Patent Description:
Advantageously, the present invention also relates to a laser processing machine having a housing with a first work space and a second work space.

Laser processing machines for treating, by means of a laser device, work pieces are known. Such treatments can be for example the cutting and/or the incision of the work pieces, the laser welding and others. Since the laser radiations used during such treatments can be harmful for an operator, such laser processing machines must comprise a housing which allows screening the laser radiations.

Some of the laser processing machines comprise a housing.

which has a first work space and a second work space separated from one another by means of a dividing wall.

It is known that such laser processing machines comprise at least one laser device which can be placed both in the first work space to carry out a laser processing in the first work space and in the second work space to carry out a processing in the second work space.

Furthermore, the housing has a first entrance and a second entrance for accessing the first work space and the second work space, respectively. Additionally, the housing also comprises a first door and a second door for selectively opening and closing the first entrance and the second entrance, respectively. An advantage of this type of housing lies in the fact that it is possible to carry out a laser processing in one between the first work space and the second work space and to load and/or unload work pieces in the other between the first work space and the second work space. It should be noted that the other between the first work space and the second work space must anyway be screened.

Typically, the dimensions of the first work space and of the second work space correspond and determine a maximum dimension of the work pieces.

Some housings, as for example the one disclosed in WO-A-<NUM>, allow removing the dividing wall so as to treat work pieces which have dimensions greater than the maximum ones defined by the dimensions of the first work space and of the second work space. The removal of the dividing wall also results in the creation of a single work space. This means that it is not possible, as in the case of the presence of the first work space and of the second work space, to carry out a processing in one between the first work space and the second work space and to remove a processed piece and to load a new work piece in the other between the first work space and the second work space.

Therefore, the need is felt in the sector for a further improvement of the housings for laser processing machines and/or of the laser processing machines which allows solving at least one of the known drawbacks.

The aforementioned objects are achieved by the present invention, since it relates to a housing as defined in the independent claim. Alternative preferred embodiments are protected in the respective dependent claims.

The aforementioned objects are also achieved by the present invention, since it relates to a machine according to Claim <NUM>.

Alternative preferred embodiments are protected in the respective dependent claims.

In order to better understand the present invention, a preferred embodiment is described in the following, by way of mere non-limiting example and with reference to the accompanying drawings, wherein:.

In <FIG>, reference numeral <NUM> indicates, as a whole, a laser processing machine for treating, by means of a laser, work pieces <NUM> for obtaining processed pieces <NUM>.

According to some non-limiting embodiments, the machine <NUM> can be configured to carry out one or more of the following laser processing processes: cutting, engraving, boring, welding, cropping, butt joining, and other.

According to some non-limiting embodiments, the work piece <NUM> can comprise, in particular consist of, a metal material such as for example steel, carbon steel, stainless steel, aluminium, brass, copper, titanium alloys and other alloys or any combination thereof.

The work pieces <NUM> can have complex or simple structures. For example, the work pieces <NUM> can have respective (complex) three-dimensional structures or bi-dimensional structures.

The work pieces <NUM> can be for example unfinished products, as possibly obtained by means of curvature, printing, hydroforming or other processes.

For example, work pieces <NUM> can be curved pipes, formed sheets, other types or combinations thereof.

With reference to <FIG>, the machine <NUM> comprises a housing <NUM>, in particular having and/or delimiting an inner space <NUM>; and a laser apparatus <NUM> arranged in the housing <NUM>, in particular in the inner space <NUM>, for carrying out a laser processing on work pieces <NUM>.

In more detail, the housing <NUM> extends along a first axis A, a second axis B perpendicular to the first axis A and a third axis C perpendicular to the first axis A and to the second axis B. In particular, the first axis A and the third axis C can have respective horizontal orientations and the second axis B can have a vertical orientation.

Preferentially, the extension of the housing <NUM> along the first axis A can define a width of the housing <NUM>, along the second axis B it can define a height of the housing <NUM> and along the third axis C it can define a depth of the housing <NUM>.

The housing <NUM> comprises a first work space <NUM> and a second work space <NUM> distinct and separate from one another and each configured to receive work pieces <NUM>.

The housing <NUM> further comprises a dividing wall <NUM>, in particular placed in the inner space <NUM>, which separates the first work space <NUM> and the second work space <NUM> from one another. In other words, the dividing wall <NUM> is interposed between the first work space <NUM> and the second work space <NUM>.

