Patent Description:
In the pharmaceutical sector, the operations of processing and packaging pharmaceutical products such as, for example, powders, tablets, pills, or suchlike, are carried out inside a protected chamber separated from the external environment, generally called "isolator", which is kept in sterile conditions and in a controlled atmosphere.

Processing and/or packaging devices and equipment are disposed inside the protected chamber, connected with the outside by means of special entrances and exits provided with transfer ports that allow a protected transfer of material inside and outside the protected chamber, preventing a direct connection between the internal and external environment of the chamber itself. Such transfer ports, which are subject to certifications attesting their compliance with current regulations, are generally known as "Alpha-Beta" ports or also as "RTPs", an acronym for Rapid Transfer Ports.

The protected chamber is also normally equipped with handling devices that allow an operator to interact with the products and/or the equipment located inside it, such as gloves by means of which an operator can operate inside the protected chamber. The gloves are generally attached with a hermetic seal to a special hole provided on a wall of the protected chamber, from which they project toward the inside of the chamber.

In order to guarantee that the required sterility requirements are always met, the atmosphere of the protected chamber has to always be kept separate from that of the external environment and it is also provided to periodically carry out treatments, inside the protected chamber, with suitable chemical substances that have a bactericidal and fungicidal action. For example, one of the most popular treatments is the treatment cycle called VHP (Vaporized Hydrogen Peroxide), in which substances based on vaporized hydrogen peroxide are introduced into the protected chamber to carry out the sterilization cycles thereof. During these cycles, which are regulated by stringent regulations in order to guarantee the cleanliness and hygiene of the processing and packaging process of pharmaceutical products, the substances introduced into the chamber are deposited on the walls of the chamber itself and on every object, component or structure contained inside it in order to completely sterilize the protected chamber.

One disadvantage of the state of the art is that traces of the substances used in the sterilization cycles have been found in the pharmaceutical products treated and packaged in the protected chamber. This occurs because the pharmaceutical products come into contact with different elements disposed inside the protected chamber, such as the guides along which they advance, which have undergone the sterilization cycle and on which a certain quantity of the sterilizing substances used in such cycles has deposited. It is evident that this disadvantage is particularly undesirable and there is a need to prevent the user of the pharmaceutical product from also ingesting traces of sterilizing substances used in the sterilization cycles.

Another disadvantage of the state of the art is that, since the sterilizing substances used are often very chemically aggressive, over time they can corrode some elements or components placed inside the protected chamber. It is clear that this disadvantage is also particularly undesirable and there is a need to prevent the sterilizing substances used in the sterilization cycles from damaging elements or components positioned in the protected chamber, shortening their useful life, which makes it necessary to replace them prematurely, with a consequent increase in maintenance costs and times.

In order to overcome these disadvantages, systems to manage the protected chambers have been perfected, in which it is provided to dismantle all the components or elements intended to come into contact with the pharmaceutical products being processed before carrying out a sterilization cycle, so that they can then be reassembled in the respective positions at the end of the sterilization cycle.

One example of such systems is described in German patent application no. <CIT>, the system of which comprises a transport container for introducing/removing components into/from the protected chamber without breaching or interrupting its protected atmosphere. The transport container is disposed outside the protected chamber and is intended to be temporarily connected, in a removable manner, to the "Alpha-Beta" transfer ports, or RTP ports as above. An example of such RTP transfer ports is described by U. patent document no. <CIT>, in which a system is provided for sterilizing the door frames, as well as the closed space interposed between the doors themselves.

Furthermore, the system described by German patent application no. <CIT> provides that the operator handles by means of the gloves as above both the components introduced into the protected chamber by means of the transport container in order to assemble them in the intended position, for example after a sterilization cycle has been carried out, and also the components that have to be removed from the protected chamber in order to be replaced in the transport container, for example before carrying out the sterilization cycle.

One disadvantage of this solution known in the state of the art is that the gloves used, while they allow to operate inside the isolator in a manner separated from it, can constitute a mean for conveying contaminants inside the chamber. In fact, it can happen that during use holes or incisions form on the gloves through which contaminants can penetrate inside the protected chamber.

Furthermore, this solution can lead to safety problems for operators, for example in the event the gloves are damaged, and the operators come into contact with pharmaceutical products which can be dangerous, toxic and/or harmful to their health, or harmful to the surrounding environment.

