阅读说明：本技术 用于皮革切割机的具有振荡刀头的切割装置 (Cutting device with oscillating cutter head for a machine for cutting leather ) 是由 詹尼·加卢奇 于 2016-10-25 设计创作，主要内容包括：一种切割装置,包括：振荡室；振荡活塞,其预先设置成使得头部在振荡室中并且杆连接至切割刀头；气动驱动系统,其与振荡室连通从而气动地驱动振荡活塞在振荡室中竖向振荡,并且因此使用于切割皮革片的切割刀头竖向振荡。该装置还包括：位于振荡室上方的辅助室；辅助活塞,其预先设置成头部在辅助室中并且具有连接至振荡活塞的头部的杆；以及推力元件,其在辅助室中预先设置在辅助活塞的头部与辅助室的下抵靠表面之间。在气动驱动系统停用之后推力元件能够被启用以提升,从而推动并且提升辅助活塞抵靠辅助室的上抵靠表面,从而使振荡活塞相应地提升并且因此将切割刀头提升至皮革片上方的升起位置。(A cutting device, comprising: an oscillation chamber; an oscillating piston predisposed so that the head is in the oscillating chamber and the rod is connected to the cutting head; a pneumatic drive system in communication with the oscillation chamber to pneumatically drive the oscillation piston to oscillate vertically in the oscillation chamber and thereby vertically oscillate the cutting head for cutting the leather sheet. The device also includes: an auxiliary chamber located above the oscillation chamber; an auxiliary piston predisposed with a head in the auxiliary chamber and having a stem connected to the head of the oscillating piston; and a thrust element predisposed in the auxiliary chamber between the head of the auxiliary piston and the lower abutment surface of the auxiliary chamber. The thrust element can be activated to lift after deactivation of the pneumatic drive system, so as to push and lift the auxiliary piston against the upper abutment surface of the auxiliary chamber, so as to cause the oscillating piston to lift accordingly and thus the cutting head to a raised position above the leather sheet.)

1. A cutting device (100) with oscillating cutting head for a machine for cutting leather, comprising:

a body (C);

a cutting head (L) for cutting a leather piece (V) spread on a work plane;

an oscillation chamber (1) within the body (C), the oscillation chamber (1) comprising an upper end stop wall (11) and a lower end stop wall (12);

an oscillating piston (10), said oscillating piston (10) having a head (13) and a rod (14), said oscillating piston (10) being predisposed for said head (13) to be inserted in said oscillating chamber (1) between said upper end stop wall (11) and said lower end stop wall (12), and said rod (14) being connected to said cutting head (L);

a pneumatic drive system (P) communicating with the oscillation chamber (1), the pneumatic drive system (P) comprising a pneumatic supply source (P1) and at least one discharge (S1, S2), the pneumatic drive source (P1) and the at least one discharge (S1, S2) being predisposed and configured so that a first portion (1A) of the oscillation chamber (1) comprised between the head (13) and the lower end wall (12) of the oscillating piston (10) and a second portion (1B) of the oscillation chamber (1) comprised between the head (13) and the upper end wall (11) of the oscillating piston (10) are arranged in alternating communication with the pneumatic supply source (P1) and the at least one discharge (S1, S2) so as to pneumatically drive the oscillation piston (1) within the oscillation chamber (1) between the lower end wall (12) and the upper end wall (12) and so that the cutting blade (V466) is in a vertical cutting position (V L) between the lower end wall (12, S3511) and the cutting blade (V L) is thus cut the cutting blade (V) and the cutting position (4) is cut in the oscillation chamber (1),

the upper end stop wall (11) is predisposed in the body (C) with respect to the lower end stop wall (12) so that the cutting head (L) remains in contact with the leather sheet (V) to be cut when the cutting head (L) reaches the upper cutting position (L2) during the vertical oscillation of the cutting head (L);

said body (C) comprising a cylinder (16) and said rod (14) of said oscillating piston (10) being predisposed to be alternately slidable in said cylinder (16);

the method is characterized in that:

the rod (14) of the oscillating piston (10) is shaped so as to have: two annular portions (141, 142) and an annular recess (140), said two annular portions (141, 142) being in sliding contact with the wall of the cylinder (16), and said annular recess (140) being comprised between said two annular portions (141, 142); an inner pipe (17); and the rod (14) is provided with a through hole (18), the through hole (18) being predisposed in a position below the annular recess (140) to place the outside of the rod (14) in communication with the internal duct (17);

-the head (13) of the oscillating piston (10) is provided with a through hole (130), said through hole (130) being used to arrange the internal duct (17) of the rod (14) in communication with a second portion (1B) of the oscillation chamber (1) comprised between the head (13) of the oscillating piston (10) and the upper end stop wall (11) of the oscillation chamber (1);

the pneumatic drive system (P) comprises: a switching chamber (8) in a portion of the inner wall of the cylinder (16) and a main conduit (81), the main conduit (81) being predisposed in the body (C) to communicate with the pneumatic supply (P1) and with a lower portion of the switching chamber (8); a second duct (82), said second duct (82) being predisposed in said body (C) to communicate with the upper part of said switching chamber (8) and with said oscillating chamber (1) through a passage hole (83) in said lower end stop wall (12) of said oscillating chamber (1); an upper drain (S1) and a lower drain (S2), the upper drain (S1) communicating with the outside in the cylinder (16) at a position above the switching chamber (8), the lower drain (S2) communicating with the outside in the cylinder (16) at a position below the switching chamber (8);

