The present invention relates to a panel cutting machine.
More specifically, the present invention relates to a machine for cutting panels used in the manufacture of furniture, to which the following description refers purely by way of example.
A machine for cutting furniture panels normally comprises a horizontal table supporting the panels; a push or gripper carriage for moving the panels along the table in a first direction parallel to the table; and a panel cutting tool movable in a second direction perpendicular to the first direction.
The push or gripper carriage and the cutting tool are guided respectively by a first guide and a second guide perpendicular to the first guide.
The push carriage normally runs along a first guide comprising two rails, which extend over the table, are parallel to the first direction, and support opposite ends of the carriage.
In known embodiments, the carriage comprises wheels, which roll along the rails and support the thrust acting on the carriage; and two toothed pinions, each engaging a respective rack and which move the carriage in the first direction.
To improve cutting of the panels, a cutting machine has recently been proposed in which the grippers on the carriage slide along relative guides, which may be horizontal and perpendicular to the forward travelling direction of the carriage, or horizontal and parallel to the forward (or reverse) travelling direction of the carriage, or vertical with respect to the table supporting the panels for cutting. In other words, in this solution, each gripper is movable, by means of appropriate mechanisms, along three Cartesian axes with respect to the carriage to which it is fitted, so as to permit complex, preset cutting schemes in cooperation with the other grippers.
Though undoubtedly an improvement as compared with existing machines, the cutting machine described is extremely expensive and difficult to maintain, on account of each gripper being operated by respective actuators, which are therefore complicated to control.
Moreover, for certain cutting schemes, the machine described is fairly limited. In particular, to ensure acceptable cutting quality, operation of the grippers should provide for a certain amount of tolerance which currently used complex actuating mechanisms do not allow.
It is an object of the present invention to provide a panel cutting machine of straightforward design, and which provides for faster performance of cutting schemes comparable in complexity to that of the machine briefly described above.
According to the present invention, there is provided a cutting machine as claimed in claim 1.
A number of non-limiting embodiments of the present invention will be described by way of example with reference to the accompanying drawings, in which:
Number 10 in
Cutting machine 10 comprises a first system S1 for handling panels P.
More specifically, first system S1 extends along an axis A1 (
Table 12 defines a work area AL of first system S1.
Table 12 ideally continues in known manner in the form of a number of supporting surfaces 15 beyond a cutting section 14 described in detail later on.
Panels P are held firmly during the cutting operation by a pressure device PR located in known manner at cutting section 14. For the sake of simplicity, pressure device PR is only shown in
An operator (not shown) can therefore move in known manner between supporting surfaces 15 to turn and position panels P manually as required with respect to cutting section 14.
First system S1 defines a top system by which to grip and push panels P.
First system S1 comprises a top carriage 16 for feeding panels P in a direction parallel to table 12 and to axis A1, as indicated by the two-way arrow F1; and a cutting tool 17 forming part of cutting section 14, and which travels in a direction, as indicated by the two-way arrow F2, parallel to table 12 and perpendicular to arrow F1 and to axis A1 (
The term “work area AL” is used here to indicate the area whose transverse dimensions are defined by the useful transverse extension E of top carriage 16. The useful transverse extension E of top carriage 16 of first system S1 is substantially equal to the extension of the cutting line Tr.
Carriage 16 is supported on a guide 18 comprising two parallel top longitudinal members 19 located over table 12 and parallel to arrow F1 and table 12; and cutting tool 17 is carried on a carriage 20 located beneath table 12 and which travels along two guides 20a parallel to arrow F2 and to table 12.
More specifically, cutting tool 17 comprises a blade 21 projecting above table 12 through a slit 22 formed in carriage 20.
The drive of cutting tool 17 is known and therefore not described in detail.
The drive (not shown in FIGS. 1 to 3) of carriage 16 comprises in known manner two electric motors, each of which rotates a respective toothed pinion meshing with a respective rack extending the full length of the longitudinal member 19 to which it is fitted (see the description relative to FIGS. 4 to 7). Carriage 16 is fitted in known manner with a number of grippers 23.
What is stated below relative to a generic gripper 23 applies to all the grippers 23A, 23B, 23C, 23D, 23E, 23F, 23G, 23H on carriage 16 (see
As shown in FIGS. 1 to 3, at gripper 23, carriage 16 comprises a bracket 24 projecting towards cutting section 14.
