Patent Description:
In particular, the invention fits into the technical field of linear motors and of how these, coupled with conveyor machines, enable the treatment and handling of objects or containers along the production line. In detail, the invention relates to the mechanism used to pump or suction a pre-established amount of air towards or from a container to be treated and/or handled.

The invention further relates to a method for treating and/or handling objects, in particular containers.

At present, the majority of conveyor machines used to operate on containers are of the rotary carousel type. The carousel has, on the periphery thereof, predefined support stations (commonly defined by a "plate") on which the containers to be treated are positioned. In particular, the carousel has a central rotation axis and for the plates has respective rotation axes parallel to the central axis. Therefore, each plate is rotatable about itself so as to set a respective container into rotation and enable the orientation and processing thereof, such as, for example, labelling.

If empty containers having flexible walls, such as, for example, cardboard or plastic containers, have to be labelled, a pre-established amount of air is usually blown inside them to impart to the structure a rigidity such as to withstand the surface pressure applied by the labeller during the processing, which can cause breakage or permanent deformation. For this purpose, it is necessary to set the air into rotation so that it arrives at each container.

Therefore, each rotary carousel is usually equipped with a rotary air distributor capable of blowing the necessary amount of air into every container. In detail, the rotary distributor is a complex system of tubes comprising a central conduit configured so as to radially distribute a pre-established flow of air to every branch, and thus to every plate and container.

<CIT> and <CIT> disclose a machine for treating and/or handling containers, comprising rotary carousels for displacing the containers, and an operating element extending from the carousel towards the object to be treated and/or handled and at least in part arranged in fluid connection with pumping and/ or suction means so as to act on a specific portion of said object to be treated and/ or handled through said compressed or suctioned fluid, said operating element having an active surface shaped to be able to interact with the specific portion of the object to be treated and/or handled, in particular a mouth of the container, and having a through opening facing towards the object to be treated and/or handled so as to define a fluid connection between said pumping and/or suction means and the object to be treated and/or handled. These documents also disclose a corresponding method.

However, nowadays there is a known practice of exploiting container conveyor systems that use a linear motor structure, wherein a plate is seated on a respective mobile carriage along a guide that can have a variety of forms (usually oval) and is powered by an electric current.

It is clear that the application of a rotary distributor for distributing air to the linear motor structure, rather than to rotary carousels, has greater complexity.

In fact, on linear motor conveyors, each carriage is configured to move totally independently of the others, in reference both to reciprocal distance and speed, making difficult any connection with possible connection tubes and the alignment thereof with the openings of the main connector.

In addition, the linear motor structure, having an extension according to a variety of shapes (e.g. oval), rather than circular, would require each carriage to be connected to the rotary air distributor, where present, with extendible tubes, since every point of the oval path would have a different distance from the point of origin of the main air flow.

<CIT> discloses a machine for treating and/or handling objects, in particular containers, said machine comprising a guide extending along an advancement direction of the objects; a main carriage slidably mounted on said guide so as to define together a main linear motor; at least one auxiliary carriage slidably mounted on said guide so as to define together an auxiliary linear motor; and a control unit connected to said guide and configured to manage the sliding of said main carriage and said auxiliary carriage along said guide and the reciprocal distance thereof. This document also discloses a corresponding method.

In this context, the technical task at the basis of the present invention is to propose a machine for treating and/or handling objects that overcomes the above-mentioned drawbacks of the prior art.

In particular, an object of the present invention is to provide a machine for treating and/or handling objects, in particular containers, which enables air to be pumped or suctioned at the carriages carrying the containers in a simple and effective manner.

Even more in particular, it is an object of the present invention to provide a machine for treating and/or handling objects wherein, on each carriage, for every respective container, it is possible to convey a sufficient amount of air necessary to stiffen the structure of the container during labelling operations or the like.

Another object of the present invention is to provide a machine for treating and/or handling objects wherein the conveyance of a flow of air can be used both to carry out treatments and perform handling operations on the objects present, in particular containers.

The stated technical task and the specified objects are substantially achieved by a machine for treating and/or handling objects and the relative method, which comprise the technical features disclosed in the independent claims. The dependent claims correspond to further advantageous aspects of the invention.

It should be highlighted that this summary introduces, in simplified form, a selection of concepts that will be further elaborated in the detailed description given below.