the annular recess (140) of the rod (14) has dimensions and the positioning of the hole (18) of the rod (14) with respect to the annular recess (140) is such that the rod (14) slides alternately inside the cylinder (16):

when the annular recess (140) of the stem (14) is positioned at the switching chamber (8), the hole (18) of the stem (14) is positioned at the lower drain (S2) so that the main duct (81) communicates with the second duct (82) through the annular recess (140) and therefore the pneumatic supply source (P1) communicates with a first portion (1A) of the oscillation chamber (1) between the head (13) and the lower end stop wall (12) of the oscillation piston (10), whereas a second portion (1B) of the oscillation chamber (1) between the head (13) and the upper end stop wall (11) of the oscillation piston (10) communicates with the lower drain (S2) through a through hole (130) of the head (13) of the oscillation piston (10), an internal duct (17) of the stem (14) and the hole (18) of the stem (14), so that the oscillating piston (10) can be pushed pneumatically upwards;

and when the annular recess (140) of the stem (14) is positioned at the upper part of the switching chamber (8) and at the upper part of the upper discharge (S1) both communicating with the second duct (82), the hole (18) of the stem (14) is at the lower part of the switching chamber (8) and communicates with the main duct (18), so that the pneumatic supply source (P1) communicates with the second part (1B) of the oscillating chamber (1) between the upper end stop wall (11) and the head (13) of the oscillating piston (10) through the hole (18) of the stem (14), the internal duct (17) of the stem (14) and the through hole (130) present in the head (13) of the oscillating piston (10), while the first part (1A) of the oscillating chamber (1) between the head (13) of the oscillating piston (10) and the lower end stop wall (12) communicates with the upper discharge (S1) through the second duct (82), so that the oscillating piston (10) can be pneumatically pushed downwards.

Technical Field

The present invention relates to the particular technical field related to cutting machines for cutting materials, such as leather pieces, leather, synthetic leather, etc., in sheets or rolls, as fur.

In particular, the present invention relates to a cutting device having an oscillating cutter head that can be used by and mounted on a cutting machine.

Background

In this particular field, the cutting machine comprises: a frame, which is located above the work plane where the material to be cut is spread, such as fur (skins, leathers), synthetic leather, etc.; a cutting device provided below with a cutting head and moving means supported by and movable relative to the frame for moving the cutting device along three cartesian axes above the work plane so that the cutting head can be positioned above the pelt, the cutting head can be lowered to cut the piece of leather and moved along a given cutting path to cut the piece of leather according to a predetermined or desired contour and/or shape.

The cutting device for the above purpose is predisposed so that the cutting head can oscillate vertically from a low cutting position to a high cutting position while cutting the hide, while still remaining within the thickness of the material to be scored/cut.

A first type of cutting device currently used consists in making the cutting head oscillate vertically by means of a mechanical drive.

For example, cutting devices are known that include a cam member mounted on a shaft that can be driven to rotate, wherein the cam contacts a rod or other element connected to a cutting bit.

In this way, once the shaft is driven in rotation, the rotation of the cam member transmits an oscillating motion (alternate vertical translation) to the rod/contact member and, therefore, to the cutting head.

Various types of cutting devices are known which are predisposed to enable the cutting head to oscillate vertically by means of a pneumatic drive.

For example, cutting devices of known type are known comprising: an oscillation chamber having an upper end wall and a lower end wall; an oscillating piston predisposed with a head in the oscillation chamber and with an associated rod connected to the cutting head; and a pneumatic drive system in communication with the oscillation chamber to oscillate the piston in the oscillation chamber between the upper and lower end stop walls and thereby oscillate the cutting bit vertically.

In this known type of cutting device, the pneumatic drive system comprises a pneumatic supply and discharge, predisposed and configured so that the portion of the oscillation chamber comprised between the piston head and the upper end stop wall and the portion of the oscillation chamber comprised between the piston head and the lower end stop wall are alternately arranged in communication with the pneumatic supply and discharge so as to enable the piston to oscillate in the oscillation chamber.

In particular, when the pneumatic supply source is arranged in communication with the portion of the oscillation chamber comprised between the piston head and the upper end stop surface, the portion of the oscillation chamber comprised between the piston head and the lower end stop surface is in communication with the discharge, in which case the piston is pushed pneumatically downwards; whereas when the pneumatic supply source communicates with the portion of the oscillating chamber comprised between the piston head and the lower end stop surface, the portion of the oscillating chamber comprised between the piston head and the upper end stop surface communicates with the discharge, in which case the piston is pneumatically pushed upwards, thereby generating an upward oscillating movement in the oscillating chamber and a vertical oscillation of the cutting head.

In this respect, in these known types of devices, the oscillation chamber comprises two openings and the pneumatic drive system comprises a duct communicating with said openings and with a obturator or another valve mechanism, so that each of the two openings of the oscillation chamber can be arranged to alternately communicate with the pneumatic source and the discharge via said duct.

In the particular field of leather cutting (and similar materials) such as furs, synthetic leather, etc., it is often necessary and necessary to perform cuts of shapes with very jagged or discontinuous profiles, which have very drastic changes of the corners or directions: in this case, it is necessary to change the direction of movement of the cutting head.