Advantageously, the dividing wall <NUM> is placeable in an operating position. In particular, the dividing wall <NUM> is variable among at least a first position (see <FIG>), a second position (see <FIG>) and a third position (see <FIG>) distinct from one another. By means of the placing of the dividing wall <NUM> in the operating position and thanks to the possibility of choosing the position of the dividing wall <NUM> among at least the first position, the second position and the third position, it is possible to vary and/or determine the dimensions of the first work space <NUM> and of the second work space.

In particular, the operating position of the dividing wall <NUM> determines a first length E1 of the first work space <NUM> and a second length E2 of the second work space <NUM>. Still more in particular, the first length E1 and the second length E2 vary as a function of the operating position, for example depending if the operating position corresponds to the first position, to the second position or to the third position.

Preferentially, the first length E1 and the second length E2 describe an extension of the first work space <NUM> and of the second work space <NUM>, respectively, along a direction parallel to the first axis A.

In particular, the operating position of the dividing wall <NUM> can be varied relative to a direction D parallel to the first axis A and/or parallel to the normal of the dividing wall <NUM>.

According to some non-limiting embodiments, the first position and the third position define respective limit operating positions. In other words, the dividing wall <NUM> can be selectively arranged in the first position, the third position or at least a position, for example the second position, interposed between the first position and the third position. In particular, the first operating position corresponds to a first limit operating position which can determine a first minimum length E1 and a second maximum length E2 and/or the third operating position corresponds to a second limit operating position which can determine a first maximum length E1 and a second minimum length E2.

In further detail, when the operating position of the dividing wall <NUM> corresponds to the first position (see <FIG>), the first length E1 can be less and/or the second length E2 can be greater respectively than the respective first lengths E1 and the respective second lengths E2 when the operating position of the dividing wall <NUM> corresponds to the second position or to the third position. Alternatively or additionally, when the operating position of the dividing wall <NUM> corresponds to the third position (see <FIG>), the first length E1 can be greater and/or the second length E2 can be less respectively than the respective first lengths E1 and the respective second lengths E1 when the operating position of the dividing wall <NUM> corresponds to the second position or to the first position. Alternatively or additionally, when the operating position of the dividing wall <NUM> corresponds to the second position (see <FIG>) the first length E1 and the second length E2 are (substantially) identical.

According to some non-limiting embodiments, for example the first length E1 and the second length E2 are (substantially) identical when the operating position corresponds to the first position or to the third position.

According to some non-limiting embodiments, the operating position can be varied between the first position and the third position in a continuous manner (i.e. there is an "unlimited" number of operating positions between the first position and the third position) or in a discrete manner (i.e. there is a limited number of operating positions between the first position and the third position).

In more detail, the dividing wall <NUM> can extend along an axis parallel to the second axis B and another axis parallel to the third axis C. Preferentially, an extension of the dividing wall <NUM> along an axis parallel to the axis A can define a thickness of the dividing wall <NUM>.

Preferentially, the dividing wall <NUM> can extend vertically.

In particular, the dividing wall <NUM> can define a respective lateral wall of the first work space <NUM> and of the second work space <NUM>.

Furthermore, the housing <NUM> can comprise two lateral walls <NUM>, each one being spaced from the dividing wall <NUM>, in particular in a direction parallel to the first axis A. In particular, the dividing wall <NUM> can be interposed between the two lateral walls <NUM> for partially delimiting the first work space <NUM> and the second work space <NUM>.

More specifically, one of the lateral walls <NUM> can define, together with the dividing wall <NUM>, the first length E1 of the first work space <NUM> and the other lateral wall <NUM> can delimit, together with the dividing wall <NUM>, the second length E2. In other words, an extension between the dividing wall <NUM> and one of the lateral walls <NUM> along the first axis A determines the first length E1 and an extension between the dividing wall <NUM> and the other of the lateral walls <NUM> along the first axis A determines the second length E2.

According to some preferred embodiments, when the dividing wall <NUM> is placed in the second position, the dividing wall <NUM> can be equidistant from the two lateral walls <NUM>. Furthermore, when the dividing wall <NUM> is placed in the first position or in the second position, the dividing wall <NUM> can be closer to one of the two lateral walls <NUM>.