The invention relates to a machine for treating and/or handling objects, in particular containers. The machine comprises a guide extending along an advancement direction of the objects, a main carriage and an auxiliary carriage, both slidably mounted on the guide so as to define respective linear motors, and a control unit connected to the guide and configured to manage the sliding of the main carriage and the auxiliary carriage and the reciprocal distance thereof. In addition, the machine comprises a fluid pumping and/or suction member interposed between the main carriage and the auxiliary carriage so as to compress or suction a fluid as a function of the variation of the reciprocal distance between the main carriage and the auxiliary carriage. Finally, the machine comprises an operating element connected to the pumping and/or suction member which extends towards the object to be treated and/or handled so as to act on the latter by means of the compressed or suctioned fluid. In particular, the operating element extending from the main carriage towards the object to be treated and/or handled is at least in part arranged in fluid connection with the pumping and/or suction member so as to act on a specific portion of the object to be treated and/or handled through the compressed or suctioned fluid.

Advantageously, managing the reciprocal distance between the main carriage and the auxiliary carriage (increasing it, decreasing it or keeping it unvaried) enables the pumping and/or suction member to be managed and thus makes it possible to control the emission or intake of a pre-established amount of fluid by that member. In this manner, therefore, exploiting the interaction between the main carriage and the auxiliary carriage overcomes the necessity of having to install for every carriage a specific pipe indispensable for conveying the amount of fluid necessary to treat and/or handle the object being processed.

The blowing of air through the operating element by the pumping and/or suction member preferably takes place for the treatment of deformable empty containers.

The present patent application further relates a method for treating and/or handling objects, in particular containers.

Additional features and advantages of the present invention will become more apparent from the approximate, and thus non-limiting, description of a preferred but non-exclusive embodiment of a machine for treating and/or handling objects, in particular containers, as illustrated in the accompanying drawings, in which:.

With reference to the drawings, they serve solely to illustrate embodiments of the invention with the aim of better clarifying, in combination with the description, the inventive principles at the basis of the invention.

The present invention relates to a machine for treating and/or handling objects, in particular containers.

With reference to the figures, a machine for treating and/or handling objects has been generically indicated with the number <NUM>.

The other numerical references refer to technical features of the invention which, barring indications otherwise or evident structural incompatibilities, the person skilled in the art will know how to apply to all the variant embodiments described.

Any modifications or variants which, in the light of the description, are evident to the person skilled in the art, must be considered to fall within the scope of protection established by the present invention, according to considerations of technical equivalence.

A machine <NUM> for treating and/or handling objects, in particular containers, comprises at least one guide <NUM> extending along an advancement direction A of the objects, at least one main carriage <NUM> and at least one auxiliary carriage <NUM>, both slidably mounted on the guide <NUM> so as to define respective linear motors. Advantageously, the reciprocal distance between the main carriage <NUM> and the auxiliary carriage <NUM> is variable on command.

A first preferred embodiment of the invention envisages that the machine <NUM> comprises a first guide (e.g. lower) for the conveyance of the object to be treated and/or handled and a second guide (e.g. upper) for the movement of the components necessary for treating and/or handling the object according to the movement of the latter.

A second embodiment of the invention, by contrast, envisages that the machine <NUM> comprises a single guide configured both for the movement of the object to be treated and/or handled and for the treatment and/or handling of the latter.

For example, in the case of "bottom handling", used mainly in conveyors for containers, the sliding carriages are configured to support the object to be treated and/or handled from the bottom and to carry out the pre-established processing by means of the specific components installed on the carriages themselves. The activation of the pumping means (described below) takes place by nearing/distancing the same lower carriages.

Alternatively, for example, in the case of "neck handling" by conveyors, the sliding carriages comprise the components necessary for treating and/or handling the object and which are configured to support it from the top, by the "neck", in order to move it in addition to carrying out the specific processing. The activation of the pumping means (described below) takes place by nearing/distancing the same upper carriages.

<FIG> illustrates the first embodiment of the invention, wherein the machine <NUM> comprises an upper guide (the guide <NUM> introduced previously) and a lower guide along which a plurality of supporting carriages is slidably mounted, each of which is provided with a plate on which an object to be treated and/or handled (not illustrated), preferably a container, is positioned. The upper guide and lower guide preferably have, at least along a section for processing the containers, the same direction of extension so that a first carriage of the upper guide (the already mentioned main carriage <NUM>) is able to follow, in a mirror-like fashion, the movement of a specific supporting carriage on the lower guide. In this manner, at every section of the guide, it is possible to enable the interaction between a functional device installed on the carriage of the upper guide and the object to be treated and/or handled, which is positioned on the supporting carriage of the lower guide.