Thus, to perform such an operation, the cutting bit must first be extracted and disengaged from the material, then rotated in a new cutting direction and finally lowered to penetrate the material, and re-oscillated to perform the slitting and cutting.

In both of the previously described types of cutting devices, with mechanical drive of the cutting head oscillation and with pneumatic drive of the cutting head, the detachment and extraction of the cutting head from the material is performed by lifting the entire cutting device: this requires a certain amount of time, which is detrimental to productivity, and further, the weight of the entire cutting device may also be several kilograms, so that inertia is not significant for short distances of play (in the order of millimetres).

This constitutes undoubtedly a drawback and a problem, in particular when the shape to be cut has a particularly complex and uneven profile, so that the cutting device needs to be lifted tens of times in order to complete the cutting operation.

Disclosure of Invention

It is therefore an object of the present invention to provide a new cutting device with an oscillating cutting head for cutting leather pieces, which is able to eliminate the above-mentioned drawbacks present in the devices of the prior art.

In particular, the object of the present invention is to provide a new cutting device with an oscillating blade which can be driven pneumatically to extract and disengage the cutting blade in a very short time, much shorter than the devices of the prior art.

The object of the present invention is to propose a cutting device with a pneumatic drive system for vibrating a cutting head according to the following solution.

A cutting device with oscillating cutter head for a machine for cutting leather, comprising: a body; a cutting head for cutting a leather sheet spread on a work plane; an oscillation chamber within the body, the oscillation chamber comprising an upper end stop wall and a lower end stop wall; an oscillating piston having a head and a rod, predisposed so that said head is interposed in said oscillating chamber between said upper and lower end walls, and said rod is connected to said cutting head; a pneumatic drive system in communication with the oscillation chamber, the pneumatic drive system comprising a pneumatic supply source and at least one discharge, the pneumatic drive source and the at least one discharge being predisposed and configured so that a first portion of the oscillation chamber comprised between the head of the oscillation piston and the lower end stop wall and a second portion of the oscillation chamber comprised between the head of the oscillation piston and the upper end stop wall are arranged in alternating communication with the pneumatic supply source and the at least one discharge so as to pneumatically drive the oscillation piston to oscillate within the oscillation chamber between the lower end stop wall and the upper end stop wall and so as to cause the cutting head to oscillate vertically between a lower cutting position of the leather piece and an upper cutting position of the leather piece, said upper end stop wall being predisposed in said body with respect to said lower end stop wall so that said cutting head remains in contact with the piece of leather to be cut when said cutting head reaches said upper cutting position during the vertical oscillation thereof; said body comprises a cylinder and said rod of said oscillating piston is predisposed to be alternately slidable in said cylinder; the rod of the oscillating piston is shaped to have: two annular portions in sliding contact with a wall of the cylinder and an annular recess included between the two annular portions; an inner conduit; and the rod is provided with a through hole predisposed in a position below the annular recess to place the outside of the rod in communication with the internal duct; the head of the oscillating piston is provided with a through hole for arranging the internal duct of the rod in communication with a second portion of the oscillating chamber comprised between the head of the oscillating piston and the upper end stop wall of the oscillating chamber; the pneumatic drive system comprises: a switching chamber in a portion of the inner wall of the cylinder and a main pipe predisposed in the body to communicate with the pneumatic supply and with a lower portion of the switching chamber; a second duct provided in advance in the body to communicate with an upper portion of the opening and closing chamber and the oscillation chamber through a passing hole in the lower end stop wall of the oscillation chamber; an upper discharge portion communicating with an outside in the cylinder at a position above the switch chamber, and a lower discharge portion communicating with an outside in the cylinder at a position below the switch chamber; the annular recess of the rod has dimensions and positioning of the hole of the rod with respect to the annular recess such that the rod slides alternately inside the cylinder: when the annular recess of the rod is positioned at the switching chamber, the hole of the rod is positioned at the lower drain, so that the main pipe communicates with the second pipe through the annular recess and therefore the pneumatic supply source communicates with a first portion of the oscillating chamber between the head and the lower end stop wall of the oscillating piston, while a second portion of the oscillating chamber between the head and the upper end stop wall of the oscillating piston communicates with the lower drain through the through hole of the head of the oscillating piston, the internal pipe of the rod and the hole of the rod, so that the oscillating piston can be pneumatically pushed up; and when the annular recess of the rod is positioned both in communication with the upper drain and in communication with the upper portion of the switching chamber, the hole of the rod is located in the lower portion of the switching chamber and in communication with the main pipe, so that the pneumatic supply source communicates with a second portion of the oscillating chamber between the upper end stop wall and the head of the oscillating piston through the hole of the rod, the internal conduit of the rod and the through hole present in the head of the oscillating piston, while a first portion of the oscillating chamber between the head of the oscillating piston and the lower end stop wall communicates with the upper drain through the second conduit, so that the oscillating piston can be pneumatically pushed down.

