Transfer device for flat substrate in a packaging production machine

Abstract

A transfer device for one or more flat substrates (4, 4a, 4b), which can be inserted between two successive units upstream and downstream (3, 6, 9) in a packaging production machine (1), the device including a bridge (14) with an upper surface (16) providing a junction between the upstream unit (3, 6) and the downstream unit (9). An adjustment device (19) varies a length (L1, L2) of the bridge (14). The bridge (14) is a static apron on which the substrate (4, 4a, 4b) slides, having a fixed transversal end (36) and a mobile transversal end (22). The adjustment device (19) varies a position of the mobile end (22), as a function of a spacing (E1, E2) between the two units.

Claims

1. A transfer device for one or more substrates, the transfer device having a frame and being insertable between two successive units, including an upstream unit and a downstream unit, in a packaging production machine, the upstream unit and the downstream unit being separated from each other by a spacing, the transfer device comprising: a bridge providing a junction between the upstream unit and the downstream unit, the bridge comprising: an adjustment device for varying a length of the bridge; an apron comprising an upper surface on which the one or more substrates slide and a lower flank, the apron being motionless when the packaging production machine is in active operation, the apron comprising a fixed transversal end toward one unit and a mobile transversal end toward the other unit, wherein a position of the mobile transversal end of the apron is configured to be moved in a first direction as a function of the spacing between the two successive units, and wherein the adjustment device comprises at least one slide secured to the frame and at least one slider cooperating with the at least one slide, the at least one slider is secured to lateral sides of the mobile transversal end, and the at least one slide is driven by a motor to longitudinally displace the at least one slider and the mobile transversal end of the apron to vary the length of the bridge; and at least one tensioner comprising a moving member and a transverse bar, the at least one tensioner adjusting a position of the lower flank by moving the moving member and the transverse bar along a linear path in a second direction in relation to the longitudinal displacement of the at least one slider, the second direction being transverse to the first direction.

2. A device according to claim 1, wherein the at least one slider is in the form of lateral nuts, and the adjustment device further comprises: two lateral slides, each in the form of a ball screw, and each rotatably driven by the motor, positioned on either side of the bridge, and secured to the frame.

3. A device according to claim 1, wherein the upper surface of the bridge is flat, smooth and horizontal.

4. A device according to claim 1, wherein the bridge is made of a deformable material.

5. A device according to claim 1, wherein the at least one tensioner keeps the bridge at a constant tension.

6. A device according to claim 5, wherein the moveable member comprises two lateral jacks, each jack positioned in an opposing arrangement on either side of the bridge and fixed to the frame.

7. A device according to claim 1, wherein the fixed transversal end is upstream of and beneath the mobile transversal end.

8. The device according to claim 1, further comprising: a guide having a longitudinal component positioned along the second direction, wherein the movement of the moving member is along the guide in response to the varying of the length of the bridge.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will be better understood and its various advantages and different features will better emerge from the following description, of the nonlimiting embodiment, with reference to the appended schematic drawings, in which:

(2) FIG. 1 represents a synoptic side view of a packaging production machine equipped with a substrate transfer device in a spread position according to the invention;

(3) FIG. 2 represents a perspective view of the device;

(4) FIG. 3 represents a synoptic upper view of the packaging production machine, with the device of FIGS. 1 and 2 in a spread position;

(5) FIG. 4 represents a synoptic upper view of the packaging production machine with the device of FIGS. 1 and 2 in a retracted position;

(6) FIG. 5 represents a side view of the device in a spread position; and

(7) FIG. 6 represents a side view of the device in a retracted position.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(8) As FIGS. 1, 3 and 4 illustrate, a packaging production machine (1) converts a substrate or a web material (2), here being flat cardboard. The machine (1) comprises a converting unit, which is, in this case, a diecutting platen press (3).

(9) The web (2) enters into the press (3) through its upstream transversal side. The web (2) arrives in the press (3) with an intermittent speed, which is rated by virtue of an infeed station (not represented). Upstream of the press (3) and therefore of the infeed station, the machine (1) may also have, by way of example, units such as printing units, means for checking quality and register, embossing units, and so on (not represented).

(10) The press (3) cuts the web (2) and delivers the substrate in the form of blanks (4), here therefore being of flat cardboard. The blanks (4) leave the press (3) through its downstream transversal side. The direction of advance or of progress (arrows F in the figures) of the web (2) and of the blanks (4) in the longitudinal direction indicates the upstream direction or the downstream direction.

(11) The machine (1) comprises a unit, in the form of a driving arrangement (6), which is placed downstream of the press (3). This arrangement (6) comprises, a lower drive roller (7), driven in rotation by a motor and comprises just one or a series of pressure rollers (8), arranged above, bearing on the roller (7).