Another disadvantage of this solution is that manual operations, performed with the gloves, are long and laborious since the gloves decrease the operator's tactile sensitivity.

Similar disadvantages also affect the solutions described in US patent application no. <CIT>, in which it is provided that the operator handles the devices for detecting bacterial loads disposed in the clean room from the outside, by using gloves associated with one of the walls of the chamber itself.

One purpose of the present invention is to provide an apparatus and a method for the automated management of a processing chamber with a controlled atmosphere which overcome at least one of the disadvantages of the solutions known in the state of the art.

One purpose of the present invention is to provide an apparatus and a method for the automated management of a processing chamber that do not require any manual intervention whatsoever by the operator through gloves.

Another purpose of the present invention is to provide an apparatus and a method for the automated management of a processing chamber which eliminate, or at least significantly reduce, possible problems of contamination of the processing chamber caused by contaminants conveyed from the outside, in particular through gloves.

Another purpose is to provide an apparatus and a method for the automated management of a processing chamber which allows to carry out assembly and disassembly operations of one or more components or elements placed inside the processing chamber in a rapid, simple and fully automatic manner.

The dependent claims describe other characteristics of the present invention.

Embodiments described here concern an apparatus for the automated management of the assembly of a machine for processing and/or packaging products in a processing chamber. According to some embodiments, the processing chamber, or clean room, is an isolated chamber with controlled atmosphere and delimited by walls, at least one of which is provided with at least one access aperture which can be closed by means of a primary closing unit.

In some embodiments, the apparatus comprises a processing system for processing the pharmaceutical products comprising at least one modular assemblable element, which can be removably coupled to other elements to obtain the processing system, which is housed in the processing chamber.

According to embodiments described here, the apparatus comprises a transport container, for example configured as a closed tubular body, configured to be associated with the access aperture, outside the processing chamber, and provided with a secondary closing unit able to cooperate with the primary closing unit so that they can be opened to put the inside of the processing chamber in communication with the inside of the transport container, at the same time keeping them isolated and separated from the external environment. The transport container is configured to contain one or more assemblable elements, modular, which have to be coupled to other elements to obtain the processing system as above. Typically, the assemblable elements have to be temporarily positioned inside the processing chamber, or temporarily removed from the same processing chamber.

According to a characteristic aspect of the present invention, the apparatus comprises a handling device housed in the processing chamber and comprising a mobile work tool, configured to alternately grip or release the assemblable element to respectively remove it from the transport container and assemble it in a predeterminate position in order to couple it to other elements so as to obtain the processing system as above and/or de-couple it from other elements with which it forms the processing system as above and return it to the transport container.

According to one embodiment provided here, the handling device comprises a plurality of articulated components pivoted together so as to rotate each with respect to the other around respective axes of rotation, since it is configured as a robotic automatic handler, for example configured as an anthropomorphic robot with at least six work axes, which is controlled by a control unit according to determinate instructions correlated to the management of the processing chamber.

According to some embodiments, the transport container comprises a support slider provided with one or more support planes intended to receive the assemblable elements resting on them.

In accordance with embodiments provided here, the transport container comprises guide means with which suitable sliding and guide means comprised in the support slider are engaged, so as to move the support slider between a retracted position, in which the support slider is contained inside the transport container, and an extracted position, in which the support slider is at least partly extracted from the transport container and protrudes into the processing chamber.

In embodiments described here, the assemblable elements, modular, as above are elements intended to come into contact with the objects being processed, that is, with the pharmaceutical products, such as for example a hopper, or a collection container, or transport elements. Such assemblable elements are conformed so that they can be reciprocally coupled and decoupled so that they can be quickly and easily disassembled from, and reassembled on, respective equipment or devices that support them. The disassembly and subsequent reassembly are carried out by means of the handling device comprised in the management apparatus according to the present invention, which for example can be configured as an articulated robot, in particular with six work axes.

According to one aspect of the present invention, a method is provided for the automated assembly of a machine for processing and/or packaging pharmaceutical products inside a clean processing room, delimited by walls, at least one of which is provided with at least one access aperture which can be selectively closed by means of a primary closing unit.

Characteristic aspects of the method according to the present invention provide the steps of:.

According to a characteristic aspect of the method according to the present invention, it is provided that the steps of opening, extracting and removing are carried out by means of a handling device housed in the clean room, wherein it is provided that the handling device grips the at least one modular assemblable element with a mobile work tool and provides to assemble the pharmaceutical products in a predeterminate position of the processing system.