Drawings

The characteristics of the cutting device with oscillating cutting head for machines for cutting hides according to the present invention will be described below with reference to the accompanying drawings, in which:

figures 1A and 1B show two different operating configurations of the oscillating cutting head of the cutting device for machines for cutting hides, during its driving oscillation to perform the cutting of the piece of hide, in which figure a1 shows a lower cutting position accessible by the cutting head during its oscillation, while figure 1B shows an upper cutting position accessible by the cutting head during its oscillation,

figure 1C shows the cutting device of the invention with oscillating blade in a non-operating configuration, in which the cutting blade can be introduced in this non-operating configuration, i.e. in a raised and lifted position with respect to the leather sheet, and then extracted and detached from the leather sheet without the need to lift the whole device;

fig. 2A shows a first preferred but not exclusive embodiment of the cutting device of the invention with an oscillating cutter head, illustrated with the associated cutting head in the operating configuration of fig. 1A, i.e. in a lower cutting position accessible to the head during oscillation thereof;

FIG. 2B shows a view according to section II-II of FIG. 2A;

fig. 2C shows a detail K of fig. 2B on a larger scale;

fig. 3A shows the cutting device of fig. 2A with an oscillating blade head, illustrated in the operating configuration of fig. 1B, i.e. in an upper cutting position accessible to the blade head during oscillation thereof;

fig. 3B shows a view according to section iii-iii of fig. 3A;

fig. 3C shows a detail H of fig. 3B on a larger scale;

fig. 4A shows the cutting device of fig. 2A with oscillating cutter head, illustrated in the particular configuration of fig. 1C, i.e. in a non-operative configuration, i.e. in a raised position with respect to the leather piece, and thus disengaged from the leather piece.

FIG. 4B shows a view according to section IV-IV of FIG. 4A;

fig. 4C shows a detail J of fig. 4B on a larger scale;

fig. 5A shows a second preferred but not exclusive embodiment of the cutting device of the invention with an oscillating cutter head, illustrated with the associated cutting head in the operating configuration of fig. 1A, i.e. in a lower cutting position accessible to the head during oscillation thereof;

FIG. 5B shows a view according to section V-V of FIG. 5A;

fig. 6A shows the cutting device of fig. 5A with an oscillating cutter head, illustrated with the associated cutting head in the operating configuration of fig. 1B, i.e. in an upper cutting position accessible to the cutter head during oscillation thereof;

fig. 6B shows a view according to section vi-vi of fig. 6A;

figure 7A shows the cutting device of figure 5A with oscillating cutter head, illustrated in the particular configuration of figure 1C, i.e. in a non-operative configuration, i.e. in a raised position with respect to the leather piece, and therefore extracted and detached from the leather piece;

FIG. 7B shows a view of the section VII-VII according to FIG. 7A.

Detailed Description

With reference to the figures, the reference numeral 100 globally designates a cutting device with oscillating cutting head for machines for cutting leathers, according to the present invention.

The cutting device 100 of the invention comprises a body C, a cutting head L for cutting a leather sheet V (or other similar material in sheet or web form, such as leather or synthetic material) spread on a work plane.

In this regard, the cutting device 100 can be mounted on a cutting machine, such as a numerically controlled cutting machine.

The cutting device is predisposed to pneumatically drive the cutting head L so that the head L can oscillate vertically to cut the leather pieces V.

For this purpose, the cutting device 100 is provided with an oscillation chamber 1 and an oscillation piston 10 inside a body C, the oscillation chamber 1 having an upper end stop wall 11 and a lower end stop wall 12, the oscillation piston 10 having a head 13 and a rod 14, the oscillation piston 10 being provided in advance such that the head 13 is inserted between the upper end stop wall 11 and the lower end stop wall 12 in the oscillation chamber 1, and the rod 14 being connected to a cutting bit L.

For the pneumatic driving of the vertical oscillation of the cutting head L, the cutting device 100 is provided with a suitable pneumatic drive system P, which communicates with the oscillation chamber 1.

The pneumatic drive system P comprises a pneumatic supply P1 (for example compressed air, schematically indicated by the boxes in the figures) and at least one discharge S1, S2.

The pneumatic drive system P is designed in the following way: the pneumatic supply source P1 and said at least one discharge S1, S2 are predisposed and configured so that a first portion 1A of the oscillation chamber 1 comprised between the head 13 and the lower end stop wall 12 of the oscillation piston 10 and a second portion 1B of the oscillation chamber 1 comprised between the head 13 and the upper end stop wall 11 of the oscillation piston 10 are arranged in communication alternately with the pneumatic supply source P1 and said at least one discharge S1, S2.

In this way, when the first portion 1A of the oscillation chamber 1 (which is comprised between the head 13 of the oscillation piston 10 and the lower end stop wall 12 of the oscillation chamber 1) is in communication with the pneumatic supply source P1, the second portion 1B of the oscillation chamber 1 (which is comprised between the head 13 of the oscillation piston 10 and the upper end stop wall 11 of the oscillation chamber 1) is in communication with the at least one drain S1, S2, so that the oscillation piston 10 can be pneumatically pushed up (see, for example, fig. 2B, 2C and 5B, which show a situation in which the head 13 of the oscillation piston 10 is in contact with the lower end stop wall 12, and is therefore in a state of being pushed up, i.e., pushed toward the upper end stop wall 11 of the oscillation chamber 1).

Specularly, when the first portion 1A of the oscillation chamber 1 (which is comprised between the head 13 of the oscillation piston 10 and the lower end stop wall 12 of the oscillation chamber 1) is in communication with the at least one discharge portion S1, S2, the second portion 1B of the oscillation chamber 1 (which is comprised between the head 13 of the oscillation piston 10 and the upper end stop wall 12 of the oscillation chamber 1) is in communication with the pneumatic supply source P1, so that the oscillation piston 10 can be pneumatically pushed down (see, for example, fig. 3B, 3C and 6B, which show a situation in which the head 13 of the oscillation piston 10 is in contact with the upper end stop wall 11, and is therefore in a state of being pushed down, i.e., toward the lower end stop wall 11 of the oscillation chamber 1).

