 12H) comprised in the second group to the delivery position (P2) of the cap (102) on a respective container (101), or vice versa.

12. Method as in claim 11, characterized in that it is provided, by means of said actuator (24), to lower the gripping head (30) of the transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) in correspondence with the pick-up position (PI) and the delivery position (P2) of the cap (102), respectively to pick up the cap (102) individually fed by the feed line (103) and to deposit it on a respective container (101) advancing on the transport line (109), and subsequently, after having respectively picked up and deposited the cap (102), to raise the gripping head (30).

13. Method as in claim 11 or 12, characterized in that it is provided that, in the pick-up position (PI) of the cap (102), the transport unit (12A, 12C, 12E, 12G; 12B, 12D, 12F, 12H) moves at a speed correlated to the feed speed of the feed line (103) moving forward the caps (102) individually, and in that in the delivery position (P2), the transport unit (12A, 12C, 12E, 12G, 12B, 12D, 12F, 12FI) moves at a speed correlated to the feed speed of the transport line (109) of the containers (101).

Description:
“MACHINE AND METHOD FOR AUTOMATICALLY CAPPING CONTAINERS, AND PACKAGING LINE COMPRISING SAID MACHINE”

FIELD OF THE INVENTION

The field of application of the present invention is that of machines and methods for automatically capping containers. In particular, but not only, the containers can be plastic containers intended to contain a plurality of discrete items, for example sweets such as candy, chewing gum, chocolates, biscuits, or food stuff in general. The present invention also concerns a packaging line able to fill the containers with the discrete items and comprising the machine for capping the containers, after they have been filled.

BACKGROUND OF THE INVENTION

Automatic packaging machines are known in the state of the art which are provided with devices able to cap containers previously filled with a plurality of items.

In accordance with some embodiments, described for example in patent document n. WO 2010/140079 Al, known devices comprise a plurality of mechanical members which pick up the caps and deposit them on the containers to be capped, where a suitable thruster element exerts a thrust force suitable to stably constrain the cap to the respective container, so as to close the latter.

The mechanical members as above typically comprise one or more rotatable members, each one rotating around a respective axis of rotation, for example conformed as star wheels provided with a plurality of seatings suitably shaped in order to temporarily hold the containers to be capped during the capping operation. In these solutions known in the state of the art the containers are made to advance by the first wheel, which is driven in rotation according to a stepwise indexed movement. There is provided a station for depositing the caps where these are rested on the containers, and, subsequently, a capping station where the caps are pressed by a thruster member against the mouth of the container, in order to close the latter.

One disadvantage of this solution known in the state of the art is that long and laborious operations are necessary to adjust the mechanical parts at each change in format of the caps. This initial set-up step, which has to be carried out by specialized technical operators, can lead to long and expensive machine downtimes.

Another disadvantage of this solution is that the star wheels are not able to effectively transport containers and/or caps having special shapes and outlines. Another disadvantage of this solution known in the state of the art is that it is very complex from a mechanical point of view, in particular if the pick-up of the caps and their delivery onto the containers occurs on horizontal planes disposed at different vertical heights.

In order to try to overcome these disadvantages, other solutions known in the state of the art have also been developed, comprising anthropomorphic arms with multiple work axes for manipulating the caps.

Examples of anthropomorphic arms suitable to be used in the context of a piece of equipment for automatically capping containers are robots commonly used in the industrial automation sector and known as Delta robots, or robots called Scara (Selective Compliance Assembly Robot Arm).

The robots known in the state of the art comprise an articulated arm provided with several elements, articulated each with respect to the other according to the desired degrees of freedom, and supporting a tool, for example configured as a gripper, for picking up the caps, and depositing them on respective containers. One disadvantage of this solution is that it is incompatible with the high productivity of an automatic packaging machine. As an indication, an objective figure for this productivity is approximately 400 containers packed per minute.

It has been estimated that the time required for the articulated arm to travel the trajectories provided from the point in which the cap is picked up, to the point in which it is delivered onto the respective container, moving at the usual speeds of movement of the robot, would allow to reach a productivity value equaling about 100-120 containers packed per minute.

Consequently, four robots would be required to achieve the target value of 400 containers per minute.

It is clear that one disadvantage of this configuration is that it is very expensive and bulky, with a considerable increase in the volumes of the packaging machine due to the significant maneuvering spaces required for the four robots. Another disadvantage is it is a very complex configuration to control, because it would be necessary to coordinate the action of the different robots, in order to prevent reciprocal collisions, or collisions with other parts of the packaging machine.

There is therefore a need to make available a capping machine for automatically capping containers, and to perfect the corresponding capping method, which allow to overcome at least one of the disadvantages of the state of the art.

One purpose of the present invention is therefore to provide a machine, and to perfect the corresponding method, for automatically capping containers, which, by overcoming the disadvantages of the state of the art, is fast and reliable, able to manipulate the caps at such a speed that it allows the automatic packaging line to reach high productivity values.

Another purpose of the present invention is to provide a machine, and to perfect the corresponding method, for automatically capping containers, which is more compact and less expensive than the solutions known in the state of the art.