According to embodiments of the method according to the present invention, it is provided that the step of removing the at least one assemblable element is carried out by means of a step of extracting a support slider from the transport container, in which the at least one modular assemblable element is housed, and subsequently by means of a step of extracting the at least one modular assemblable element from the support slider.

According to embodiments of the method according to the present invention, after the step of removing and assembling the at least one modular assemblable element, it is provided to reintroduce the support slider into the transport container by means of the handling device, and close the primary closing unit by means of the handling device.

In a preferred embodiment, also the step of extracting the support slider from the transport container, its subsequent reintroduction into it, and the steps of extracting the modular assemblable elements from the support slider, in addition to the subsequent step of repositioning the assemblable elements in the support slider are all carried out by the handling device.

According to another aspect of the present invention, a method is provided to prepare a machine for processing and/or packaging pharmaceutical products, wherein it is provided to manage the processing chamber in an automated manner according to the method described above for the automated management of the assembly of the processing system, and wherein inside the clean room it is provided to periodically carry out one or more sterilization cycles, using chemical substances that have bactericidal and fungicidal action, such as for example vaporized hydrogen peroxide. According to a characteristic aspect of the method to prepare such machine, the assemblable elements are disposed outside the processing chamber during the sterilization cycles, since they are taken outside and returned inside the clean room by means of the transport container as above.

Advantageously, thanks to the apparatus and the method for the automated management of the assembly of a machine for processing and/or packaging pharmaceutical products inside a processing chamber according to the present invention, it is possible to automatically assemble and disassemble the assemblable elements, modular, that make up the processing system as above, by means of the handling device preferably configured as an articulated robot.

One advantage of the present invention is that it prevents the operations of assembly and disassembly of the assemblable elements from having to be carried out manually by an operator by means of the gloves disposed on one of the walls of the processing chamber. This is advantageous because it eliminates, or significantly reduces, the risk of unwanted contaminations of the protected atmosphere of the processing chamber which can occur through the gloves, which can have slits or incisions through which germs or bacteria can enter the processing chamber.

Another advantage of the present invention is that it avoids long and laborious manual operations of assembly and disassembly of the assemblable elements for the operator, which can be inconvenient to carry out, and take a long time, thus causing long machine downtimes.

Yet another advantage of the present invention is making available a machine for processing and packaging pharmaceutical products, and a method to prepare it, which allow to introduce or extract the assemblable elements into/from the processing chamber in a completely automated manner, which determines the advantages described above.

We will now refer in detail to the various embodiments of the present invention, of which one or more examples are shown in the attached drawings. Each example is supplied by way of illustration of the invention and shall not be understood as a limitation thereof. For example, the characteristics shown or described insomuch as they are part of one embodiment can be adopted on, or in association with, other embodiments to produce another embodiment.

Embodiments described using the attached drawings concern an apparatus <NUM> for the automated management of the assembly of a machine for processing and/or packaging pharmaceutical products inside a processing chamber <NUM>, in the sector also called "isolator" or "clean room", of a machine for processing and/or packaging pharmaceutical products. The processing chamber <NUM> is a closed chamber, separate from the external environment and with a controlled atmosphere.

The apparatus <NUM> is suitable to be used in particular in the pharmaceutical sector to insert and position in the processing chamber <NUM> those assemblable elements <NUM> intended to come into contact with the products to be processed, and subsequently to remove such components from the processing chamber <NUM>.

The apparatus <NUM> comprises at least one handling device <NUM> positioned inside the processing chamber <NUM>, and a transport container <NUM> configured to transport one or more assemblable elements <NUM> inside and outside the processing chamber <NUM>, as will be explained in more detail below.

The processing chamber <NUM>, a portion of which can be seen in <FIG>, is separated from the external environment by walls <NUM> and is also provided with access apertures <NUM> associated with respective closing devices structured in such a way as to allow a protected transfer of material inside or outside the chamber <NUM>.

According to some embodiments, the closing devices can be rapid transfer ports (RTP), or "Alpha-Beta" ports, of a type known in the state of the art, provided with a primary closing unit <NUM>', also referred to as "Alpha unit", suitable to be coupled with a mating secondary closing unit <NUM>', also referred to as a "Beta unit", provided on a transfer device, for example the transport container <NUM>, by means of suitable reciprocal coupling interfaces.