As may be better seen in <FIG>, a second carriage of the upper guide (the above-mentioned auxiliary carriage <NUM>) follows or precedes the first carriage along the upper guide moving away from or nearer to it so that an actuator, which is connected to the aforesaid functional device and positioned between the carriages of the upper guide, activates the operation of the functional device to enable the interaction with the object to be treated and/or handled positioned on the supporting carriage of the lower guide. Consequently, the variation of the distance of the auxiliary carriage relative to the main carriage activates the actuator capable of acting on the functional device. The auxiliary carriage is preferably not configured to carry or act on a further container, but is only at the service of the main carriage. In other words, the auxiliary carriage is not in turn equipped with a further functional device activated by a further actuator installed on another auxiliary carriage.

According to the present invention, the actuator is a pumping and/or suction member <NUM> for pumping and/or suctioning a fluid (preferably air), which is interposed between the main carriage <NUM> and the auxiliary carriage <NUM> and compresses or suctions the fluid as a function of the variation of the reciprocal distance between the main carriage <NUM> and the auxiliary carriage <NUM>, whereas the functional device is an operating element <NUM> extending towards the object to be treated and/or handled so as to act on the latter through the compressed or suctioned fluid and is at least in part arranged in fluid connection with the pumping and/or suction member <NUM>.

Hereinafter in the present description, reference will be made to ambient air as the preferred type of fluid used.

<FIG> illustrates some details of a possible embodiment of the invention, according to which the pumping and/or suction member <NUM> comprises a cylinder <NUM> and a piston <NUM> inserted inside the cylinder <NUM> and slidable therein as a function of the variation of the reciprocal distance between the main carriage <NUM> and the auxiliary carriage <NUM>.

The cylinder <NUM> is preferably connected to the main carriage <NUM>, whereas the piston <NUM> is connected to the auxiliary carriage <NUM>. Alternatively, it is possible to invert the aforesaid connection of the cylinder <NUM> and the piston <NUM> to the carriages or it is possible to use an equivalent device which is thus configured to transform the translational motion of nearing or distancing between the carriages into a compression or suction of air.

<FIG>, <FIG> illustrate a possible embodiment of the operating element <NUM>, which comprises a rod-shaped body <NUM> extending from a shelf of the main carriage <NUM> along a substantially vertical direction towards a terminal <NUM> thereof projecting towards the object to be treated and/or handled.

The terminal <NUM> of the operating element <NUM> has an active surface <NUM> shaped so as to interact with a specific portion of the object to be treated and/or handled, such as, for example, a mouth of a container. In addition, the active surface <NUM> has a through opening <NUM>, preferably central, facing towards the object to be treated and/or handled, and thus substantially disposed along the vertical direction, so as to define a fluid connection between the pumping and/or suction member <NUM> and the object to be treated and/or handled. Consequently, as may also be seen in <FIG>,<FIG>, extending between the pumping and/or suction member <NUM> and the operating element <NUM> there is a conduit <NUM> connected to the cylinder <NUM> and to the through opening <NUM> of the terminal <NUM>.

The operating element <NUM> preferably comprises a valve element (not visible in the appended figures) arranged at the through opening <NUM>. The valve element can be configured between a condition that is free to the passage of air and an obstruction condition that obstructs the passage of the air as a function of the presence of interaction between the active surface <NUM> and the specific portion of the object to be treated and/or handled. In other words, when the operating element <NUM> enters into contact with the object to be treated and/or handled, the valve element, which is normally abutted in the obstruction condition, is configured in the condition that is free to the passage of air to enable the performance of the treatment and/or the handling of the object.

If the valve element is present, or in general in other cases, the operating element <NUM> comprises an accumulation area <NUM> such as to contain the air compressed by the pumping and/or suction member <NUM> when the valve element is in the condition that obstructs the passage of said fluid. The accumulation area <NUM> can be defined by the conduit <NUM> or by other conduits connected to the member <NUM>.