Another purpose of the present invention is to provide a machine, and to perfect the corresponding method, for automatically capping containers, which is flexible, being able to manipulate different types of caps and requiring simple and rapid format change operations, which do not lead to long machine downtimes.

Another purpose of the present invention is to provide a machine, and to perfect the corresponding method, for automatically capping containers, which can be easily integrated into a packaging line so that it is possible to provide machine parts, such as for example the container transport line, which are suitable to interact with other work stations on the line, for example with a container filling station, so as to optimize the bulk, the number and disposition of the machine components, while also simplifying their structure.

The Applicant has devised, tested and embodied the present invention to overcome the shortcomings of the state of the art and to obtain these and other purposes and advantages.

SUMMARY OF THE INVENTION

The present invention is set forth and characterized in the independent claims, while the dependent claims describe other characteristics of the invention or variants to the main inventive idea.

In accordance with the above purposes, a capping machine is provided for capping containers comprising a line to feed caps comprising at least one detection device configured to detect the position and/or the orientation of the caps on the feed line, a line to transport the containers, and an apparatus comprising a plurality of transport units, mobile with continuous rotary motion around a main axis of rotation, and a main actuator configured to drive the transport units in rotation around the axis as above, wherein the transport units are each configured to pick up a respective cap on the transport line and to deposit it on a respective container to be capped on the transport line. According to a possible embodiment, each transport unit also comprises a gripping head able to be driven in rotation on itself, so as to be rotatably mounted around an axis of longitudinal development of the transport units.

According to a characteristic aspect of the present invention, the apparatus comprises at least two movement groups, each configured to move a first and second group of transport units according to an oscillating movement along a displacement directrix having at least one radial component with respect to the main axis of rotation, between a retracted condition, in which the transport units are closer to the main axis of rotation, and an extended condition, in which the transport units are more distant from the main axis of rotation; each movement group comprising a plurality of articulated movement devices each carrying a respective one transport unit in order to move the latter according to an alternate movement between the retracted condition and the extended condition.

According to another aspect of the present invention, the apparatus also comprises at least two motor members, each configured to drive a respective movement group in order to move the articulated movement devices as above so as to take the transport units in succession first into a pick-up position where the cap is picked up, and subsequently into a delivery position where the cap is delivered onto a respective container, in which the transport units are disposed respectively above a cap to be picked up and a container to be capped, substantially aligned vertically with them; wherein the pick-up and delivery positions of a cap are disposed, with reference to the radial component as above, between the retracted condition and the extended condition.

The capping machine comprises a programmable control and management unit, which is configured to control, in a coordinated manner, the movement of the apparatus with the movement of the feed line of the caps, and possibly with the movement of the transport line of the containers.

One advantage of the capping machine according to the present invention is that it is very flexible because the transport units can be advantageously taken into a position such that they are substantially aligned, in the pick-up position, with the caps to be picked up, and, in the delivery position, with the containers to be capped. Thanks to the control and command unit, the apparatus and the lines to feed the caps and to transport the containers are driven effectively and rapidly, in order to allow the capping machine to operate reliably and to reach high production rates.

The apparatus according to the present invention advantageously allows to adjust the movement of the transport units in order to easily adapt to caps and/or containers of the most varied formats. In fact, the pick-up and delivery positions can be easily changed, since in order to change them it is sufficient to change the movement of the transport units (in particular, the trajectories and displacement speeds), for example in order to adapt to different operative conditions of the line to feed the caps.

Another advantage of the apparatus according to the present invention is that it is very compact, having a limited radial extension which allows to reduce its bulk.

Another advantage of the apparatus according to the present invention is that it does not require long and laborious format change operations. It is in fact sufficient to replace the gripping heads that grip the caps with another set of gripping heads having a shape mating with that of the format of the caps to be transported.

In a preferred embodiment, the transport units all rotate together around the main axis of rotation, for example according to a continuous motion with constant speed, all driven by the main actuator as above; however, with regards to the oscillating movement, the transport units of the first group are released in their movement from the transport units of the second group thanks to the independent motorization of the two groups, the former being for example in the retracted position, and the latter in the extended one.

According to a preferred embodiment, the transport units comprised in the first group are disposed alternately with the transport units comprised in the second group, so that two consecutive transport units are constrained to a different movement group.

According to embodiments provided here, the movement groups as above are configured as an articulated quadrilateral.

Each transport unit extends along its axis of longitudinal development, which is substantially parallel to the main axis of rotation.

According to some embodiments, each transport unit comprises an actuator configured to move the gripping head of the caps which is mobile, in particular according to two different degrees of freedom, with respect to the transport unit itself. According to some embodiments, the gripping head can both rotate around the axis of longitudinal development, and also translate linearly along the same axis.

Advantageously, the linear translation movement of the gripping heads allows them to be lowered toward the feed line of the caps and the transport line of the containers, both to pick up the caps and to deposit them on the containers, and to be raised - possibly together with the caps they hold - after the caps have been picked up and delivered. In addition, the actuator allows the gripping head to exert the necessary thrust action that allows to constrain the cap in a stable and permanent manner to the respective container.