The primary closing unit <NUM>' can be installed on the access aperture <NUM> inside the processing chamber <NUM>.

According to some embodiments, the primary closing unit <NUM>' comprises coupling means, comprising a flange <NUM> which surrounds the access aperture <NUM>, and a hatch 19a which closes the access aperture, provided with suitable sealing elements.

According to some embodiments, the hatch 19a of the primary closing unit <NUM>' can be hinged on one side to the flange <NUM> so as to rotate with respect to it between a closed condition and an open condition (<FIG>).

According to some embodiments, the primary <NUM>' and secondary closing unit <NUM>' can be conformed so that, once coupled to each other, the opening of the hatch 19a of the primary closing unit <NUM>' also determines the opening of the secondary closing unit <NUM>', so as to put the inside of the transport container <NUM> in communication with the inside of the processing chamber <NUM>, maintaining the respective internal environments, now communicating with each other, separate and isolated from the external environment.

In one embodiment, the handling device <NUM> is configured to open and close the hatch 19a, thus determining the opening and closing of the primary <NUM>' and secondary closing unit <NUM>' respectively.

According to some embodiments, the mobile transport container <NUM> is configured to contain at least one assemblable element <NUM> inside it so that it can transport it in a closed and sealed condition.

With the term "assemblable element" here and hereafter in the description we mean an element comprised in equipment, devices, systems or apparatuses disposed inside the processing chamber <NUM> which can be used alone, or in connection with other components or objects or parts of the machine. In particular, the assemblable elements <NUM> in question are preferably modular elements, that is, they can be assembled and disassembled with respect to the equipment, device, system or apparatus of which they are a part. Furthermore, it should be noted the assemblable elements <NUM> in question are preferably components intended to come into contact with the objects to be processed in the processing chamber <NUM>, that is, for example with the pharmaceutical products. By way of a non-limiting example, the assemblable elements <NUM>, when coupled together, can form a system for processing the pharmaceutical products, housed inside the processing chamber <NUM>.

According to some embodiments, the transport container <NUM> comprises a tubular body <NUM> closed at one end 22b and provided at the opposite end 22a with the secondary closing unit <NUM>' suitable to be hermetically coupled with the primary closing unit <NUM>' associated with the access aperture <NUM> provided on a wall <NUM> of the processing chamber <NUM>.

According to some embodiments, the transport container <NUM> comprises a support slider <NUM> provided with one or more support planes <NUM> intended to receive the assemblable element <NUM> resting on them. In one embodiment, the slider <NUM> can provide at least two support planes <NUM>, offset vertically, and that substantially have the shape of a parallelepiped.

The slider <NUM> is disposed sliding in the tubular body <NUM>. In a preferred embodiment, the slider <NUM> is sliding on linear guides (not shown) which can have a certain inclination which allows the slider to partly protrude outside the tubular body <NUM> to project inside the processing chamber <NUM>, as shown in figs. from <NUM> to <NUM>. In one embodiment, the linear guides provide an end-of-travel, located in a suitable position, such as to block the advancement of the slider <NUM> and thus prevent its complete exit from the tubular body <NUM>.

According to a variant embodiment, a drive unit is provided for moving the slider <NUM>, of a type known in the state of the art and not shown, which can comprise, for example, an electric motor. In this variant, the movement of the slider <NUM> along the linear guides which alternately allows it to be extracted from the tubular body <NUM> (so as to be extracted at least in part outside the latter), and subsequently to be reintroduced inside it, is obtained by means of the drive unit as above.

In another alternative embodiment, the slider <NUM> is moved by the handling device <NUM>, which extracts it from the tubular body <NUM> and reintroduces it therein. In this embodiment, the slider <NUM> can comprise suitable gripping means, for example conformed as a hook, a peg or a bracket, and intended to be grip by the handling device <NUM> during the extraction and the reintroduction of the slider <NUM>.

According to some embodiments described here, the handling device is configured as an articulated robot <NUM>, of a type known in the state of the art.

The articulated robot <NUM> comprises a plurality of articulated components <NUM> pivoted one to the other and is in particular suitable to be used in the sector of production and packaging of pharmaceutical products. That is to say, the articulated robot <NUM> can be used in isolated chambers which have to meet stringent sterility requirements to prevent possible contamination of the pharmaceutical products themselves, such as for example the processing chamber <NUM> of a so-called isolator.

