FR2676947A1 - Numerical-control machine for cutting metal sheets and tubes - Google Patents

Abstract

Numerical cutting machine, characterised in that the transverse beam (3) which it possesses, fitted with tool holders (4) serving for cutting the metal sheets flat, is prolonged so as to support an additional tool holder (7) located facing a tube (TB) formed for cutting and normally fixed at Y, whereas means (8-9) are provided for supporting the tube and driving it rotationally about an axis parallel to the travelling path, in a substantially fixed longitudinal position.

Description

MACHINE FOR CUTTING SHEETS AND TUBES WITH CONTROL
DIGITAL.

The invention relates to numerically controlled cutting machines, which use a cutting torch (flame cutting) or a plasma torch (plasma cutting) as cutting tool.

Known machines include a longitudinal raceway (X axis) and a transverse beam (Y axis) movable in longitudinal translation. A master tool holder and several slave tool holders are slidably supported along the beam. The movement in Y of the master tool holder and the movement in X of the beam are determined by a numerical control programmed so that the trajectory of the master tool holder corresponds to the desired cut. The slave tool holders are secured to the master tool holder by a transmission member for the simultaneous cutting of several parts in the sheet metal.

Appropriate software is used to calculate the flat sections of different volumes to be produced in sheet metal work and their intersections, for example cylinder-cylinder, plane-cylinder, cone-cylinder, etc. and to determine the X and Y components of the cutting speed. which should be used, in particular depending on the thickness of the sheet to be cut.

In certain applications, in particular the cutting of sections or tubular segments and of the intersections necessary for the connections, it would be advantageous to be able to make a volume cutting on the already formed tube.

The known methods for this purpose are either artisanal (use of a portable torch which is moved on the surface of the tube), or very complex (use of lathe-type machines in which a mandrel rotates the tube in front of the cutting tool and calculates the components of the cutting speed according to parameters such as the angular speed of rotation and the diameter of the tube).

The subject of the invention is a simplified method of cutting from a tubular volume capable of allowing digital control of movements from software identical to that which is used for cutting the corresponding presses from a flat sheet.

This process mainly consists in using a mobile tool holder in X and causing a relative movement between the surface of the tube and the tool holder, with a linear speed independent of the tube diameter and identical to the transverse speed that the tool holder should have. movable in Y to perform the cut of the flat part of the form to be produced, while moving the tool holder in X at the longitudinal speed that it should have to perform said cut of the flat part.

According to a preferred embodiment, the tool holder is fixed in Y and the tube is rotated around an axis parallel to X with a tangential speed equal to said linear speed.

The invention also relates to a digital cutting machine of the kind defined above, characterized in that, with a view to implementing the above process, the transverse beam which it comprises, provided with tool holders used for cutting flat sheets, is extended so as to support an additional tool holder located opposite a tube formed to cut and normally fixed in Y, while means are provided to support the tube and cause it to rotate around d 'an axis parallel to the raceway, in a substantially fixed longitudinal position.

Other particularities, as well as the advantages of the invention will become clear in the light of the description below.

In the attached drawing
Figures 1, 2 and 3 represent respectively,
elevation, top and side view, a
digital cutting machine conforms to a mode
preferred embodiment of the invention
Figure 4 is a schematic view of the device to
motorized rollers which drives the rotating tube
Figure 5 is a schematic view of the device to
loose rollers that cooperate with the device
drive of Figure 4; and
FIG. 6 is a floating stop for maintaining
the longitudinal position of the tube.

In FIGS. 1 to 3, it can be seen that the machine comprises, in a manner known per se, a fixed base on which the flat sheet metal TP is placed at a certain height, a longitudinal raceway (rails 1, 2, FIG. 2) and a gantry comprising a transverse beam 3 on which are guided the tool carriages, of which only one (4) has been shown. The transverse movement of these carriages along the beam is controlled by a first motor (not shown and contained in the tool holder 4) by means of an endless transmission ribbon 6.

The longitudinal movement of the gantry is controlled by a second motor MX contained in the longitudinal guide train.

The constitution and the operation of the part of the machine which has just been briefly described are conventional and conform to what has been said above. Software associated with digital control makes it possible in particular to cut the developed flat of a tube by determining the transverse (Vy) and longitudinal (vox) speeds of movement of the tools according to the only thickness of the sheet (for a metal given).

According to the invention, the gantry is extended upstream of the block 5 relative to the flat cutting part, the extension of the beam 3 supporting an additional tool holder 7 which is either capable of being locked in a position where the tool is located in the vertical axial plane of the TB tube, or to be secured to the ribbon 6 (by means not shown) to be driven in Y by the first aforementioned motor. In both cases, the tool holder 7 is adjustable in height within wide limits by means not shown. This adjustment is permanent during cutting, the distance between the end of the cutting tool and the surface of the tube can be kept constant by a servo (not shown).

The TB tube is capable of being rotated about its axis by a tacker with two motorized rollers (8, FIG. 3) placed in the vicinity of its end close to the tool holder 7 and rests on a free roller tacker (9 , Figure 3).