In other words, in the obstruction condition the valve element enables the pumping and/or suction member <NUM> to compress the air before the operating element <NUM> interacts with the object to be treated and/or handled. In this operating condition, therefore, the main carriage <NUM> and the auxiliary carriage <NUM> reduce the reciprocal distance thereof so that the pumping and/or suction member <NUM> compresses the necessary amount of air in the accumulation area <NUM>, since the valve element is in an obstruction position. Subsequently, when the operating element <NUM> enters into contact with the object to be treated and/or handled, the valve element is abutted in the free condition, in which it allows the passage of the compressed air towards the object to be treated and/or handled.

Preferably, independently of the presence of the accumulation area <NUM> and mainly as regards the blowing of air into a container, the operating element <NUM> or the pumping and/or suction member <NUM> comprises a further valve element, more precisely a non-return valve, so as to be able to carry out several consecutive pumping/suction movements in order to increase the pressure of the accumulated air. In particular, the nearing between the auxiliary carriage <NUM> and the main carriage <NUM> takes place several times so as to reach the correct level of pressure of the air to blow towards the inside of the container. In other words, thanks to the non-return valve, the piston <NUM> can be moved forward and backward relative to the cylinder <NUM> so as to blow an additional amount of air each time and consequently increase the pressure inside the initially empty container so as to impart rigidity to the normally deformable structure.

In practical terms, the nearing of the auxiliary carriage <NUM> to the main carriage <NUM> determines a first blowing of air into the container, whereas a distancing of the two carriages determines the suction of ambient air (and not air from the container) by the pumping and/or suction member <NUM>, which is subsequently able to blow the suctioned ambient air into the container in addition to the previous air so as to increase the internal pressure thereof. Advantageously, the operating element <NUM> or the pumping and/or suction member <NUM> comprising the non-return valve can also be used in the event that the air has to be suctioned from a container (rather than compressed), so as to near/distance the carriages to/from each other several times and increase the total suction of the air from the object to be treated and/or handled.

The operating element <NUM> is preferably movable between a distanced interaction position, wherein the active surface <NUM> is arranged at a distance from the main carriage <NUM> and at the object to be treated and/or handled so as to act on the latter through the compressed or suctioned fluid, and a neared position, wherein the active surface <NUM> is arranged nearer to the main carriage <NUM> with respect to the distanced interaction position.

In other words, the terminal <NUM> and the rod-shaped body <NUM>, solidly joined to each other, are capable of translating along the vertical direction so as to bring the terminal <NUM> and therefore the active surface <NUM> near to or at a distance from the object to be treated and/or handled.

Alternatively, only the rod-shaped body <NUM> is solidly joined to the main carriage <NUM>, whereas the terminal <NUM> is slidable along the rod-shaped body <NUM> between the two aforesaid operating positions.

In both cases, the movement can be induced by a suitably shaped path (cam profile) that is present parallel to the guide <NUM>, with which it is able to interact with at least part of the operating element <NUM>, an appendage thereof, for example, so as to determine the vertical translation. Otherwise, the movement can be induced by an elastic element (not illustrated, for example a spring) interposed between the terminal <NUM> and the main carriage <NUM>, in particular between the terminal <NUM> and the shelf of the main carriage <NUM> to which the rod-shaped body <NUM> is connected.

As an alternative to using an elastic element or shaped path, it is possible to install a further auxiliary carriage <NUM> along the guide <NUM>, preferably in a position opposite the other auxiliary carriage <NUM> relative to the main carriage <NUM>. Interposed between the main carriage <NUM> and the further auxiliary carriage <NUM> there is a connection element <NUM> capable of moving the operating element <NUM> along the vertical direction V as a function of the variation of the distance between the main carriage <NUM> and the further auxiliary carriage <NUM>.

According to a first embodiment of the invention illustrated in <FIG> and <FIG>, the active surface <NUM> is counter-shaped with respect to the mouth of the container so as to convey the air compressed by the pumping and/or suction member <NUM> into the latter when the operating element is abutted in the distanced interaction position.

The active surface <NUM> preferably has a substantially convex or conical shape so as to be at least partially inserted into the mouth of the container and prevent the compressed air inside it from leaking out before the processing has ended.

In a second aspect of the invention (not illustrated), the active surface <NUM> is shaped so as to abut against the portion of the object to be treated and/or handled, since the pumping and/or suction member <NUM> is configured to maintain the suction of air also following the passage from the distanced interaction position to the neared position.