A main body 23a is hinged to bracket 24 by a hinge 25, and can be raised or lowered by an actuator 26 integral with carriage 16. The rod 26a of actuator 26 acts on an arm 27 projecting from main body 23a; for which purpose, the end of rod 26a is connected to arm 27 by an articulated joint 28.
Gripper 23 comprises a fixed bottom jaw 29 integral with main body 23a; and a movable top jaw 30 hinged to main body 23a by a hinge 31.
Movable top jaw 30 is moved towards or away from fixed bottom jaw 29 by an actuator 32, the rod 32a of which is extracted or withdrawn under the control of an electronic central control unit (not shown), and the body of which is carried by main body 23a of gripper 23.
Movable top jaw 30 is obviously moved towards fixed bottom jaw 29 to grip one end of a pack P of panels, as shown in
As shown in
Operation of first system S1 is easily deducible from the foregoing description. More specifically, the pack P of panels, pushed manually by the operator from supporting surfaces 15 to cutting section 14, is gripped by the number of grippers 23 lowered by actuators 26 to cover the width of pack P.
For example, as shown in
In the example shown, pack P1 of panels has a transverse dimension T1 and a longitudinal dimension L1.
The first embodiment of the present invention in FIGS. 1 to 3 is substantially characterized by comprising a second system S2 for handling panels P, and which is located beneath work area AL.
Second system S2 is similar to first system S1.
In fact, second system S2 also extends along axis A1 (
Second system S2 defines a bottom system by which to grip and push panels P.
Second system S2 comprises a bottom carriage 39 for feeding panels P in a direction parallel to table 12 and to axis A1, as indicated by the two-way arrow F1.
Carriage 39 is supported on a guide 40 comprising two bottom longitudinal members 41 located beneath table 12 and parallel to arrow F1 and table 12.
The drive (not shown) of carriage 39 comprises in known manner two electric motors, each of which rotates a respective toothed pinion meshing with a respective rack extending the full length of the longitudinal member 41 to which it is fitted.
Carriage 39 is fitted in known manner with a number of grippers 42.
What is stated below relative to a generic gripper 42 applies to all the grippers 42A, 42B, 42C, 42D, 42E, 42F, 42G, 42H on carriage 39.
As shown in FIGS. 1 to 3, at gripper 42, carriage 39 comprises a bracket 43 projecting towards cutting section 14.
Two arms 46 and 47 are hinged to bracket 43 by respective hinges 44 and 45, and are rotated by an actuator 48, the body of which is hinged to bracket 43 by a hinge 48b.
A main body 42a of gripper 42 is hinged to the two arms 46, 47 by two hinges 49 and 50.
As shown in
As shown in
Given the way in which they are hinged, arms 46 and 47 are obviously parallel to each other at all times when moving main body 42a.
Gripper 42 comprises a fixed bottom jaw 52 integral with main body 42a; and a movable top jaw 53 hinged to main body 42a by a hinge 54.
Movable top jaw 53 is moved towards or away from fixed bottom jaw 52 by an actuator 55 hinged to body 42a by a hinge 55b, and the rod 55a of which is extracted or withdrawn under the control of the electronic central control unit, and is hinged to movable top jaw 53 by a hinge 55c.
Movable top jaw 53 is obviously moved towards fixed bottom jaw 52 to grip one end of a pack P of panels, as shown in
As before, corridors 33A-33H between rollers 11 allow grippers 42 to move towards cutting section 14 to pick up pack P of panels.
Operation of second system S2 is easily deducible from the foregoing description. More specifically, the pack P of panels, pushed manually by the operator from supporting surfaces 15 to cutting section 14, is gripped by the number of grippers 42A-42H raised by actuators 48 to cover the width of pack P.
For example, as shown in
In the example shown, pack P2 of panels has a transverse dimension T2 and a longitudinal dimension L2.
Operating as described above, numerous cutting schemes can be performed as a function of the transverse and longitudinal dimensions of packs P1 and P2 of panels.
More specifically, the two systems S1 and S2 are independent, and can simultaneously perform different cutting schemes on two packs P1 and P2 of panels, and both using the same work area AL, which originally was only used by first system S1.
In other words, dimensions T1 and T2 of respective packs P1 and P2 of panels determine automatic activation or deactivation of grippers 23A-23H and 42A.42H, so that activation of certain grippers 23A-23H automatically deactivates the complementary grippers 42A-42H, to perform the desired cutting schemes using cutting tool 17.