To this end, the articulated robot <NUM> in question is suitable, in particular, to be subjected to appropriate decontamination and sterilization treatments, for example CIP and/or SIP treatments which provide the use Vapor Phase Hydrogen Peroxide (VPHP), which has a high oxidizing power with a bactericidal, sporicidal and fungicidal action, without oxidation of its external surface, or possible damage to the components themselves.

By way of example, the articulated robot <NUM>, shown enlarged in <FIG>, has five articulated components <NUM>, respectively indicated by the letters A, B, C, D, E, coupled in an articulated manner one after the other in correspondence with respective coupling interfaces <NUM>.

According to some embodiments, in correspondence with the coupling interfaces <NUM>, movement members, not shown, can be provided, configured to allow a relative rotation of the two respectively coupled articulated components <NUM> around a common axis of rotation.

It is not excluded, however, that the articulated robot <NUM> can have a smaller or greater number of articulated components <NUM>, depending on requirements.

According to some embodiments, each articulated component <NUM> is at least partly hollow and is internally provided with a housing compartment (not shown) configured to house the drive members, the electrical and electronic circuitry and/or the ducts for fluids required to move the articulated component <NUM> itself and to transmit power and data signals between the respective articulated components <NUM>.

In one embodiment, the succession of articulated components <NUM> comprises a base articulated component, indicated with the letter A in <FIG>, intended to be attached to a floor <NUM> of the processing chamber <NUM>, an end articulated component, indicated with the letter E in <FIG>, and a plurality of other articulated components interposed between them to define the kinematic chain that governs the movement of the handling device <NUM>, indicated with the letters B, C and D in <FIG>. The end articulated component E comprises an attachment portion <NUM> to which a work tool <NUM> is connected in a temporary and removable manner.

In the embodiment shown in <FIG>, the work tool <NUM> is conformed as a gripper comprising a first and a second gripping element 25a, 25b cooperating with each other to remove and release the assemblable element <NUM>.

The first and second gripping elements 25a, 25b are mobile with respect to each other to move reciprocally toward/away from each other, as indicated by the arrow F in <FIG>, in order to respectively grip and release the assemblable element <NUM>, and they can also rotate around the axis of rotation R.

Thanks to the fact that the work tool <NUM> is supported at the end of an articulated robot <NUM> formed by a plurality of articulated components <NUM> (five in the example described and shown in the attached drawings), it is able to be moved in space at will, since it is able to reach a sufficiently wide maneuvering space.

It is evident that according to alternative embodiments, all included within the field of protection of the present invention, the work tool <NUM> can be conformed differently from what is shown by way of example in <FIG>, but in many ways technically equivalent to it.

In one embodiment, the apparatus <NUM> can comprise two or more handling devices <NUM>, each for example being able to be configured as an articulated robot such as the one described above with reference to <FIG> and being placed in a suitable respective position inside the processing chamber <NUM>.

Inside the processing chamber <NUM>, there are provided a plurality of pieces of equipment, devices, systems or apparatuses configured to carry out respective processes on the pharmaceutical products.

By way of example, we refer to a processing system <NUM> of pharmaceutical products configured as a transport system for transporting the pharmaceutical products inside the processing chamber <NUM>. One portion of this processing system <NUM> can be seen in <FIG>, for the sole purpose of better clarifying the subsequent description of the functioning of the apparatus according to the present invention. Hereafter in the description, with reference number <NUM> we will refer specifically to the transport system, described purely by way of example with reference to the embodiments shown in <FIG>.

It is clear that the person of skill in the art will understand that the transport system <NUM>, which is not comprised in the apparatus <NUM> according to the present invention, can be made according to many other embodiments, all equivalent to the one described below with reference to <FIG>.

The transport system <NUM> can comprise a base <NUM> attached to the floor <NUM> of the processing chamber <NUM>.

According to some embodiments, the transport system <NUM> can be of the vibrating type. In this case, the transport system <NUM> can comprise one or more vibrator devices (not shown) suitable to properly make one or more elements of the transport system <NUM> vibrate, according to determinate frequencies, so as to determine the feed of the objects being transported. In some embodiment versions, such vibrator devices can be disposed inside the base <NUM>, or in any case associated with, and supported by, the latter.