Thanks to the fact that the gripping heads can rotate around the axis of longitudinal development of the transport unit that comprises them, they can advantageously rotate in order to angularly orient the seating able to receive the cap in accordance with the disposition of the cap on the feed line of the caps, a disposition which is detected before the cap arrives in correspondence with the pick-up position by suitable optical detection means.

The possibility that the gripping heads rotate around the axis of longitudinal development of the respective transport unit also advantageously means that the gripping heads are able to effectively manage the capping operation even if the caps are screw-on caps, because the rotation movement as above makes them suitable for screwing these caps on to the respective container.

According to some embodiments, the apparatus comprises pneumatic holding means to hold the cap, associated with the gripping heads, configured to exert a depression able to hold the caps.

According to another aspect of the present invention, an apparatus is provided in accordance with the embodiments described above, cooperating with work stations disposed upstream and downstream of the apparatus, which are different from the feed and transport lines described above, possibly also in the context of an automatic machine different from the capping machine as above.

According to another aspect of the present invention, a method is provided for capping containers, in particular by means of a capping machine in accordance with embodiments described above, in which it is provided to move the caps forward, individually fed, on a feed line, to detect the position and/or the orientation of the caps by means of a detection device, to drive a plurality of mobile transport units configured to each pick up one cap in a pick-up position, and to deposit them each in a delivery position on a respective container to be capped which is advancing on a transport line. The step of driving the plurality of transport units allows to take them in succession firstly into the pick-up position of the cap and, subsequently, into the delivery position of the cap on a respective container, positions in which the transport units are disposed respectively above a cap to be picked up and a container to be capped, substantially aligned vertically with them.

According to a characteristic aspect of the method according to the present invention, before the driving step it is provided, by means of a control and management unit of the capping machine, to determine at least the position that the transport units will have to assume in the pick-up position as a function of the position of the cap that has been detected by means of the pick-up device, and possibly, after the control and management unit has calculated the instant in time when the transport unit will reach the pick-up position, to modify the feed speed of the caps on the feed line so that the cap to be picked up and the transport unit reach the pick-up position temporally coordinated with each other.

According to another characteristic aspect of the method according to the present invention, the driving step comprises: - driving into rotation, according to a continuous rotary motion, the plurality of transport units around a main axis of rotation by means of a main actuator,

- possibly rotating on itself a gripping head of the caps, comprised in each of the transport units by means of an actuator configured to rotate the gripping head around an axis of longitudinal development of the respective transport unit, as a function of the orientation of the cap as detected by the detection device;

- moving respective first and second groups of the transport units according to an oscillating movement, by means of at least two movement groups, along a displacement directrix having at least one radial component with respect to the main axis of rotation, between a retracted condition, in which the transport units are closer to the main axis of rotation, and an extended condition, in which the transport units are more distant from the main axis of rotation; wherein each of the transport units is connected to an articulated movement device comprised in the two movement groups in order to move the transport units according to an alternate movement between the retracted condition and the extended condition as above; wherein it is provided to drive at least two motor members each configured to drive a respective one of the movement groups in order to move the articulated movement devices according to an alternate movement between the retracted condition and the extended condition as above, between which there are, with reference to the radial component, the pick-up position and the delivery position of a cap;

- taking one transport unit comprised in the first group to the pick-up position of the cap, and at the same time, taking one transport unit comprised in the second group to the delivery position of the cap on a respective container, or vice versa.

According to some embodiments of the method according to the present invention, it is provided, by means of an actuator, to lower the gripping head of the transport unit in correspondence with the pick-up position and the delivery position of the cap, respectively to pick up the cap individually fed by the feed line and to deposit it on a respective container advancing on the transport line, and subsequently, after having respectively picked up and deposited the cap, to raise the gripping head.

According to some embodiments of the method according to the present invention, it is provided that, in the pick-up position of the cap, the transport unit moves at a speed correlated to the speed of advance of the feed line of the caps (for example, at a speed equal to the speed of advance of the conveyor belts that form the line), and that, in the delivery position of the cap, the transport unit moves at a speed correlated to the speed of advance of the transport line of the containers (for example, at a speed equal to the speed of advance of the line). In other words, the relative speed between the transport units and the conveyor belts which move the caps forward is zero, at least at the moment the cap is picked up in correspondence with the pick-up position, and, similarly, the relative speed between the transport units and the transport line of the containers is zero, at least at the moment the cap is delivered in correspondence with the delivery position.

According to another aspect of the present invention, a packaging line is provided able to fill containers with discrete items, for example food items, such as sweets, chocolates, chewing gum, and comprising a station to fill the containers with the items and a capping machine in accordance with the embodiments described above.