Thus, the pneumatic drive system P present in the cutting device 100 is capable of pneumatically driving the oscillating piston 10 to oscillate in the oscillation chamber 1 between the lower end stop wall 12 and the upper end stop wall 11 and thus to oscillate the cutting head L vertically.

Specifically, the cutting bit L is then oscillated vertically between a lower cutting position L1 (see fig. 1A, 2B, 5A, 5B) and an upper cutting position L2 (see fig. 1B, 3A, 3B, 6A, 6B), wherein the lower cutting position L1 is a position defined when the head 13 of the oscillation piston 10 reaches abutment against the lower end stop wall 12 of the oscillation chamber 1, and the upper cutting position L2 is a position defined when the head 13 of the oscillation piston 10 reaches abutment against the upper end stop wall 11 of the oscillation chamber 1.

To this end, the cutting device 100 is such that the upper end stop wall 11 is predisposed in the body C at a distance with respect to the lower end stop wall 12 such that, when the head 13 of the oscillating piston 109 comes into contact with the upper end stop wall 11, the cutting head L reaches an upper cutting position L2 such that it always remains in contact with the piece of leather V to be cut, with the aim of ensuring the continuity of the cutting operation.

A first characteristic of the cutting device 100 of the present invention is that: the cutting device 100 comprises an auxiliary chamber 2 and an auxiliary piston 23, the auxiliary piston 23 having a head 24 and a rod 25.

In particular, the auxiliary chamber 2 is arranged above the oscillation chamber 1 and is provided with an opening 20, the opening 20 being predisposed to communicate with a pneumatic supply P1 and having an upper abutment surface 21 and a lower abutment surface 22, while the auxiliary piston 23 is predisposed in the following manner: the head 24 of the auxiliary piston is located inside the auxiliary chamber 2 and the relative rod 25 is connected to the head 13 of the oscillating piston 10 through a hole 110 present in the upper end stop wall 11 of the oscillating chamber 1.

In more detail, the auxiliary chamber 2 and the rod 25 of the auxiliary piston 23 are dimensioned such that, when the pneumatic supply P1 is activated to oscillate the oscillating piston 10 in the oscillation chamber 1 between the lower end stop wall 12 and the upper end stop wall 11, the auxiliary piston 23 oscillates upwards in the auxiliary chamber 2 up to the upper end stop position FC, which is at a distance from the upper abutment surface 21 of the auxiliary chamber 2 and below the upper abutment surface 21 (see, for example, fig. 3B and 6B).

Another characteristic of the cutting device 100 of the invention is that: the cutting device 100 comprises a thrust element 3, the thrust element 3 being predisposed in the auxiliary chamber 2 to be interposed between the head 24 of the auxiliary piston 23 and the surface of the lower abutment surface 22 of the auxiliary chamber 2.

For example, the thrust element 3 may be constituted by a sleeve having a through hole for the sliding passage of the stem 25 of the auxiliary piston 23, the thrust element 3 being shaped so that it can be interposed between the head 24 of the auxiliary piston 23 and the lower abutment surface 22 of the auxiliary chamber 2 and constitute an abutment against the head 24.

In particular, during activation of the pneumatic supply source P1 to pneumatically drive the oscillating piston 10 in the oscillation chamber 1 and thus to oscillate the cutting head L vertically between the lower cutting position L1 and the upper cutting position L2, the thrust element 3 can be pneumatically held in contact with the lower abutment surface 22 by a pneumatic flow entering from the opening 20 of the auxiliary chamber 2, wherein the opening 20 is in communication with the pneumatic supply source P1.

A particularly novel and advantageous aspect of the cutting device 100 of the invention is that the thrust element 3 can be activated after deactivation of the pneumatic supply P1, so as to lift and push the head of the auxiliary piston 23 upwards and thus lift the auxiliary piston 23 upwards, until the auxiliary piston 23 is arranged with its head 24 in abutment with the upper abutment surface 21 of the auxiliary chamber 2, so as to lift the oscillating piston 10 accordingly (the rod 25 of the auxiliary piston 23 is connected to the head 13 of the oscillating piston 10 as mentioned before) and thus lift the cutting bit L above the upper cutting position L2 (see, for example, fig. 4B, 4C, 7B).

In another novel and advantageous aspect strictly related to the preceding one, the cutting device 100 of the invention consists in that the upper end stop wall 11 of the oscillation chamber 1 is configured and predisposed in the body C in such a way that the upper end stop wall 11 can have a static configuration (fig. 2B, 2C, 3B, 3C, 5B, 6B) in a predetermined working position P L during the activation of the pneumatic supply P1 to define an upper end stop limit of the oscillating piston 10 in the oscillation chamber 1, and that, when the pneumatic supply P1 is deactivated and the thrust element 3 is activated to lift, the upper end stop wall 11 can be moved dynamically upwards with respect to the body C to enable the lifting of the oscillating piston 10 until the auxiliary piston 23 reaches a position in which the head 24 of the auxiliary piston 23 abuts against the upper abutment surface 21 of the auxiliary chamber 2 (fig. 4B, 4C, 7B).