The transport system <NUM> comprises a hopper <NUM> intended to receive a multitude of objects haphazardly, such objects possibly being pharmaceutical products such as for example pills, tablets or capsules. The transport system <NUM> also comprises a collection container <NUM>, into which the objects leaving the hopper <NUM> arrive. In one embodiment, the collection container <NUM> is disposed below the hopper <NUM>, in communication with an exit thereof, so that the objects contained in the hopper <NUM> can gradually fall by gravity into the collection container <NUM>. According to a version provided here, the collection container <NUM> has an inclined bottom <NUM> so as to allow the objects to advance by sliding.

The transport system <NUM> comprises a first transport element <NUM> and a second transport element <NUM> on which a plurality of tracks <NUM> are made, inside which the objects as above are fed. In one embodiment, the transport elements <NUM>, <NUM> are adjacent to each other so that the tracks <NUM> made in one are the direct continuation of the ones made in the other.

The transport system <NUM> comprises a support bench <NUM> intended to receive the transport elements <NUM>, <NUM> resting on it, in a stable and removable manner. The support bench <NUM> is supported by spacer elements <NUM>, for example configured as columns, to distance it from the base <NUM>.

According to some embodiments provided here, the transport elements <NUM>, <NUM> are supported by the support bench <NUM> by means of a mechanical coupling, for example by means of a same-shape coupling which can provide both a connection with play, and also with interference.

In the version shown by way of example in the drawings, the transport elements <NUM>, <NUM> comprise the plane on which the objects advance, in which the tracks <NUM> are made, and a base plane <NUM> which supports the advance plane, that is, the tracks <NUM>, by means of support columns <NUM>. In this version, the support bench <NUM> comprises one or more seatings <NUM>, in particular made as hollows on a lateral wall of the support bench <NUM>, for example on the wall facing the handling device <NUM>. In some embodiments, the seatings <NUM> are shaped as holes with a substantially cylindrical shape, sized so as to each house a respective support column <NUM>. In other words, since the seatings <NUM> are intended to each receive a support column <NUM>, the sizes and shape of the seatings <NUM> are correlated to those of the support columns <NUM>.

It should be noted that the first transport element <NUM> and the second transport element <NUM> constitute only some non-limiting example embodiments of the assemblable elements <NUM>. Other examples of assemblable components <NUM>, modular, are, with reference to the embodiment that can be seen in <FIG>, the hopper <NUM> and the collection container <NUM>.

According to some embodiments, the automated management apparatus <NUM> comprises a control and command unit <NUM> (<FIG>) configured to control and command the functioning of the automated management apparatus <NUM>, in particular to control and command the handling device or articulated robot <NUM>.

In accordance with embodiments provided here, the apparatus <NUM> comprises a recognition device which is configured to recognize the assemblable element <NUM> and send a corresponding recognition signal to the handling device <NUM>, in particular through the control and command unit <NUM>. In possible embodiments, the recognition device comprises at least one sensor configured to acquire images to recognize the assemblable element <NUM>. In the example shown in <FIG>, the recognition device is configured as a video camera, in particular of the high-resolution type commonly used in industrial automation applications, indicated with reference number <NUM>. The video camera <NUM> can for example be attached to one of the walls <NUM> of the chamber <NUM>, in a suitable position that allows it to have a field of vision over the entire processing system <NUM>.

According to possible embodiments, the recognition signal as above contains information relating to at least one of either the assembly position and/or assembly direction of the assemblable element <NUM>, modular, on the processing system <NUM>, and/or the gripping position of the assemblable element <NUM>, modular, by the handling device <NUM>.

In some embodiments, it is provided that the assemblable element <NUM> comprises an identification code for its recognition by the recognition device, of a known type and not shown. By way of a non-limiting example, such identification code can be configured as an RFID tag, a barcode, or any other alphanumeric code whatsoever.

With reference to the drawings, the functioning of the apparatus for the automated management of the processing chamber <NUM> is now described.

Initially, it is provided to attach the secondary closing unit <NUM>' made on a transport container <NUM> to a primary closing unit <NUM>' of the processing chamber <NUM> (<FIG>). The transport container <NUM> contains inside it an assemblable element <NUM> positioned resting on the support slider <NUM>. It should be noted that the disposition of the assemblable element <NUM> on the support slider <NUM> can be previously carried out by an operator, for example in an environment with a controlled atmosphere.