ILLUSTRATION OF THE DRAWINGS

These and other characteristics of the present invention will become apparent from the following description of some embodiments, given as a non-restrictive example with reference to the attached drawings wherein:

- fig. 1 is a schematic, partial perspective view of an apparatus for automatically capping containers according to the present invention, in which portions of the automatic packaging machine which comprises it are also visible;

- fig. 2 is a schematic, partial and enlarged perspective view of the apparatus of fig. 1, shown from a different angle with respect to that of fig. 1 ;

- figs. 3, 3A and 4 are schematic and partial top plan views of the apparatus for capping containers according to the present invention, in which the apparatus is shown in different operative configurations, in which portions of the packaging machine as above are also visible;

- figs. 5 and 6 are schematic top plan views of an enlarged detail of the apparatus of fig. 1 , respectively in the two operative configurations as above;

- fig. 7 is a view like that of figs. 5 and 6, which shows the apparatus in another operative condition, different from the previous ones;

- fig. 8 is a schematic, partial perspective view of some enlarged components, comprised in the apparatus of fig. 1 ;

- figs. 9A-9D are schematic front elevation views of a portion of the apparatus according to the present invention, which show an operative sequence of the method for capping containers according to the present invention;

- fig. 10 is a schematic cross-section view of a component comprised in the apparatus according to the present invention, in which a cap which will have to be associated with a respective container is also shown.

We must clarify that in the present description and in the claims the terms high, low, vertical, horizontal, upper, lower, internal and external, with their declinations, have the sole function of better illustrating the present invention with reference to the drawings and must not be in any way used to limit the scope of the invention itself, or the field of protection defined by the claims.

DESCRIPTION OF EMBODIMENTS

With reference to the drawings, a capping machine 100 (fig. 1) is described for capping containers 101 with caps 102, as part of a packaging line intended to fill containers with discrete items.

The capping machine 100 comprises an apparatus 10 (visible enlarged in fig. 2) comprising a plurality of transport units 12 for transporting the caps 102, configured to take the caps 102 from a feed line 103, in correspondence with a pick-up position PI, transport the caps 102 toward a transport line 109 of the containers 101, and, in correspondence with a delivery position P2, deposit the caps 102 on respective containers 101.

The capping machine 100 comprises a feed line 103 to feed the caps 102, comprising for example one or more conveyor belts 104, in particular disposed in sequence one after the other.

According to some embodiments described here, the feed line 103 comprises a spacer device 105, configured to distribute the caps 102, in particular in a uniform manner, on the line so as to space them appropriately to dispose them in a position suitable to be subsequently picked up by the apparatus 10, in particular by its transport units 12, as will be better explained below. In other words, the spacer device 105 (figs. 3 and 4) is able to distance each cap 102 from the immediately preceding and following caps by a distance D, measured parallel to a direction of feed X of the caps, as shown in figs. 2-4 and 8. According to some embodiments, the feed line 103 comprises one or more positioning members 106, configured to modify the position of the caps 102 on the feed line 103, for example in order to align the caps in a precise and predetermined position. In a preferred embodiment, the positioning members 106 comprise a pair of abutment elements 107, disposed on one of the conveyor belts 104, to abut against the caps 102 advancing on the line and move them to the intended position, within a defined zone.

Downstream of the positioning members 106, the feed line 103 comprises an optical detection device 108, for example configured as a high resolution and high speed digital video camera, commonly used in vision systems common in many industrial automation applications.

The optical detection device 108 is configured to detect the position and/or orientation of the cap 102 on the conveyor belt 104. In particular, the optical detection device 108 can be configured, for example, to detect both the position of the cap 102 with respect to a determinate reference (for example with respect to the transport unit intended to pick it up), and the angular orientation of the cap 102 with respect to its center.

The machine 100 comprises one or more drive members, not shown, of a type known in the state of the art, which drive the conveyor belts 104 to feed the caps 102 on the feed line 103.

The machine 100 also comprises a transport line 109 to transport the containers 101. The transport line 109, partly shown in fig. 1, can have a closed ring configuration and cooperate with devices or members of a known type, and not shown, which load the containers 101 onto the transport line 109 after they have been filled, and unload the containers 101 from the transport line 109, after they have been capped by the apparatus 10 according to the present invention.

A delivery position P2 of the caps 102 is defined on the transport line 109, in correspondence with which the apparatus 10 according to the present invention deposits the caps 102 on respective containers 101.

In one embodiment, the delivery position P2 is located on one of the two branches of the ring formed by the transport line 109 which extends along a transport axis Y.

As shown in figs. 3, 3 A and 4, the transport axis Y is for example incident with respect to the direction of feed X of the caps 102 along the feed line 103.

The transport line 109 can be driven by respective drive means, of a known type and not shown, or, alternatively, it can also be driven by an actuator member (for example a servomotor) comprised in the apparatus 10.

The transport line 109 comprises a plurality of assemblies 110, mobile along the transport line 109, and better shown in figs. 2-4 and 8-9. Each assembly 110 comprises a compartment 111, suitably shaped to accommodate a respective container 101.

The compartments 111 are shaped in such a way as to stably hold the containers 101 during their movement along the transport line 109.

It should be noted that when the shape and size of the containers to be capped change, the assemblies 110 must be replaced with other assemblies having compartments 111 with a shape mating with that of the containers 102 to be capped.