Thanks to these particular aspects (auxiliary chamber, auxiliary piston connected to the oscillating piston, thrust element, upper end stop wall of the dynamically moving oscillating chamber), the cutting device 100 of the invention can be such as to lift the cutting head L to a raised position L R above the upper cutting position L2, beyond the thickness of the leather sheet V, and thus to completely extract and disengage from the leather sheet V (fig. 1C, 4A, 4B, 7A, 7B), in correspondence with the deactivation of the pneumatic supply P1, all without requiring any movement or lifting of the entire device or of the body of the device that bears the cutting head.

Accordingly, the cutting device 100 of the present invention effectively solves the problems occurring in the previously proposed cutting devices of the prior art.

Additional and other features and advantageous aspects of the cutting device 100 of the present invention will be set forth below.

In a first preferred possible embodiment, illustrated in fig. 2A to 4C, the cutting device 100 can be predisposed and configured to comprise an elastic element 31, for the purpose of the activation of the raising of the thrust element 3.

The elastic element 31 is predisposed to be interposed between the thrust element 3 and the lower abutment surface 22 of the auxiliary chamber 2.

In particular, the elastic element 31 is configured to be compressible and elastically loadable when the thrust element 3 is pneumatically held in contact with the lower abutment surface 22 by a pneumatic flow entering from the opening 20 of the auxiliary chamber 2 communicating with the pneumatic supply source P1 during the activation of the pneumatic supply source P1.

In this way, the elastic element 31 is in this case placed so as to be able to elastically drive the raising of the thrust element 3 to push the head 24 of the auxiliary piston 23 upwards and, consequently, push and lift the auxiliary piston 23 upwards and bring the relative head 24 against the upper abutment surface 21 after the deactivation of the pneumatic supply P1, and consequently raise the oscillating piston 10 and consequently the cutting head L to the raised position L R, extracting and disengaging from the leather piece V.

In this respect, the thrust element 3 comprises an annular seat 32 open at the bottom, while the elastic element 31 is constituted by a helical spring 31 predisposed in the annular seat 32 so as to be able to come into contact, through a lower end, with the lower abutment surface 22 of the auxiliary chamber 2.

On the basis of the second possible embodiment, for the purpose of the ascending drive of the thrust element 3, the cutting device 100 can be predisposed to comprise: a maintenance opening 27, located between the thrust element 3 and the lower abutment surface 22, in the relative side wall in the vicinity of the lower abutment surface 22 of the auxiliary chamber 2; an auxiliary pneumatic supply PA; and a maintenance duct 26 inside the body C, the maintenance duct 26 being provided in advance in communication with the maintenance opening 27 and the auxiliary pneumatic supply source PA (see fig. 5A to 7B).

In particular, the cutting device 100 is configured so that the automatic pneumatic supply PA is activated as a result of the deactivation of the pneumatic supply P1 of the pneumatic drive system P (fig. 7B), so as to direct the pneumatic flow inside the auxiliary chamber 2 below the thrust element 3 through the maintenance duct 26 and the maintenance opening 27, so as to pneumatically drive the thrust element 3 to rise to push and lift the auxiliary piston 23 against the upper abutment surface 21, and thus to raise the oscillating piston 10, and therefore the cutting head L to the raised position L R, extracting and disengaging from the leather pieces V.

In both of the possible embodiments described above, the cutting device 100 has the following further features.

The cutting device 100 includes: a manipulation chamber 4 within the body C, the manipulation chamber 4 being located between the oscillation chamber 1 and the auxiliary chamber 2; a piston 40, predisposed in the operating chamber 4, having a lower wall 41 and provided with a through hole 42, the through hole 42 being intended for the passage of the stem 25 of the auxiliary piston 23, so as to connect the stem 25 with the head 13 of the oscillating piston 10; a connecting element 43, the connecting element 43 connecting and constraining the piston 40 to the thrust element 3 through the through hole 28 present in the lower abutment surface 22 of the auxiliary chamber 2.

In this way, when the thrust element 3 is pneumatically maintained in contact with the lower abutment surface 22 of the auxiliary chamber 2 by means of a pneumatic flow, entering from the opening 20 of the auxiliary chamber 2 communicating with the pneumatic supply source P1 during the driving of the pneumatic supply source P1, the piston 40 is maintained in a predetermined position with the thrust element 3 by means of the connecting element 43, so that the relative lower wall 41 is positioned in said working position P L to constitute the upper end stop wall 11 of the oscillation chamber 1 and to define the upper end stop limit of the oscillation piston 10 (fig. 2B, 2C, 3B, 3C, 5B, 6B).

Furthermore, thanks to the presence of the connecting element 43 between the thrust element 3 and the piston 40, when the pneumatic supply P1 is deactivated and the thrust element 3 is activated to lift the upper abutment surface 21 of the auxiliary chamber 2, driven by the elastic element 31 or by the auxiliary pneumatic supply PA and thus push and lift the auxiliary piston 23, the piston 40 also rises in the operating chamber 4 and the relative lower wall 41 is displaced upwards, so as to enable the oscillating piston 10 to rise beyond the upper end limit reached in the oscillation stroke and therefore to enable the cutting head L to rise to the raised position L R.