(12) The blanks (4) are engaged, held and driven between the roller (7) and the roller or rollers (8). The arrangement (6) ensures an active transfer of the blanks (4). The arrangement (6) is intended to draw the blanks (4), in succession one after the other, from the press (3), in the longitudinal direction (F), from upstream to downstream.

(13) The machine (1) comprises a transport unit, known under the name of vacuum transport (9), which is placed downstream of the press (3), after the driving arrangement (6). This vacuum transport (9) comprises a conveyor with one or more lower endless belts (11) with orifices. A vacuum box (12), connected to a vacuum source, draws the blanks (4) against the belt or belts (11).

(14) The blanks (4) are placed, one after the other, with a short gap between them on the upper face of the belts (11). The vacuum transport (9) ensures an active transfer of the blanks (4). The belt or belts (11) drive the blanks (4), in the longitudinal direction (F), from upstream to downstream.

(15) The spacing (E1 and E2) between the two units, the driving arrangement (6) and the vacuum transport (9) are variable from one machine to another. These spacings (E1 and E2) are a function of the respective positioning and the length of these two units (6 and 9), incorporated in the packaging production machine (1).

(16) The machine (1) comprises a waste stripping unit (not represented), which is placed downstream after the vacuum transport (9). In a controlled manner, this unit eliminates the cardboard wastes precut from the blanks (4).

(17) The packaging production machine (1) comprises a transfer device according to the invention (13) for one or more flat substrates, i.e. the blanks (4). The device (13) can be inserted between two successive units, an upstream unit and a downstream unit. The device (13) is intended to convey the blanks (4) from an upstream unit in the form of the diecutting platen press (3) to a downstream unit in the form of the waste stripping unit.

(18) More precisely, in a particularly interesting embodiment, the machine (1) may comprise, in order, from upstream to downstream, the diecutting platen press (3), the driving arrangement (6), the device (13), the vacuum transport (9), and the waste stripping unit. In other words, the device (13) is placed downstream at the output of the driving arrangement (6) and upstream at the input of the vacuum transport (9).

(19) The device (13) provides a passive transfer of the blanks (4). For this, and as can be seen in the figures, the device (13) comprises a bridge (14) providing a junction between the upstream unit, i.e. the driving arrangement (6), and the downstream unit, i.e. the vacuum transport (9). The junction bridge (14) is in the form of an inverted L. The bridge (14) is similar to an apron, with an upper surface (16) and a lower flank (17).

(20) The blanks (4) pass slidingly on the upper surface (16). The upper surface (16) of the bridge (14) may be preferentially substantially flat. In this embodiment, the upper surface (16) is substantially horizontal. The upper surface (16) guarantees a continuous plane between a surface located inside the press (3), the driving arrangement (6) and the vacuum transport (9). The blanks (4) thus circulate in this plane following the longitudinal direction (F).

(21) For the blanks (4) to be displaced by their own inertia, the upper surface (16) may be advantageously substantially smooth. The upper surface (16) is antistatic. The upper surface (16) is non-adherent and may have a low friction coefficient. In this way, the blanks (4) will slide without the risk of their front flaps catching.

(22) The lower flank (17) of the bridge (14) is placed below the arrangement (6) and is substantially vertical or substantially parallel to the downstream transversal side of the press (3). The transition between the upper surface (16) and the lower flank (17) is provided by a transversal bar (18) forming an edge. The lower flank (17) of the bridge (14) thus serves as storage for the unused length of the bridge (14), for adjusting the length (L1 and L2).

(23) The bridge (14) may favorably be made of a material that may be capable of being deformed. By way of example, the surface (16) of the bridge (14) may be made of thermoplastic polyurethane with a thickness substantially equal to 1 mm. This softness or flexibility allows for the passage of the bar (18). Such a material makes the bridge (14) able to be easily spread, then retracted, according to the desired length (L1 and L2).

(24) As FIGS. 3 to 6 show, a length (L1 and L2) of the device (13), and more precisely of the upper surface (16) of the bridge (14), varies according to the spacing (E1 and E2) that exists between the two successive units, the upstream unit, i.e., for example, the arrangement (6), and the downstream unit, i.e., for example, the vacuum transport (9). All the lengths between L1 and L2 can be chosen and then set by the operator.

(25) The machine (1) may also favorably incorporate a downstream unit i.e., for example, the vacuum transport (9) with variable length. In this case, the length (L1 or L2) of the device (13) added to the length of the downstream unit (9) may be constant (T). The vacuum transport (9) can thus have a variable length. It is possible to choose the length (L1, L2) of the device (13) such that the latter when added to the length of the vacuum transport (9) remains a constant (T).