The apparatus 10 comprises a support device 11, for example having a substantially cylindrical shape, hollow inside.

The support device 11 extends, optionally in an axial-symmetrical manner, around a main axis of rotation Z of the apparatus 10, which is substantially vertical.

The support device 11 can comprise a fixed base 15 and a support member 16, mobile with respect to the base 15 and rotating around the main axis of rotation

Z.

The support device 11 supports the plurality of transport units 12 in a cantilevered manner and rotates them around the main axis of rotation Z by means of a main actuator 38, of a type known in the state of the art, visible in fig. 2.

According to one embodiment, the main actuator 38 comprises an electric motor 39 which rotates a toothed wheel 40, which in turn drives a transmission belt 41 which rotates a member integral with the support member 16, thus making the latter rotate.

According to some embodiments provided here, the apparatus 10 comprises eight transport units, to which here and in this description we will refer generically with the reference number 12, while the letters A to H will be used to identify them individually.

Each transport unit 12 develops mainly along a respective axis of longitudinal development T, substantially vertical, and parallel to the main axis of rotation Z.

The apparatus 10 comprises at least a first movement group 13, to which one or more transport units 12 are constrained.

In the embodiment described and shown in the attached drawings, the apparatus 10 also comprises a second movement group 14, to which one or more respective transport units 12 are constrained.

In particular, in this example embodiment, the four transport units 12 A, 12C, 12E, 12G form a first group constrained to the first movement group 13, while the remaining four transport units 12B, 12D, 12F, 12H form a second group constrained to the second movement group 14. In this way, the four transport units 12 A, 12C, 12E, 12G of the first group are disposed alternately with the four transport units 12B, 12D, 12F, 12H of the second group, so that two consecutive transport units are constrained to a different movement group 13, 14.

The movement group 13, 14, as will be explained in detail below, allows to move the transport units 12 between a retracted condition R (fig. 3), in which the transport units 12 are closer to the main axis of rotation Z, and an extended condition E (fig. 4), in which the transport units 12 are more distant from the main axis of rotation Z.

In the retracted condition R (fig. 3), the axes of longitudinal development T of the transport units 12 are disposed along a first circumference CMIN which defines the minimum distance, measured in a radial direction, between the transport units 12 and the main axis of rotation Z.

In the extended condition E (fig. 4), on the other hand, the axes of longitudinal development T of the transport units 12 are disposed along a second circumference C MA x which defines the maximum distance, measured in a radial direction, between the transport units 12 and the main axis of rotation Z.

As will be clarified by this detailed description, the transport units 12 can be disposed in a suitable position, so that they are vertically aligned respectively above the cap 102 to be picked up in the pick-up position PI and above the container 101 to be capped in the delivery position P2, which is variable between the retracted condition R and the extended condition E. In particular, this suitable position is the position in which the ideal circumference defined as the place of the points on which the axes of longitudinal development T of the transport units 12 are located connected to the same movement group 13, 14 is substantially tangent respectively to the direction of feed X in the pick-up position PI and/or to the transport direction Y in the delivery point P2. The ideal circumference as above is a circumference having a radius comprised between the radius of the first circumference C M IN and the radius of the second circumference C MA x. For reasons of clarity, in fig. 3 the second circumference C M AX has also been shown; while in fig. 4 the first C MIN circumference has also been shown, so as to display, in the same drawing, the minimum and maximum radial extension limit of the transport units 12.

According to one embodiment, the transport units 12 are supported by the support member 16 of the support device 11.

In the embodiment provided here, the support member 16 comprises a plurality of lobes 17, each intended to support a respective transport unit 12.

Each transport unit 12 is pivoted to the respective lobe 17 and moved by an articulated movement device comprised in the movement group 13, 14 and driven by motor members 28, 29, visible in fig. 2.

In the embodiment described and shown in the attached drawings, the first movement group 13 and the second movement group 14 each comprise four articulated movement devices, each configured to move, according to an alternating movement, a respective transport unit 12 comprised respectively in the first or second group of transport units, between the retracted condition R and the extended condition E.

According to some embodiments, the four articulated movement devices, both of the first movement group 13 and of the second movement group 14, are connected to a respective movement member 23, which is in turn driven in rotation around the main axis of rotation Z by the first or second motor members 28, 29, depending on whether it is the movement member 23 comprised in the first or second movement group 13, 14.

Each articulated movement device is formed by a plurality of components, reciprocally articulated, to allow the respective transport unit 12 to carry out the alternating movement as above. As best seen in figs. 5, 6 and 8, which show, enlarged, only the first movement group 13, together with its four articulated movement devices, and the first group of transport units 12 A, 12C, 12E, 12G constrained to them, isolated from the rest of the apparatus 10 for reasons of clarity, the lobes 17 are provided with a through hole 18 intended to receive an attachment pin 19.

In these drawings, the lobes 17 to which no transport unit 12 is connected are the lobes intended to receive the second group of transport units 12B, 12D, 12F, 12H, constrained to the second movement group 14, which are not shown here.