The connecting element 43 comprises a stem 44, hollow inside, and a head 45 at the lower end of the stem 44, the connecting element 43 being predisposed in the operating chamber 4 in such a way that the upper end of the stem 44 is fixed to the thrust element 3 through the passage hole 28 in the lower abutment surface 22 of the auxiliary chamber 2, the head 45 being connected and fixed to the piston 40, while the stem 44 houses slidingly inside it the stem 25 of the auxiliary piston 23.

Another advantageous aspect of the cutting device 100 of the present invention is that the manoeuvring chamber 4 comprises an opening 48 at or near the upper part of the manoeuvring chamber, the opening 48 communicating with the pneumatic supply source P1 of the pneumatic drive system P, so that when the pneumatic supply source P1 is activated, the pneumatic flow enters the manoeuvring chamber 4 and acts on the head 45 of the connecting element 43 to keep the piston 40 pushed downwards and thus keep the lower surface 41 of the upper end stop wall 11 defining the oscillation chamber 1 stationary in the working position P L, thus preventing the impact and abutment of the head 13 of the oscillation piston 10 from causing the piston 40 to displace upwards.

In the embodiments cited above, the cutting device 100 of the invention also has the particular feature described below in relation to the way in which the oscillating piston 10 is pneumatically driven to oscillate in the oscillation chamber 1 between the upper and lower end stop walls 11, 12 to drive the cutting head L to oscillate vertically between the upper cutting position L2 and the lower cutting position L1.

The body C comprises a cylinder 16, while the rod 14 of the oscillating piston 10 is predisposed to be able to slide alternately in the cylinder 16.

Further, the rod 14 of the oscillating piston 10 is shaped to have: two annular portions 141, 142 in sliding contact with the wall of the cylinder 16, and an annular recess 140 included between the two annular portions 141, 142; an inner pipe 17; and the rod 14 is provided with a through hole 18, the through hole 18 being provided in advance in a position below the annular recess 140 to place the outside of the rod 14 in communication with the inner duct 17.

The head 13 of the oscillating piston 10 is then provided with a through hole 130, the through hole 130 being used to place the internal duct 17 of the rod 14 in communication with the second portion 1B of the oscillation chamber 1 comprised between the head 13 of the oscillating piston 10 and the upper end stop wall 11 of the oscillation chamber 1.

Further, the pneumatic drive system P includes: a switching chamber 8 in a portion of the inner wall of the cylinder 16, and a main conduit 81, the main conduit 81 being predisposed in the body C to communicate with the pneumatic supply P1 and with the lower portion of the switching chamber 8; a second duct 82, which is provided in advance in the body C to communicate with the upper part of the opening and closing chamber 8 and the oscillation chamber 1 through a through hole 83 in the lower end stop wall 12 of the oscillation chamber 1; an upper discharge portion S1 and a lower discharge portion S2, wherein the upper discharge portion S1 communicates with the outside in the cylinder 16 at a position above the opening and closing chamber 8, and the lower discharge portion S2 communicates with the outside in the cylinder 16 at a position below the opening and closing chamber 8.

In particular, the annular recess 140 of the rod 14 has dimensions and the positioning of the hole 18 of the rod 14 with respect to the annular recess 140 is such that, as the rod 14 slides alternately inside the cylinder 16, the following conditions and situations are established: when the annular recess 140 of the stem 14 is positioned at the switching chamber 8, the hole 18 of the stem 14 is positioned at the lower drain S2, so that the main duct 81 communicates with the second duct 82 through the annular recess 140 and therefore the pneumatic supply P1 communicates with the first portion 1A of the oscillating chamber 1 between the head 13 and the lower end stop wall 12 of the oscillating piston 10, whereas the second portion 1B of the oscillating chamber 1 between the head 13 and the upper end stop wall 11 of the oscillating piston 10 communicates with the lower drain S2 through the through hole 130 of the head 13 of the oscillating piston 10, the inner duct 17 of the stem 14 and the hole 18 of the stem 14, so that the oscillating piston 10 can be pneumatically pushed up (see for example figures 2B, 2C and 5B), and when the annular recess 140 of the stem 14 is positioned at the upper drain S1 which communicates with both the second duct 82 and at the upper portion of the switching chamber 8, the hole 18 of the stem 14 is in the lower portion of the switching chamber 8 and communicates with the main duct 18, the pneumatic supply source P1 is made to communicate with the second portion 1B of the oscillation chamber 1 between the upper end stop wall 11 and the head 13 of the oscillation piston 10 through the hole 18 of the rod 14, the inner pipe 17 of the rod 14, and the through hole 130 present in the head 13 of the oscillation piston 10, while the first portion 1A of the oscillation chamber 1 between the head 13 and the lower end stop wall 12 of the oscillation piston 10 is made to communicate with the upper drain S1 through the second pipe 82, so that the oscillation piston 10 can be pneumatically pushed down (see, for example, fig. 3B, 3C, and 6B).

For example, a possible operating cycle of the cutting device 100 of the invention is described below, for example starting from the situation illustrated in fig. 2B and 2C, in which the pneumatic supply P1 is activated and the oscillating piston 10 has a relative head 13, the head 13 being in contact with the lower end wall 12 of the oscillation chamber 1, i.e. with the cutting head L in the lower cutting position L1.