The transport container <NUM> is positioned in a closed condition, so that its secondary closing unit <NUM>' couples to the primary closing unit <NUM>'. Subsequently, it is provided to open the hatch 19a toward the inside of the processing chamber <NUM>, so as to open both the primary and secondary closing unit <NUM>', <NUM>' and put the inside of the transport container <NUM> in communication with the inside of the processing chamber <NUM>, as shown in <FIG>.

At this point the slider <NUM> is extracted in the manner described above, so that the handling device <NUM> can remove the assemblable element <NUM>.

It should be noted that, in the embodiments in which the apparatus provides the recognition device <NUM>, before the steps that will be described below, there is provided a step of recognition of the assemblable element <NUM>, modular, by the recognition device <NUM>. Such step provides to send a corresponding recognition signal to the handling device <NUM>, in particular by means of the control and command unit <NUM>. According to some embodiments of the method according to the present invention, the recognition signal as above contains information relating to the position and/or direction of assembly of the modular assemblable element <NUM> on the processing system <NUM>, and/or to the gripping position of the modular assemblable element <NUM> by the handling device <NUM>.

For this purpose, the handling device <NUM> is disposed so as to take the work tool <NUM> in the proximity of the assemblable element <NUM>, and the gripping elements <NUM>, 25b are brought close to each other so as to grasp the assemblable element <NUM> (<FIG>).

Subsequently, the handling device <NUM> is disposed so as to place the assemblable element <NUM> in the expected position, which - in the example shown - is on the support bench <NUM>. In the particular embodiment described above, the handling device <NUM> disposes the assemblable element <NUM> on the support bench <NUM> causing the support columns <NUM> to be inserted into the respective seatings <NUM> (<FIG>).

Subsequently, the gripping elements 25a, 25b are moved away from each other and the handling device <NUM> can thus release the assemblable element <NUM>.

When it is necessary to disassemble the assemblable element <NUM>, the handling device <NUM> can of course be commanded to carry out the sequence described above with reference to <FIG> in a reverse order, so as to remove the assemblable element <NUM> from its operating position (for example from the support bench <NUM>) and rest it on the support slider <NUM> so that it is closed within the transport container <NUM>.

It should be noted that the functioning of the automated management apparatus <NUM> has been described with reference to the example in which the handling device <NUM> removes the first transport element <NUM> from the transport container <NUM> to deposit it on the support bench <NUM>. It is evident that the functioning of the apparatus <NUM> would be the same also in those cases in which the articulated robot <NUM> handles assemblable elements <NUM> different from the first transport element <NUM>, such as for example the second transport element <NUM>, the hopper <NUM> or the collection container <NUM>.

It is clear that modifications and/or additions of parts or steps may be made to the apparatus <NUM> and method for the automated management of a processing chamber <NUM> as described heretofore, without departing from the scope of the present invention, as defined by the appended claims.

Claim 1:
Apparatus for the automated management of the assembly of a machine for processing and/or packaging pharmaceutical products inside a clean room (<NUM>), comprising:
- a chamber (<NUM>) delimited by walls (<NUM>), at least one of said walls (<NUM>) being provided with at least one access aperture (<NUM>) which can be selectively closed by means of a primary closing unit (<NUM>');
- a processing system (<NUM>) for processing the pharmaceutical products comprising at least one modular assemblable element (<NUM>), which can be removably coupled to other elements to obtain said processing system, said processing system (<NUM>) being housed in said chamber (<NUM>);
- a transport container (<NUM>) configured to be associated with said access aperture (<NUM>) from the outside of said chamber (<NUM>) and provided with a secondary closing unit (<NUM>') able to cooperate with the primary closing unit (<NUM>') of said chamber (<NUM>) so that they can be opened in order to put the inside of the transport container (<NUM>) in communication with the inside of the chamber (<NUM>), said transport container (<NUM>) being configured to contain said at least one modular assemblable element (<NUM>) that has to be coupled to other elements to obtain said processing system (<NUM>), said apparatus being characterized in that it comprises a handling device (<NUM>) housed in said chamber (<NUM>) and comprising a mobile work tool (<NUM>) configured to alternately grip or release said assemblable element (<NUM>) to respectively remove it from said transport container (<NUM>) and assemble it in a predeterminate position in order to couple it to other elements so as to obtain said processing system (<NUM>) and/or de-couple it from said other elements with which it forms said processing system (<NUM>) and return it into said transport container (<NUM>).