It is obvious that what can be seen in figs. 5, 6 and 8 as above could also refer to the second movement group 14, to its four articulated movement devices, and to the second group of transport units 12B, 12D, 12F, 12H constrained to them, completely analogous to the former.

The transport unit 12 comprises a body 20 from which two connection fins 21 project, toward a respective lobe 17, which are sized so as to be positioned respectively above and below the lobe 17.

Each connection fin 21 has another hole 22 (fig. 8), which is aligned with the through hole 18 and constitutes its extension so as to define a single hole having an axis substantially parallel to the axis of longitudinal development T of the transport unit 12.

The attachment pin 19 enters into the other hole 22 of the two connection fins 21, and into the through hole 18, and is tightened according to methods known in the state of the art.

In this way, each transport unit 12 is rotatably attached to the support member 16 since it is pivoted to a respective lobe 17 by means of the attachment pin 19. The first movement group 13 comprises a movement member 23, for example cruciform, provided with four arms 24 and rotating both clockwise and also counterclockwise, around the main axis of rotation Z.

In one embodiment, the main axis of rotation Z defines an axis of symmetry of the movement member 23.

According to some embodiments, the movement member 23 comprises a number of arms 24 different from four, but in any case equal to the number of transport units 12 connected to the movement group 13, 14.

We will now describe in detail the articulated movement devices comprised in the first movement group 13 and connecting a respective transport unit 12 with one of the arms 24 of the movement member 23.

Each articulated movement device comprises a rod 25, configured to connect an arm 24 to the body 20 of a respective transport unit 12.

In one embodiment, the rods 25 are connected - on one side - to the movement member 23 in correspondence with a distal end 24A of the respective arm 24, and - on the other side - to the body 20 of the respective transport unit 12 in correspondence with a coupling portion 26 of the body 20.

For the correct movement of the transport unit 12, the coupling portion 26 is located on the opposite side with respect to the fulcrum defined by the attachment pin 19, with respect to the axis of longitudinal development T of the transport units 12.

Each articulated movement device also comprises two eyelets 27 (fig. 8), each disposed in correspondence with the relative end of the rod 25, intended to engage with respective pins provided both in correspondence with the distal end 24A, and also in correspondence with the coupling portion 26. To allow the eyelet 27 to engage with the respective pin, both the distal end 24A and the coupling portion 26 are conformed as a fork, where the pin extends between the two prongs of the fork.

The apparatus 10 comprises a first motor member 28 to drive the movement group 13 in rotation. In particular, the first motor member 28, of a type known in the state of the art, drives in rotation the movement member 23 to make it perform a determinate rotation, clockwise or anticlockwise, around the main axis of rotation Z. The action of the first motor member 28 causes the movement member 23 to be mobile with respect to the support member 16, which is in turn rotatable, as previously described, around the same main axis of rotation Z.

Thanks to the conformation of the movement group described above, the rotation of the movement member 23 around the main axis of rotation corresponds to an oscillating or tilting movement of the transport units 12 connected to it, in the direction indicated by the arrows F in figs. 5 and 6. The oscillating or tilting movement as above causes the transport units 12 to move in a directrix of movement having at least one radial component L with respect to the main axis of rotation Z. As regards the reciprocal disposition of the movement groups, as shown in figs. 2-4, it can be observed that the movement members 23 of the two articulated mechanisms 13, 14 are coaxial with respect to each other and with respect to the central axis of rotation Z, one being disposed above and one below, each connected respectively to the first motor member 28 and the second motor member 29 of its own movement group.

In one embodiment, the first motor member 28 and the second motor member 29, of a type known in the state of the art, are substantially similar to each other both structurally and functionally, as shown in fig. 2.

By way of non-limiting example, the first motor member 28 and the second motor member 29 each comprise a respective electric motor 42, which rotates a toothed element 43 associated with it, on which a respective transmission belt 44 is wound. The latter selectively rotates a rotating element comprised inside the support device 11 , and for this reason not visible in the attached drawings, which is constrained to the respective movement member 23, in order to rotate in its turn the latter in the manner described above.

Fig. 7 shows another operating condition of the apparatus 10, obtainable thanks to the fact that the first movement group 13 and the second movement group 14 are commanded independently by the first motor member 28 and the second motor member 29 respectively.

The additional operating condition visible in fig. 7 shows the transport units 12 A, 12C, 12E and 12G of the first movement group 13 disposed in the retracted condition R, while the transport units 12B, 12D, 12F and 12H of the second movement group 14 are disposed in the extended condition E.

In this other operating condition, the axes of longitudinal development T of the transport units 12 A, 12C, 12E and 12G of the first movement group 13 are therefore disposed on the first circumference C MIN , while the axes of longitudinal development T of the transport units 12B, 12D, 12F and 12H of the second movement group 14 are disposed on the second circumference C M AX- In an alternative embodiment, completely equivalent to that described above with reference to fig. 7, in the further operating condition it can be provided that the transport units 12 A, 12C, 12E and 12G of the first movement group 13 are disposed in the extended condition E, while the transport units 12B, 12D, 12F and 12H of the second group of movement 14 are disposed in the retracted condition R. According to alternative embodiments, not shown, but all falling within the field of protection of the present invention, a number of movement groups other than two can be provided, each of which can comprise a number of articulated movement devices other than four, for moving a group of transport units consisting of a number of units other than four, and each movement group may have a structure different from that described above, by way of example only, provided that it is able to determine, also in a technically equivalent manner, the oscillating movement of the transport units 12.