The active surface <NUM> preferably has a substantially suction cup-like or concave conformation, so that the pumping and/or suction member <NUM> suctions the air comprised between the active surface <NUM> and the portion of the object against which it is abutted so as to form a negative pressure such as to join them solidly to each other. Advantageously, it is thus possible to use the operating element <NUM> to carry out pick-and-place operations. The object to be treated and/or handled, once joined to the operating element <NUM> (picking step), can subsequently be moved elsewhere in space (placing step) according to different directions of movement, such as vertical, horizontal or any combination between the two.

In the first step, the operating element <NUM> is in the distanced interaction position when the pumping and/or suction member <NUM>, by suctioning air thanks to the distancing of the auxiliary carriage <NUM> from the main carriage <NUM>, generates a negative pressure that forms the suction cup effect.

In the second step, by contrast, while the operating element <NUM> is moved into the neared position, the pumping and/or suction member <NUM> maintains the suction of air so as to retain the object to be treated and/or handled connected to the terminal <NUM>. In this second step, the main carriage <NUM> and the auxiliary carriage <NUM> can keep the reciprocal distance constant so as to maintain sufficient negative pressure to prevent the detachment of the object to be treated and/or handled, or they can continue to be distanced from each other so as to induce continuous suction.

<FIG> illustrates the second embodiment of the machine <NUM>, wherein a sole guide <NUM> is present (but there could also be more than one) for the sliding of the carriages, mainly for the performance of pick-and-place operations.

For this type of operation, the machine <NUM> is facing towards a transfer member <NUM> (preferably a star wheel) for transferring the objects to be treated and/or handled, which is positioned alongside the guide <NUM> along which the carriages slide for processing and conveyance. Said transfer member <NUM> is preferably defined by a linear motor handling system.

Consequently, the operating element <NUM>, and thus the active surface <NUM>, are able to translate not only along a vertical direction, but also along a horizontal direction parallel to the guide <NUM> so as to interact with the objects to be treated and/or handled present on the transfer member <NUM>. Advantageously, the horizontal translation can take place thanks to a cam element, rather than by means of a further auxiliary carriage <NUM>.

Even more advantageously, if the operating element <NUM> comprises the valve element, the picking and placing of the object to be treated and/or handled can be managed both by moving the piston <NUM> following the reciprocal movement between the carriages, and by opening and closing the valve element.

In practical terms, when the operating element <NUM> extends horizontally to enter towards the object to be treated and/or handled so that it enters into contact with the active surface <NUM>, the valve element is abutted in the condition that is free to the passage of the flow of air so as to determine the suction cup effect and carry out the picking operation. When the operating element <NUM> is horizontally retracted, by contrast, the valve element is abutted in the obstruction condition so as to maintain the suction cup effect between the active surface <NUM> and the object to be treated and/or handled, moving it from the transfer member <NUM> to the guide <NUM>.

It should be noted that the operating element <NUM> is movable horizontally (or according to a composition of horizontal and vertical movements) with a variable stroke so as to adjust the picking distance of a container. In this regard, <FIG> illustrates a variant embodiment of the machine <NUM> illustrated in <FIG>, wherein the guide <NUM> and the carriages <NUM> and <NUM> together define the transfer member <NUM> (or transfer star wheel).

<FIG> also represents a conveyor belt <NUM> (having a generally linear extension) configured to convey the objects to be treated and/or handled towards the transfer member <NUM>, which is in turn configured to pick up the objects and position them on the guide <NUM> of the machine <NUM>, generally a main conveyor.

The distance that exists between a container loaded on the conveyor belt <NUM> and the picking members of the transfer member <NUM> can be different from the distance that exists between a container loaded on the transfer member <NUM> and the main conveyor. The difference in distance can be due to the different size of the container to be treated (which may be smaller or larger).

Consequently, the variation in the horizontal movement of the operating element <NUM> (which may be more or less distanced from the main carriage <NUM>) makes it possible to compensate for the aforesaid difference in distance.

In other words, the operating element <NUM>, being movable along the horizontal direction between the distanced interaction position and the neared position, is capable of picking up and releasing the object to be treated and/or handled, compensating for the above-mentioned difference in distance, and thus extending to a greater or lesser degree according to requirements. Generally, moreover, the transfer between the transfer member <NUM> and the guide <NUM> takes place between the respective curved sections of the circuit, where it would be difficult to retain a container of a non-cylindrical shape by means, for example, of two carriages with retaining half-grippers, due to a size discrepancy.