Furthermore, the housing <NUM> can also comprise a first auxiliary wall <NUM> and a second auxiliary wall transverse to the dividing wall <NUM>. In particular, the first auxiliary wall <NUM> and the second auxiliary wall are spaced apart from one another along a direction parallel to the third axis C and delimit the first work space <NUM> and the second work space <NUM> along the direction parallel to the third axis C.

Preferentially, the first auxiliary wall <NUM> and the second auxiliary wall can face one another.

Preferentially, the first auxiliary wall <NUM> can be placed in the inner space <NUM>.

With particular reference to <FIG>, the housing <NUM> can comprise a first entrance <NUM> and a second entrance <NUM> configured to allow access, for example to an operator and/or to a robot, to the first work space <NUM> and to the second work space <NUM>, respectively, in particular for loading a work piece <NUM> and/or for unloading a processed piece <NUM>.

Advantageously, the first entrance <NUM> and the second entrance <NUM> are variable as a function of the operating position of the dividing wall <NUM>.

In particular, la operating position of the dividing wall <NUM> can determine a first extension of the first entrance <NUM> and a second extension of the second entrance <NUM> along the first axis A.

Advantageously and thanks to the fact of having the first work space <NUM> and the second work space <NUM>, it is possible to carry out a laser processing in one between the first work space <NUM> and the second work space <NUM> and to unload a processed piece <NUM> and/or load a work piece <NUM> in the other between the first work space <NUM> and the second work space <NUM>.

The housing <NUM> can comprise a closing device configured to selectively open and close the first entrance <NUM> and the second entrance <NUM>.

More specifically, the closing device can comprise one or more doors, in particular sliding and/or telescopic doors, so as to selectively open and close the first entrance <NUM> and the second entrance <NUM>. Still more specifically, the closing device can comprise a first door <NUM> configured to selectively open and close the first entrance <NUM> and a second door <NUM> configured to selectively open and close the second entrance <NUM>.

Considering the fact that the operating position of the dividing wall <NUM> can vary, it is necessary to control the closing device, in particular the first door <NUM> and the second door <NUM>, depending on the operating position selectively chosen.

The laser processing machine <NUM> and/or the housing <NUM> comprises/comprise a control unit operatively connected to the closing device, in particular to the first door <NUM> and the second door <NUM>, and also a sensor device operatively connected to the control unit and configured to determine the operating position of the dividing wall <NUM>.

The control unit is configured to control the closing device, in particular to selectively control the first door <NUM> and the second door <NUM>, as a function of the operating position of the dividing wall <NUM>, as determined by the sensor device. Preferentially, the control unit can also be configured to control the closing device, in particular to selectively control the first door <NUM> and the second door <NUM>, as a function of the first length E1 and of the second length E2.

In particular, the sensor device can be configured to determine with precision the position of the dividing wall <NUM> which in turn allows adjusting with precision the closing device, in particular the first door <NUM> and the second door <NUM>, so as to ensure the selective closing of the first entrance <NUM> and of the second entrance <NUM>.

According to some non-limiting embodiments, the sensor device can comprise a plurality of reading heads each arranged in the area of a respective possible position of the dividing wall <NUM>. In the specific case, the sensor device can comprise a first reading head arranged in the area of the first position, a second reading head arranged in the area of the second position and a third reading head arranged in the area of the third position.

Preferentially, each reading head can be configured to detect a transmitter mounted on the dividing wall <NUM> for determining the operating position of the dividing wall <NUM>.

Alternatively or additionally, the sensor device can comprise an (absolute) encoder (indirectly) associated with the dividing wall <NUM>.

Preferentially, the length of each one of the first door <NUM> and the second door <NUM> is changeable so as to be adaptable relative to the operating position of the dividing wall <NUM>, in particular as determined by the sensor device.

In more detail, the control unit can be configured to selectively control each one of the first door <NUM> and the second door <NUM> between a respective closing configuration and a respective opening configuration, in particular for selectively closing and opening the first entrance <NUM> and the second entrance <NUM>, respectively. In particular, the first door <NUM> and the second door <NUM> close and free the first entrance <NUM> and the second entrance <NUM>, respectively, when they are controlled in the respective closing configuration and the respective opening configuration, respectively.