According to some embodiments, each transport unit 12 comprises a gripping head 30 of the caps 102, better visible in the section of fig. 10.

In one embodiment, the gripping head 30 comprises a seating 31 intended to receive the cap 102, having a shape mating with that of the cap. In this case, when the shape of the caps 102 that the apparatus 10 must place on the containers 101 changes, it is necessary to change the gripping heads 30, with another set of gripping heads having a seating 31 of a shape correlated to the cap to be handled.

In one embodiment, the gripping head 30 comprises a holding member 32, for example configured as a suction cup, to retain the cap 102 inside the seating 31.

In this embodiment, a feed channel 33 is provided, which puts the holding member 32 in flow communication with an air source at a pressure lower than atmospheric pressure, suitable to allow the generation of a sufficient depression to guarantee an effective holding of the cap 102 by the gripping head 30, at least during the movement of the cap 102 from the cap feed line 103 to the container transport line 109.

In one embodiment, the surface of the holding member 32 intended to contact the cap 102 has a shape mating with that of the cap.

According to one embodiment, the holding member 32 is mobile angularly with respect to the axis of longitudinal development T to incline the surface intended to contact the cap 102 with respect to the latter. This embodiment is particularly suitable in the case where the apparatus 10 has to transport caps 102 with particular shapes, having to hold them in correspondence with an inclined surface with respect to a horizontal plane.

In alternative embodiments, not shown, the gripping head 30 does not have the holding member 32 shaped like a suction cup; however, mechanical or electro mechanical or magnetic holding means are provided, totally equivalent from the functional point of view, as an alternative to the pneumatic holding member 32 described above.

Each transport unit 12 comprises an actuator 34 to move the corresponding gripping head 30.

According to some embodiments, the actuator 34 is installed below the body 20 and constitutes its downward extension, along the axis of longitudinal development T of the transport unit 12.

In one embodiment, the actuator 34 comprises a servomotor of a type known in the state of the art, commonly available on the market.

According to some embodiments, the actuator 34 commands the movement of a bar 35, through mechanisms known in the state of the art which will not be described in detail here.

The bar 35, to which the gripping head 30 is connected, can both slide linearly along the axis of longitudinal development T, and also rotate around this same axis, thus giving the gripping head 30 a combined movement of translation and rotation with respect to axis of longitudinal development T.

Each transport unit 12 also comprises a plurality of attachments 36, for example configured as linear or L-shaped connectors, intended to receive respective distribution pipes connected to an energy source, for example electric or pneumatic, to power the various components comprised in the transport unit, such as for example the holding member 32 or the actuator 34.

The apparatus 10 also comprises a collector 37, disposed above the transport units 12, which provides for the transmission of power and data signals between the fixed and moving parts of the apparatus 10 according to methods known in the state of the art, in particular also in relation to the machine 100 which comprises it.

The capping machine 100 comprises a programmable control and management unit 45, schematically indicated by the dotted rectangle in fig. 1, configured to control its functioning and to command the movement of the capping machine so that the apparatus 10 is commanded in a coordinated manner at least with the feed line 103 of the caps 102, and with the transport line 109 of the containers 101. In a preferred embodiment, the control and management unit 45 is located inside the collector 37.

We will now describe in detail the functioning of the capping machine 100 according to the present invention, with particular reference to the sequence shown in figs. 9A-9D. In the following description, we refer, by way of example, to the transport unit 12A, but it is clear that the operating sequence of the functioning of all the other transport units 12B-12H is completely analogous.

The caps 102, individually fed on the feed line 103, reach the pick-up position P 1 distanced by a distance D from each other which is correlated to the geometry and location of the apparatus 10, in particular to the disposition on it of the transport units 12 and the conformation of the latter.

Before reaching the pick-up position PI, the optical detection device 108 has detected the relative position of the cap 102 with respect to the transport unit 12 which will have to pick it up, as shown in fig. 3 A, where both the cap 102 under the optical detection device 108, and the transport unit 12 that will have to pick it up have been highlighted with a dotted pattern.

At this point, the control and management unit 45 makes an estimate of the positions where the cap 102, and the transport unit 12 which will have to pick it up, will be located at the time it is picked up, taking into consideration their trajectory and the respective speeds of displacement.

In this way, comparing this estimate with the expected pick-up position PI, the control and management unit 45 is able to calculate in advance any relative deviations, in the directions of the two orthogonal axes indicated by the arrows Al, A2 in fig. 3 A, which would lead to a misalignment between the cap 102 to be picked up and the corresponding transport unit 12 in correspondence with the pick-up position PI .