In this case, the position of the rod 14 of the oscillating piston 10 with respect to the cylinder 16 of the body C is such that the recess 140 of the rod 14 is positioned at the switching chamber 8, placing the main duct 81 in communication with the second duct 82, while the hole 18 of the rod 14 is positioned in the lower discharge S2.

Thus, the pneumatic supply source P1 communicates via the main duct 81, the switching chamber 8, the second duct 82 and the through hole 83 with the first portion 1A of the oscillation chamber 1 comprised between the head 13 of the oscillation piston 10 and the lower wall 12 of the oscillation chamber 1, while the second portion 1B of the oscillation chamber 1 comprised between the head 13 of the oscillation piston 10 and the upper wall 11 of the oscillation chamber 1 communicates via the hole 130 of the head 13, the inner duct 17 of the stem 14 and the hole 18 of the stem 14 with the lower drain S2.

Therefore, when the second portion 1B of the oscillation chamber 1 above the head 13 of the oscillation piston 10 is connected with the lower discharge portion S2, the pneumatic flow originating from the pneumatic supply source P1 reaches into the first portion 1A of the oscillation chamber 1 below the head 13 of the oscillation piston 10, thus pushing the head 13 upward.

The oscillating piston 10 is thus pushed upwards, whereby the rod 14 slides upwards in the cylinder 16 and the cutting head L is displaced upwards accordingly, the upward displacement of the oscillating piston 10 also determining the raising of the auxiliary piston 23 in the auxiliary chamber 2 via the connecting element 43.

During such ascent, the pneumatic supply source P1 communicates with the cab 4 through the opening 48 of the cab 4 predisposed to communicate with the main duct 81, so that the pneumatic flow enters the cab 4 and maintains the position of the piston 40, thus keeping the position of the lower surface 41 stable, the lower surface 41 constituting, as previously described, the upper end stop wall 11 of the oscillation chamber 1 and determining the working position P L of the upper surface 11, in the same way the pneumatic supply source P1 also communicates with the auxiliary chamber 2 via the relative opening 20, and the pneumatic flow entering the auxiliary chamber 2 thus keeps the thrust element 3 pushed downwards against the lower abutment surface 22 of the auxiliary chamber 2.

When the head 13 of the oscillating piston 10 abuts against the upper end stop wall 11 of the oscillating chamber 1 (see fig. 3B, 3C), the cutting head L reaches its upper cutting position L2, so that the auxiliary piston 23 is in the end stop position FC below the upper abutment surface 21 of the auxiliary chamber 2, while the upward sliding of the rod 14 in the cylinder 16 of the body C determines the condition (see in particular fig. 3C) that the hole 18 of the rod 14 is located at the lower part of the switching chamber 8 and therefore communicates with the main duct 81, and that the recess 140 of the rod 14 is located at both the upper drain S1 and the upper part of the switching chamber 8 and therefore communicates with the second duct 82.

In this case, the main duct 81 communicates with the second portion 1B of the oscillating chamber 1 comprised between the head 13 of the oscillating piston 10 and the upper wall 11 of the oscillating chamber 1 through the through hole 18 of the stem 14, the inner duct 17 of the stem 14 and the hole 130 of the head 13 of the oscillating piston 10, while the first portion 1A of the oscillating chamber 1 below the head 13 of the oscillating piston 10 communicates with the upper discharge portion S1 via the through hole 83 and the second duct 82.

Thus, when the first portion 1A of the oscillation chamber 1 below the head 13 of the oscillation piston 10 is connected with the upper discharge S1, the pneumatic flow originating from the pneumatic supply P1 reaches the second portion 1B of the oscillation chamber 1 above the head 13 of the oscillation piston 10, thus pushing the head 13 upwards, the oscillation piston 10 is thus pushed downwards, so that the rod 14 slides downwards in the cylinder 16 and the cutting head L is displaced downwards, respectively, to return to the previous situation-see figure 2C-i.e. to the lower cutting position L1, while the auxiliary piston 23 returns downwards to abut against the thrust element 3 via the connecting element 43 and the head 13 of the oscillation piston 10 (figure 2C).

The cycle described below is repeated as long as the pneumatic supply P1 is active, thus determining the oscillation of the cutting bit L between the lower cutting position L1 and the upper cutting position P2.

At the moment when it is desired to change the cutting direction and, therefore, to disengage and completely extract the cutting head L from the leather piece V, it is sufficient to deactivate the pneumatic supply P1 and the thrust element 3 is activated to lift, so as to push and lift the auxiliary piston 23 to place the relative head 24 against the upper abutment surface 21 of the auxiliary chamber 2, thus also causing the lifting of the connecting element 43, which displaces the piston 40 upwards, thus causing the oscillation piston 10 to lift, due to the connection of the relative head 13 with the stem 25 of the auxiliary piston 23, beyond the upper end stop height normally reached during oscillation (i.e. beyond the height of the upper end stop wall 11 of the oscillation chamber 1 defined by the lower portion 41 of the piston 40 when positioned in the working position P L), and thus lifting the cutting head L to its position L R, so as to disengage and extract the cutting head L from the leather piece V.

In the first embodiment described above, the activation of the lifting of the thrust element 3 is done automatically and instantaneously thanks to the elastic element 31 interposed between the thrust element 3 and the lower abutment surface 22 of the auxiliary chamber 2, whereas in the second embodiment the activation of the lifting is done by the activation of the auxiliary pneumatic supply PA.