In further detail, the control unit can be configured to adjust the first door <NUM> and the second door <NUM> to extend from a respective lateral portion <NUM> of the housing <NUM> to the dividing wall <NUM> for closing the first entrance <NUM> and the second entrance <NUM>, respectively, in particular when it controls, in use, the first door <NUM> and the second door <NUM> in the respective closing configuration. In particular, each lateral portion <NUM> comprises a respective lateral wall <NUM>; in other words, in use, the first door <NUM> and the second door <NUM> can selectively extend from the respective lateral wall <NUM> to the dividing wall <NUM>.

According to some non-limiting embodiments, the housing <NUM> can comprise a first housing seat <NUM> for the first door <NUM> and a second housing seat <NUM> for the second door <NUM>. In particular, each one of the first housing seat <NUM> and the second housing seat <NUM> can be arranged in the area of a respective lateral portion <NUM>.

Preferentially, the control unit can be configured to control the extension of the first door <NUM> and of the second door <NUM> depending on the operating position detected by the sensor device so as to align the first door <NUM> and the second door <NUM> with the dividing wall <NUM> when they are controlled in the respective closing configuration. According to some non-limiting embodiments, the extension of the first door <NUM> and of the second door <NUM> is controlled so as to establish a contact with the dividing wall <NUM> when the first door <NUM> and the second door <NUM> are controlled in the respective closing configuration.

More specifically, each one of the first door <NUM> and the second door <NUM> can extend from the first housing seat <NUM> and from the second housing seat <NUM>, respectively, to the dividing wall <NUM> when it is controlled in the respective closing configuration. Furthermore, each one of the first door <NUM> and the second door <NUM> can be inserted in the first housing seat <NUM> and the second housing seat <NUM>, respectively, when it is controlled in the respective opening configuration.

Preferentially, the first door <NUM> and the second door <NUM> can be sliding and/or telescopic doors. More specifically, each one of the first door <NUM> ad the second door <NUM> can comprise a plurality of leaves configured to slide in front of one another. In particular, each leaf is coupled to at least another leaf in a linearly shiftable manner.

According to some non-limiting embodiments, the housing <NUM> can comprise a first auxiliary sensor device configured to determine an extension and/or a placing (absolute or relative for example with respect to the dividing wall <NUM>) of the first door <NUM> and/or of the second door <NUM>, in particular when being controlled in the closing configuration and/or when it is controlled in the closing configuration. Preferentially, the control unit can be configured to adjust the first door <NUM> and the second door <NUM> as a function of the measurements of the first auxiliary sensor device, in particular for ensuring a correct closing of the first entrance <NUM> and of the second entrance <NUM> with the first door <NUM> and with the second door <NUM>, respectively, and/or for ensuring that the first door <NUM> and the second door <NUM> are aligned and/or in contact with the dividing wall <NUM> when they are controlled in the respective closing configuration.

Preferentially, the closing device can be configured to open the first entrance <NUM> and the second entrance <NUM> while, in use, a laser processing is carried out in the second work space <NUM> and in the first work space <NUM>, respectively.

Preferentially, in use, the closing device closes the first entrance <NUM> while the laser apparatus <NUM> carries out a laser processing in the first work space <NUM> and/or the second entrance <NUM> while the laser apparatus <NUM> carries out a laser processing in the second space <NUM>.

According to some embodiments, the housing <NUM> can comprise at least a first guide assembly, a second guide assembly and a third guide assembly arranged in the inner space <NUM> and which define the first position, the second position and the third position, respectively. In particular, the dividing wall <NUM> can be selectively coupled to the first guide assembly, to the second guide assembly and to the third guide assembly for placing the dividing wall <NUM> in the first position, in the second position and in the third position, respectively.

Preferentially, the dividing wall <NUM> and/or the first guide assembly, the second guide assembly and the third guide assembly can comprise stopping devices configured to fix the dividing wall <NUM> in a reversible manner.

According to a such embodiment, in use, in order to change the position of the dividing wall <NUM> it is necessary to decouple the dividing wall <NUM> from the first guide assembly, from the second guide assembly or from the third guide assembly. Subsequently, it is possible to couple the dividing wall <NUM> to the first guide assembly, to the second guide assembly or to the third guide assembly.

Preferentially, the first guide assembly, the second guide assembly and the third guide assembly extend in a direction parallel to the third axis C and are arranged with respect to one another along a direction parallel to the first axis A.

Alternatively o additionally, the housing <NUM> can comprise a moving device coupled to the dividing wall <NUM> and configured to move the dividing wall <NUM> along a direction normal to the dividing wall <NUM> between a first limit position which corresponds to the first position and a second limit position which corresponds to the third position. In particular, the direction normal to the dividing wall <NUM> can be parallel to the axis A.