According to some embodiments, the control and management unit 45 is configured to command in feedback the transport units 12 and the feed line 103 of the caps 102 in order to determine their reciprocal alignment in the pick-up position PI . In particular, the control and management unit 45 first establishes the position that the transport unit 12 should have, determining where it should be located (that is, on which intermediate circumference comprised between the retracted position R and the extended position E, that is, between the circumferences C MIN and C MAX , as explained previously with reference to figs. 3 and 4) to intersect the direction of feed X of the caps 102 in the pick-up position PI, and subsequently - knowing at what moment the transport unit 12 will arrive at the pick-up point PI - commands the motor members which drive the feed line 103 of the caps 102, possibly slowing down or speeding up the latter appropriately, so that the cap 102 reaches the pick-up position PI substantially at the same time as the respective transport unit 12 reaches it.

According to some embodiments, the optical detection device 108 also detects the angular orientation of the cap 102, so that on the basis of the detected orientation, the control and management unit 45 commands the actuator 34 to possibly rotate the gripping head 30 around the axis of longitudinal development T of the transport unit 12A which is reaching the pick-up position PI (fig. 9 A), so that the seating 31 has the same orientation as the cap 102 to be picked up.

Subsequently, when the transport unit 12A has reached the pick-up position PI, it is in a vertically aligned condition, that is, disposed above the cap 102 to be picked up, thanks to the combined actuation, by the control and command unit, of the transport units 12 with that of the feed line 103 of the caps 102, as explained above (fig. 9B).

It should be noted that in the pick-up position PI, the actuator 34 has also translated vertically downward, along the axis of longitudinal development T, the gripping head 30 of the transport unit 12 A, by a quantity such as to allow the gripping head 30 to reach the cap 102 disposed on the conveyor belt 104.

Subsequently, the actuator 34 translates, vertically upward along the axis of longitudinal development T, the gripping head 30, which is holding the cap 102, shown in fig. 9C in an intermediate position along the path between the pick-up position PI and the delivery point P2 of the cap. At this time, the holding member 32 engages with the cap 102 so as to hold it inside the seating 31.

Furthermore, in the position shown in fig. 9C, it is provided that the actuator 34 rotates the gripping head 30 to ensure that the seating 31 in which the cap 102 is held is correctly oriented with respect to the position of the respective container 101, on which the cap must be deposited in the delivery position P2.

In the delivery position P2 (fig. 9D) the gripping head 30 translates vertically downward, with a movement similar to that described above with reference to the pick-up position PI of the cap 102.

In the delivery position P2 the transport unit 12A deposits the cap 102 on the respective container 101, and keeps it pressed on it for a determinate period of time, during which the actuator 34 allows the gripping head 30 to exert an adequate downward thrust force.

After depositing the cap 102, the transport unit 12A translates vertically upward along the axis of longitudinal development T and continues its rotation movement around the main axis of rotation Z, without the cap 102, until it returns to the pick-up position PI, in order to pick up another cap 102 and then repeat the operating cycle described above.

It should be noted that, in each fig. 9A-9D, a transport unit 12 is shown which is picking up a cap 102 in the pick-up position PI which is comprised in a group of transport units connected to a movement group 13, 14, while simultaneously another transport unit 12 which is comprised in another group of transport units connected to a different movement group 14, 13, is delivering a cap 102 above a container 101 in the delivery position P2. For example, in figs. 9A, 9B, 9C and 9D the transport units 12B-12E, 12A-12D, 12H-12C and 12F-12A are respectively picking up and delivering a cap 102.

In this way, the position of the transport unit 12 which is picking up the cap 102 from the feed line 103 is released from the position of the transport unit 12 which is delivering the cap 102 on the transport line 109 of the containers 101, being able to be disposed with great flexibility respectively in correspondence with the pick-up position PI and delivery position P2, by suitably actuating the different movement groups 13, 14.

It should also be noted that the capping machine 100 is able to effectively manage malfunctions, such as for example the case where the cap 102 to be picked up on the feed line 103 is missing, or a container 101 from the respective assembly 110 is missing. In these cases, the control and management unit 45 of the capping machine 100 will command the apparatus 10 in a manner coordinated with the lines 103, 109, for example by not having the cap 102 picked up from the transport unit 12 which should be deposited on the missing container, or by holding the cap 102 picked up for a complete cycle and then depositing it when, in the next cycle, the transport unit 12 reaches the delivery point P2 again. In other cases again, it can be provided to modify the speed of feed of the transport line 109, and therefore the position of the delivery point P2 when a cap is missing. In fact, thanks to the movement group 13, 14, the transport unit 12 can“follow” for a certain segment of the transport line 109 the container 101 on which the cap 102 has to be deposited, with the delivery position P2 translating downstream, but always disposed between the retracted position R and the extended position E.

It is clear that modifications and/or additions of parts may be made to the capping machine 100 and to the corresponding method as described heretofore, without departing from the field and scope of the present invention.

It is also clear that, although the present invention has been described with reference to some specific examples, a person of skill in the art shall certainly be able to achieve many other equivalent forms of machines and/or method for automatically capping containers, having the characteristics as set forth in the claims and hence all coming within the field of protection defined thereby.