Therefore, the picking of the operating element <NUM> by suction enables these problems to be solved as well, given that the retention of the container takes place by suction, not through the reciprocal nearing of the carriages. With reference to <FIG>, between the transfer member <NUM> and the conveyor belt <NUM>, a picking step takes place, wherein the objects to be treated and/or handled are picked up from the conveyor belt <NUM> (the picking step, wherein the operating element <NUM> is in the distanced interaction position) so as to be moved along the transfer member <NUM> towards the guide <NUM> (the first part of the placing step, wherein the object is maintained solidly joined to the active surface <NUM> of the operating element <NUM> in the neared position).

Between the transfer member <NUM> and the guide <NUM>, therefore, a transfer step takes place (the second part of the placing step), wherein the object to be treated is transferred from the transfer member <NUM> to the guide <NUM> when the respective curved sections of the two circuits are facing each other. From an operational viewpoint, the operating element <NUM> is extended once again in the distanced interaction position along the horizontal direction so that the object constrained to the active surface <NUM> is above the respective conveyor carriage slidable along the guide <NUM>. In this configuration, the solid connection with the object is interrupted (by means of a specific cam element, or the combined action of the pumping and/or suction member <NUM> with the valve element and/or the reciprocal variation between the main carriage and the auxiliary carriage slidable along the transfer member <NUM>) so that the latter can be positioned on the respective carriage and moved along the guide <NUM>.

According to one aspect of the invention, as illustrated in <FIG>, the machine <NUM> comprises a control unit <NUM> connected to the guide <NUM> and configured to manage the sliding of the main carriage <NUM> and the auxiliary carriage <NUM> along the guide <NUM> and the reciprocal distance thereof.

The control unit <NUM> is configured to reduce the reciprocal distance between the main carriage <NUM> and the auxiliary carriage <NUM> in the event that it is necessary to compress the air towards the object to be treated and/or handled, or it is configured to increase the reciprocal distance between the main carriage <NUM> and the auxiliary carriage <NUM> so as to suction the air from the object to be treated and/or handled. In addition, the control unit <NUM> is configured to keep the reciprocal distance between the main carriage <NUM> and the auxiliary carriage <NUM> constant so as to keep the compressed or suctioned air unvaried, i.e. to keep constant the pressure (or negative pressure) of the air emitted or suctioned by the pumping and/or suction member <NUM>.

The control unit <NUM> is preferably configured to manage the sliding speed of each carriage along the guide <NUM> and also to manage the speed of relative movement between the carriages during the distancing and reciprocal nearing thereof.

Controlling the relative speed between the carriages is equivalent to controlling the pushing force that one carriage (generally the auxiliary one <NUM>) exerts on the other (generally the main one <NUM>). Consequently, in this manner, the control unit <NUM> is also capable of managing the pressure inside the container, as it is proportional to the pushing force between the carriages.

In other words, the control unit <NUM> is configured to control the pushing force of one carriage (generally the auxiliary one <NUM>) on the other (generally the main one <NUM>) through the electric control circuit of the linear motors defined by the stator and by the carriages themselves.

It is preferably possible to connect the control unit <NUM> to the valve element, if present, so as to vary the configuration thereof between the free condition and the condition of obstruction to the passage of the compressed or suctioned air.

Advantageously, therefore, the control unit <NUM> is configured to vary the reciprocal distance between the main carriage <NUM> and the auxiliary carriage <NUM> and to configure the valve element, if present, accordingly, prior to or simultaneously to any processing that needs to be carried out on the object to be treated and/or handled.

The machine <NUM> is preferably used to convey containers along a production line in which it is possible to install various operating units <NUM> capable of carrying out different processes, such as, for example, the labeller illustrated in <FIG>.

As regards an example of operation of the machine <NUM>, it derives directly from what was described above and is reiterated here below.

A method for treating and handling objects, in particular containers, carried out by an operator comprises the operating steps of:.

After the above-mentioned components have been provided, the operator will be able to:.

By varying the distance between the main carriage <NUM> and the auxiliary carriage <NUM>, the operator will be able to act on the pumping and/or suction member <NUM> so as to compress or suction a pre-established amount of air. The operating element <NUM> connected to the pumping and/or suction member <NUM> is advantageously shaped so as to convey said amount of compressed or suctioned air towards or from the object to be treated and/or handled.