Preferentially, the moving device can be configured to change the position of the dividing wall <NUM> in a continuous manner.

According to some non-limiting embodiments, the sensor device can comprise an (absolute) encoder coupled to the moving device, for example to a motor of the moving device, for delimiting the operating position of the dividing wall <NUM>.

With particular reference to <FIG>, the dividing wall <NUM> can comprise at least one first end portion <NUM>, in particular a lower portion <NUM>, configured to be in contact and/or being in contact with a support surface and a second end portion <NUM>, in particular an upper portion <NUM>, opposite the first end portion <NUM>, in particular along a direction parallel to the second axis B.

According to the illustrated embodiment, the dividing wall <NUM> can also comprise a protruding portion <NUM> protruding from the second end portion <NUM>, in particular in a direction parallel to the second axis B.

With particular reference to <FIG>, <FIG> and <FIG>, the housing <NUM> can comprise a covering device <NUM>, in particular placed in the inner space <NUM>, configured to selectively cover at least one between the first work space <NUM> and the second work space <NUM>. In particular, the covering device <NUM> can be configured to cover one between the first work space <NUM> and the second work space <NUM> and to free the other between the first work space <NUM> and the second work space <NUM>.

For example, in <FIG> and <FIG> the respective conditions in which the covering device <NUM> covers the first work space <NUM> and the second work space <NUM>, respectively, are indicated.

This allows carrying out a laser processing in the work space <NUM> or <NUM> which is not covered by the covering device <NUM>, while an operator can remove a processed piece <NUM> and/or insert a new work piece <NUM> in the other work space <NUM> or <NUM> (i.e. the work space <NUM> or <NUM> which is covered by the covering device <NUM>).

Advantageously, the control unit can be operatively connected to the covering device <NUM> and can be configured to control the covering device <NUM> as a function of the operating position of the dividing wall <NUM> as determined by the sensor device.

In more detail, the covering device <NUM> can comprise a first cover <NUM> and a second cover <NUM>, each controllable at least in an active configuration in which the first cover <NUM> and the second cover <NUM> are configured to cover and/or cover the first work space <NUM> and the second work space <NUM>, respectively.

Considering the fact that the first extension E1 and the second extension E2 can vary as a function of the operating position of the dividing wall <NUM>, it is advantageous to control the first cover <NUM> and the second cover <NUM> as a function of the operating position, in particular for ensuring a precise covering.

In particular, the control unit can be configured to control the first cover <NUM> and the second cover <NUM> as a function of the operating position of the dividing wall <NUM>, in particular as determined by the sensor device.

More specifically, the first cover <NUM> and the second cover <NUM> extend from a respective lateral portion of the housing <NUM> to the dividing wall <NUM> when they are controlled in the respective active configurations.

Preferentially, the covering device <NUM> can also comprise a guide system <NUM> configured to guide the first cover <NUM> and the second cover <NUM> so that the first cover <NUM> and the second cover <NUM>, when they are in the respective active configurations, comprise at least a respective main portion <NUM> and a respective auxiliary portion <NUM> extending transversally from the respective main portion <NUM>.

Preferentially, each main portion <NUM> has a (substantially) horizontal orientation.

According to some non-limiting embodiments, each one of the first cover <NUM> and the second cover <NUM> can be controllable in a respective waiting configuration in which the first cover <NUM> and the second cover <NUM> are configured to free and/or free the first work space <NUM> and the second work space <NUM>, respectively.

In particular, the housing <NUM> can be configured so that one between the first cover <NUM> and the second cover <NUM> can be controlled in the respective active configuration while the other between the first cover <NUM> and the second cover <NUM> can be controlled in the waiting configuration.

In more detail, the guide system <NUM> can comprise a first group of tracks <NUM> for guiding the first cover <NUM> so that the first cover <NUM>, when it is in the active configuration, has at least the respective main portion <NUM> and the respective auxiliary portion <NUM> and a second group of tracks <NUM> for guiding the second cover <NUM> so that the second cover <NUM>, when it is in the active configuration, has at least the respective main portion <NUM> and the respective auxiliary portion <NUM>.

In more detail, each one of the first group of tracks <NUM> and the second group of tracks <NUM> can comprise a respective first track <NUM> and a second track <NUM> spaced apart from one another along a respective axis E parallel to the third axis C.