Obviously, activation or deactivation of grippers 23A-23H and/or grippers 42A-42H, and operation of carriage 16 and/or 39 are controlled by the electronic central control unit (not shown) as a function of the transverse dimensions T1 and T2 of respective packs P1 and P2 of panels, and possibly also as a function of other parameters.
For which purpose, sensors (not shown) may be provided at work area AL or elsewhere to determine the transverse dimensions T1, T2 of packs P1, P2 of panels. The data acquired is then transmitted to the electronic central control unit, which accordingly, and possibly also on the basis of other parameters, controls lowering or raising of grippers 23A-23H and/or grippers 42A-42H and operation of carriage 16 and/or 39.
Obviously, in the event of a change in the transverse dimensions T1, T2 of respective packs P1, P2 of panels, the electronic central control unit again accordingly selects which grippers 23A-23H and 42A-42H to lower or raise with respect to work area AL, so as to grip packs P1 and P2 of panels and feed them in the direction indicated by two-way arrow F1.
As will be obvious to anyone skilled in the art, as opposed to one system S2, an embodiment (not shown) of cutting machine according to the invention may comprise a number of side by side systems 52.
In the second embodiment shown in FIGS. 4 to 7, first system S1 for handling panels P is practically the same, whereas the component parts of second system S2 differ.
First system S1 is therefore not described as a whole, and, where necessary, reference is made to the description given of it in the first embodiment with reference to FIGS. 1 to 3.
Unlike the first embodiment in FIGS. 1 to 3, however, the second embodiment in FIGS. 4 to 7 comprises a drive 56 for driving carriage 16 of first system S1.
As shown in
Rotation of toothed pinions 58a, 59a, controlled by the electronic central control unit (not shown), moves carriage 16 as required in the direction indicated by two-way arrow F1, as described previously with reference to the first embodiment in FIGS. 1 to 3.
System S2 in FIGS. 4 to 7 comprises a first carriage 62 mounted to slide along one of the two longitudinal members 19A, 19B (
System S2 also comprises a second carriage 68 carried by first carriage 62, and which, by means of a guide 69, also advantageously defined by two “dovetail” guide members (
As shown in
As stated, rotation of toothed pinion 71 in either direction moves second carriage 68 with respect to first carriage 62 in either of the senses indicated by arrow F2.
As shown particularly in
Movable top jaw 75 is moved towards or away from fixed bottom jaw 74 by an actuator 77, the rod 77a of which is extracted or withdrawn as commanded by the electronic central control unit. The body of actuator 77 is hinged to main body 73a of gripper 73 by a hinge 77b, and rod 77a is connected to movable top jaw 75 by a hinge 77c.
Movable top jaw 75 is obviously moved towards fixed bottom jaw 74 to grip one end of pack P of panels.
In the
In the
Systems S1 and S2 therefore cooperate to permit the cutting scheme, shown purely by way of example, in
That is, grippers 23A-23D of first system S1 are lowered to pick up a pack P3 of panels, while grippers 23E-23H are raised to allow second carriage 68 of second system S2 into work area AL to pick up a pack P4 of panels.
Pack P4 of panels is picked up by electric motor 65 moving first carriage 62 in the direction indicated by arrow F1.
As in the first embodiment in FIGS. 1 to 3, both systems S1, S2 can work simultaneously in the same work area AL to handle respective packs P3, P4 of panels. As stated relative to the first embodiment, sensors may also be provided in the second embodiment in FIGS. 4 to 7, to determine the transverse dimensions of packs P3, P4 of panels.
As opposed to one system S2 alongside system S1, a further embodiment may obviously comprise another system S2 on the opposite side to the one shown in FIGS. 4 to 7.
Complex cutting machines may also be conceived employing simultaneously one or more systems S2 as shown in FIGS. 1 to 3 (first embodiment) and/or one or more systems S2 as described with reference to FIGS. 4 to 7 (second embodiment).
The advantages of the cutting machine according to the present invention can be summed up in enabling simultaneous handling of packs P1, P2, P3, P4 by two systems S1, S2, which operate independently but using the same work area AL. This provides for a high degree of simplicity and versatility in the handling and cutting of packs of panels, using extremely straightforward, time-tested means.
Number | Date | Country | Kind |
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BO2003A000501 | Aug 2003 | IT | national |