If the operator prepares an operating unit <NUM> adapted to follow a specific process on the object, the operator can advantageously set the variation of the reciprocal distance between the carriages, and thus the compression or suction of air, so as to take place simultaneously to the process performed on the object by the operating unit <NUM>.

In fact, if the machine <NUM> comprises a labeller and is used to convey containers, it is advantageous to blow compressed air into them so as to stiffen the structure of the container during processing and prevent the labelling from deforming the structure of the container itself due to the pressure of applying the label.

If the operating element <NUM> comprises a valve element at the through opening <NUM> and in the obstruction condition, the operator will advantageously be able to determine a variation of the reciprocal distance between the carriages before the processing takes place, not necessarily during, and even before the operating element <NUM> is moved into the distanced interaction position. The compressed air is in fact stored in the accumulation area <NUM> of the operating element <NUM>, which conveys it into the container only when the valve element is configured in the condition that is free to the passage of air following the movement of the operating element <NUM> into the distanced position of interaction with the object to be treated and/or handled.

Otherwise, the machine <NUM> can be used to perform functions of the pick-and-place type, wherein the operating element <NUM> interacts with the object to be treated and/or handled so as to move it in space and into the place of interest.

In fact, the distancing of the main carriage <NUM> from the auxiliary carriage <NUM> determines the suction of a pre-established amount of air (as a function of how far the carriages are distanced from each other) by the pumping and/or suction member <NUM> so as to form a negative pressure between the terminal <NUM> of the operating element <NUM> and a specific portion of the object to be treated and/or handled, which are joined together by virtue of a suction cup effect that is established between them. This step, called the picking step, enables the operating element <NUM> to become bonded with the object to be treated and/or handled so as to be able to form a single body that is movable in space, because controllable by the operator.

Advantageously, if the operating element <NUM> comprises the valve element at the through opening <NUM> and in the obstruction condition, the operator will be able to bring about a variation of the reciprocal distance between the carriages for the picking step before the terminal is in contact with the object to be treated and/or handled, and thus before the operating element <NUM> is moved into the distanced interaction position.

Subsequently, in order to carry out the placing step, i.e. the movement of the object to be treated and/or handled, the latter must remain bonded to the terminal <NUM> and thus the suction of the pumping and/or suction member <NUM> must be kept constant. To this end, it is possible that the auxiliary carriage <NUM> and the main carriage <NUM>, already distanced from each other, maintain their distance so as to keep the established negative pressure constant, or it is possible to ensure that during the entire movement phase the reciprocal distance thereof continues to increase so as to obtain a continuous suction of air.

In this manner, during the placing step the object to be treated and/or handled remains connected to the terminal <NUM> so as to be moved freely in the operator's space.

Claim 1:
A machine (<NUM>) for treating and/or handling objects, in particular containers, comprising:
- a guide (<NUM>) extending along an advancement direction (A) of the objects;
- a main carriage (<NUM>) slidably mounted on said guide (<NUM>) so as to define together a main linear motor;
- at least one auxiliary carriage (<NUM>) slidably mounted on said guide (<NUM>) so as to define together an auxiliary linear motor;
- a control unit (<NUM>) connected to said guide (<NUM>) and configured to manage the sliding of said main carriage (<NUM>) and said auxiliary carriage (<NUM>) along said guide (<NUM>) and the reciprocal distance thereof;
characterised in that it comprises:
- a pumping and/or suction member (<NUM>) for pumping and/or suctioning a fluid interposed between said main carriage (<NUM>) and said auxiliary carriage (<NUM>) so as to compress or suction said fluid as a function of the variation of the reciprocal distance between said main carriage (<NUM>) and said auxiliary carriage (<NUM>);
- an operating element (<NUM>) extending from the main carriage (<NUM>) towards the object to be treated and/or handled and at least in part arranged in fluid connection with said pumping and/or suction member (<NUM>) so as to act on a specific portion of said object to be treated and/or handled through said compressed or suctioned fluid
; said operating element (<NUM>) having an active surface (<NUM>) shaped to be able to interact with the specific portion of the object to be treated and/or handled, in particular a mouth of the container; said active surface (<NUM>) having a through opening (<NUM>) facing towards the object to be treated and/or handled so as to define a fluid connection between said pumping and/or suction member (<NUM>) and the object to be treated and/or handled.