Furthermore, the first track <NUM> and the second track <NUM> can each comprise a respective first portion <NUM> and a respective second portion <NUM>. The first portions <NUM> can be made and/or configured to support and/or define the respective main portion <NUM> and the second portions <NUM> can be configured to support and/or define the respective auxiliary portion <NUM>.

Additionally, each second portion <NUM> can be connected to and extends from the respective first portion <NUM> to the second end portion <NUM>.

In particular, each second portion <NUM> can be inclined relative to the respective first portion <NUM>.

Preferentially, each first portion <NUM> can extend along a longitudinal axis (substantially) parallel to the first axis A. Still more preferentially, each first portion <NUM> can be oriented horizontally.

Preferentially, the length of the first portions <NUM> is selectively adaptable as a function of the operating position of the dividing wall <NUM>, in particular as determined by the sensor device. In this manner, it is possible to adapt the extensions of the main portions <NUM> as a function of the operating position of the dividing wall <NUM>.

According to some non-limiting embodiments, the housing <NUM> can also comprise a second auxiliary sensor device configured to determine an extension and/or (absolute or relative) placing of the first cover <NUM> and/or of the second cover <NUM>, in particular when it is controlled in the active configuration and/or when being controlled in the active configuration. Preferentially, the control unit can be configured to adjust the first cover <NUM> and the second cover <NUM> also as a function of the measurements of the second auxiliary sensor device, in particular for selectively aligning the first cover <NUM> and the second cover <NUM> with the dividing wall <NUM>.

Preferentially, the second auxiliary sensor device can also be configured to determine the extensions of the first portions <NUM>.

According to some non-limiting embodiments, the housing <NUM> can also comprise a first housing device <NUM> and a second housing device <NUM> for housing the first cover <NUM> and the second cover <NUM>, respectively, in particular when it is controlled in the respective waiting configuration.

According to some non-limiting embodiments, the housing <NUM> also comprises an actuating device <NUM> configured to selectively control the first cover <NUM> and the second cover <NUM> between the active configuration and the waiting configuration.

With particular reference to Figures <NUM> to <NUM>, the laser apparatus <NUM> can comprise one or more laser devices, in the specific case a laser device <NUM> is illustrated.

The laser apparatus <NUM> can also comprise a support structure <NUM>, in particular arranged in the inner space <NUM>, carrying the laser device <NUM> in a movable manner.

In more detail, the support structure <NUM> can comprise a fixed structure <NUM> and a movable structure <NUM> carrying the laser device <NUM> and coupled in a movable manner to the fixed structure <NUM>. In particular, the movable structure <NUM> can be movable along a path, in particular a linear path.

Furthermore, the support structure <NUM> can comprise an actuator for moving the movable structure <NUM> along the path.

In further detail, the laser device <NUM> is coupled to the movable structure <NUM> so as to carry out respective angular movements around one or more rotation axes and a translation along a respective axis (substantially) parallel to the second axis B (for selectively approaching and spacing apart the laser device <NUM> to or from the work piece <NUM>).

The movable structure <NUM> can allow selectively placing the laser device <NUM> in the first work space <NUM> and in the second work space <NUM>.

According to some non-limiting embodiments, the laser processing machine <NUM> can also comprise two work tables <NUM>, one arranged in the first work space <NUM> and the other in the second work space <NUM>. Each work table <NUM> is configured to support the work pieces <NUM> (and then, the processed pieces <NUM>).

According to some non-limiting embodiments, the specific work table <NUM> arranged in the first work space <NUM> and in the second work space <NUM> can be chosen and/or changed depending on the dimension of the first work space <NUM> and of the second work space <NUM>.

The laser processing machine <NUM> can further comprise a man-machine interface <NUM>.

In use, the processing machine <NUM> laser-processes work pieces <NUM> for obtaining processed pieces <NUM>.

In particular, the work pieces <NUM> are placed in the first work space <NUM> and in the second work space <NUM>.

The operating position of the dividing wall <NUM> can be chosen for adjusting the dimensions of the first work space <NUM> and of the second work space <NUM>.

If wanting to change the dimensions of the first work space <NUM> and of the second work space <NUM>, the operating position of the dividing wall <NUM> has to be changed.

According to some embodiments, the operating position can vary in a discrete manner, while according to other alternative embodiments, the operating position can vary in a continuous manner between a first limit position and a second limit position.