Each tacker consists of two rollers (80-81 and 9091 respectively) mounted on a carriage (82-92) arranged to allow adjustment of the spacing between the two rollers of the torque. Each carriage can slide on rails 10-11 in order to adjust the longitudinal position of the TB tube.

A longitudinal floating stop 13 is also supported on the same rails 10-11 in a sliding manner.

The latter (Figures 3 and 6) has a rule 130 resting on the edge of the tube at the end opposite the cutting end. This rule is articulated, with two degrees of freedom, around an axis 131 which pivots at one end of an arm 132 itself articulated at the end of a fixed axis 133 mounted at the upper end of a vertical support 134 itself articulated at its base on a carriage 135 capable of sliding on the rails 10-11 for adjusting the longitudinal position of the stop.

 This stop makes it possible to avoid jamming of the tube in the event of irregularities in the shape of the tube which tend to cause a certain longitudinal clearance for cutting a straight section or not in a tube.

The tool holder 7 is blocked and the numerical control uses the same software as for the flat cutting of the developed part of the tube.

In operation, the two motorized rollers drive the tube in rotation at exactly the same tangential speed Vy as that which is fixed by said software for the displacement in Y of the flat cutting tool holder.

We obviously
DQ = Vy = do
2 2
D and d being the respective diameters of the tube and the drive rollers and Q and o the respective angular velocities From where o = Vy x 2
d which determines the angular speed of the roller drive motor to be imposed by the numerical control. This speed is independent of D.

l'écart angulaire entre les points de contact des galets avec le tube étant alors égal à 900. Advantageously, the spacing E between the axes of the drive rollers is maintained at a value equal to

the angular difference between the points of contact of the rollers with the tube then being equal to 900.

The control of the displacement in X of the beam 3 is ensured by the same motor and with the same software as for the flat cutting of the corresponding press.

If it is desired to make a cut with chamfering, it suffices to tilt the cutting nozzle at the end of the torch, the latter (70) being, for this purpose, mounted orientable about a parallel axis (71) to The direction
Y (Figure 3).

This operating mode also makes it possible to carry out a tube-tube intersection with a large opening for a branching.

In a variant, which will be preferred, when the opening of the tap being of small size, it is important that the cut is not made radially, but vertically, the tube will be kept fixed in rotation, while the tool holder 7 will be secured to the transmission ribbon, therefore moved in Y at the same linear speed as for cutting the corresponding flat bench.

 The beam 3 will obviously undergo the same displacement in X as for said cutting of the flat press. The height of the tool must be controlled to follow the shape of the surface of the tube.

Ultimately, the machine of the invention makes it possible, using the same software, to perform both the cutting of flat sheets intended in particular for forming tubular boilermaking as well as performing the direct cutting in volume on the tube already formed.

It goes without saying that various modifications may be made to the devices described and shown, without departing from the spirit of the invention.

Claims (10)

1. simplified method of cutting in a tubular volume, capable of allowing the numerical control of movements from software identical to that which is used for cutting the corresponding presses in a flat sheet, characterized in that it consists in using a mobile tool holder in X and cause a relative movement between the surface of the tube and the tool holder with a linear speed independent of the diameter of the tube and identical to the transverse speed that the mobile tool holder in Y should have to cut the developed flat of the form to be produced, while moving the tool holder in X at the longitudinal speed that it should have to perform said cutting of the flat press. 2. Method according to claim 1, characterized in that the tool holder is fixed in Y and the tube is rotated about an axis parallel to X with a tangential speed equal to said linear speed. 3. Method according to claim 1 or 2, characterized in that the tube cutting tool is orientable around an axis parallel to the direction Y. 4. Method according to claim 2, characterized in that the distance between the end of the tube cutting tool and the surface to be cut is kept constant during the rotation of the tube. 5. Method according to claim 1, characterized in that the tube is locked in rotation while the tool holder is driven in Y at said linear speed. 6. digital cutting machine for the implementation of the method according to claims 1 to 5, characterized in that the transverse beam (3) which it comprises, provided with tool holders (4) used for cutting sheets to flat, is extended so as to support an additional tool holder (7) located opposite a tube (TB) formed to cut and normally fixed in Y, while means (8-9) are provided to support the tube and drive it in rotation about an axis parallel to the raceway, in a substantially fixed longitudinal position.  7. Machine according to claim 6, characterized in that said tube support and drive means comprise a pair of drive rollers (80-81) with axes parallel to direction X and of position adjustable in said direction. 8. Machine according to claim 7, characterized in that the angular spacing of the points of contact of said rollers with the tube is maintained at a value of the order of 900. 9. Machine according to claim 7, characterized in that said support and drive means further comprise a pair of free rollers with axes parallel to the direction X and on which the tube rests. 10. Machine according to one of claims 7 to 9, characterized in that said substantially fixed longitudinal position of the tube is ensured by means of a floating stop (130-135).