When the operating position has been defined, it is possible to start the laser processing.

In order to carry out the processing, the laser device <NUM> has to be placed in the first work space <NUM> or in the second work space <NUM> for carrying out the laser processing in the first work space <NUM> or in the second work space <NUM>, respectively.

For safety reasons, it is necessary to close the first entrance <NUM> and the second entrance <NUM> if a processing is carried out in the first work space <NUM> (see <FIG>) and in the second work space <NUM> (see <FIG>), respectively.

The sensor device determines the operating position which allows the control unit to adjust the closing device, in particular the first door <NUM> and the second door <NUM>, for ensuring the correct closing of the first entrance <NUM> and of the second entrance <NUM>.

Advantageously, the control unit also adjusts the covering device <NUM> as a function of the operating position of the dividing wall <NUM>.

In more detail, the covering device <NUM> covers the first work space <NUM> (see <FIG> and <FIG>), in particular by means of the control of the first cover <NUM> in the respective active configuration, while the laser apparatus <NUM>, in particular the laser device <NUM>, carries out the laser processing of the work piece <NUM> placed in the second work space <NUM> (while the second cover <NUM> is in the respective waiting configuration). Furthermore, the covering device <NUM> covers the second work space <NUM> (see <FIG> and <FIG>), in particular by means of the control of the respective second cover <NUM> in the active configuration, while the laser apparatus <NUM>, in particular the laser device <NUM>, carries out the laser processing of the work piece <NUM> placed in the first work space <NUM> (while the first cover <NUM> is in the respective waiting configuration).

During the execution of a laser processing in one between the first work space <NUM> and the second work space <NUM> it is possible, for example through an operator or a robot, to remove a processed piece <NUM> and/or place a new work piece <NUM> in the other between the first work space <NUM> and the second work space <NUM>.

In order to carry out at times the laser processing in the first work space <NUM> and at times in the second work space <NUM> it is necessary to transfer the laser device <NUM> from the first work space <NUM> or from the second work space <NUM> to the second work space <NUM> or to the first work space <NUM>. For this reason, it is necessary to control the first cover <NUM> and the second cover <NUM> from the active configuration to the waiting configuration if the laser processing was carried out in the second work space <NUM> or in the first work space <NUM>, respectively.

By examining the characteristics of the processing machine <NUM> and/or of the housing <NUM> according to the present invention, the advantages that they allow obtaining are evident.

In particular, the housing <NUM> allows a greater flexibility. It is possible to change the dimensions of the first work space <NUM> and of the second work space <NUM> for adapting them the best way possible to the dimensions of the work pieces <NUM>. For example, it is possible to manage the laser processing of work pieces <NUM> which have various dimensions.

A further advantage lies in the fact of having the sensor device and the control unit for ensuring the safety of the operators thanks to the precise control of the closing device and/or of the covering device <NUM> as a function of the detected operating position.

Claim 1:
A housing (<NUM>) for a laser processing machine (<NUM>) to treat, by means of a laser, work pieces (<NUM>), in particular metal work pieces;
the housing (<NUM>) comprises:
- a dividing wall (<NUM>), which separates a first work space (<NUM>) having a first length (E1) and a second work space (<NUM>) having a second length (E2) from one another; wherein the first work space (<NUM>) and the second work space (<NUM>) are configured to receive the work pieces (<NUM>);
- a first entrance (<NUM>) to allow access to the first work space (<NUM>);
- a second entrance (<NUM>) to allow access to the second work space (<NUM>);
- a closing device (<NUM>; <NUM>), which is configured to selectively open and close the first entrance (<NUM>) and the second entrance (<NUM>); and
- a control unit, which is operatively connected to the closing device (<NUM>; <NUM>);
characterized in that the dividing wall (<NUM>) is placeable in an operating position, which is variable among at least a first position, a second position and a third position;
wherein the first length (E1) and the second length (E2) vary as a function of the operating position;
wherein the control unit is configured to control the closing device (<NUM>; <NUM>) as a function of the operating position of the dividing wall (<NUM>);
wherein the housing (<NUM>) further comprises a sensor device, which is operatively connected to the control unit and is configured to determine the operating position of the dividing wall (<NUM>);
wherein the control unit is configured to control the closing device (<NUM>; <NUM>) as a function of the operating position of the dividing wall (<NUM>) as determined by the sensor device.