(26) The length (L1 or L2) of the bridge (14) can be chosen as a function of the size of the blanks (4a and 4b). In this way, the blank (4a and 4b) always retains a front and/or rear region driven by the arrangement (6) and/or by the vacuum transport (9).

(27) In the case that can be seen in FIG. 3, the blanks (4a) have a greater length (“long grain” cardboard). The operator will extend the length (L1) of the bridge (14) and will shorten the length of the vacuum transport (9), keeping the overall length (T) constant. In the case that can be seen in FIG. 4, the blanks (4b) have a shorter length (“short grain” cardboard). The operator will shorten the length (L2) of the bridge (14) and will extend the length of the vacuum transport (9), keeping the overall length (T) constant.

(28) The transfer device (13) thus comprises adjustment means (19) for varying this length (L1 and L2) of the bridge (14). Using these adjustment means (19), the operator adjusts the length (L1 and L2) of the bridge (14), so that the latter corresponds to the spacing (E1 and E2). For a good circulation and holding of the blanks (4, 4a and 4b), a spacing value (E1 or E2 or intermediate) is equal to a length (L1 or L2 or intermediate) of the bridge (14).

(29) Preferably, the adjustment means (19) may comprise at least one slider joined to the bridge (14). In the present case, two sliders may be in the form of two lateral nuts (21a and 21b), positioned on either side of the bridge (14). The two nuts (21a and 21b) may advantageously each be secured to a transversal, upper, downstream and mobile end (22) of the bridge (14), laterally, i.e. on the operator's side and the side opposite the operator's side.

(30) Favorably, the adjustment means (19) may comprise at least one slide fixed to a frame (not represented) of the device (13). In the present case, two lateral slides may be in the form of two ball screws (23a and 23b), positioned on either side of the bridge (14). The two screws (23a and 23b) may preferably each be secured laterally, i.e., operator's side and opposite the operator's side, to the frame (not represented) of the device (13), while remaining able to rotate. The two screws (23a and 23b) are arranged parallel to one another, in the same plane as that formed by the upper surface (16), substantially horizontally.

(31) The two screws (23a and 23b) may be rotatably driven by a single motor (24), arranged on the operator's side. Two gears (26a and 26b), placed on the operator's side and on the opposite operator' side, and a return shaft (27) allow the movement to be transmitted from the operator's side to the side opposite the operator's side.

(32) The slider, i.e. the two nuts (21a and 21b), may cooperate with the slide, i.e. the two screws (23a and 23b). When the two screws (23a and 23b) are rotated by the motor (24), they drive the two nuts (21a and 21b) in longitudinal displacement (arrows D and I in FIGS. 2, 5 and 6).

(33) When the two screws (23a and 23b) rotate in a first direction, the two screws (21a and 21b) are displaced upstream (D), driving the end (22) of the bridge (14) in the upstream direction. The length of the bridge (14) reduces and changes from a value L1 to L2. When the two screws (23a and 23b) rotate in a second direction opposite to the first direction, the two nuts (21a and 21b) are displaced downstream (I), driving the end (22) of the bridge (14) in the downstream direction. The length of the bridge (14) increases and changes from a value L2 to L1.

(34) The longitudinal displacement (D and I) of the two nuts (21a and 21b) is stabilized by two rules (28), securely attached to the frame of the device (13). Each of the two rules (28) corresponds and is respectively parallel to each of the two screws (23a and 23b). Each of the two nuts (21a and 21b) comprises a lower part (29) sliding on the rule (28).

(35) To compensate for the length variations (L1 and L2) of the bridge (14) and to be able to keep the bridge (14) at a constant tension, the device (13) may preferably comprise tension means (31). Advantageously, the tension means (31) may comprise two lateral jacks (32a and 32b). These two jacks (32a and 32b) may be positioned laterally on either side of the bridge (14), and secured to a frame of the device (13). The two jacks (32a and 32b) are provided, mounted vertically, at the lower flank (17), on the operator's side and on the side opposite the operator's side. Each of the two jacks (32a and 32b) comprises a mobile piston (33a and 33b) oriented downwards.

(36) The end portion of each of the pistons (33a and 33b) ends with a bearing (34a and 34b). Each of the two bearings (34a and 34b) holds a transversal rod (35). The rod (35) ensures the transition between the lower flank (17) of the bridge (14) and a transversal, lower, upstream and fixed end (36) forming a transversal fastening for securing the bridge (14) to the frame. The fixed transversal end (36) is located upstream and below the mobile transversal end (22). The lower flank (17) and the fixed end (36) are retracted under the upper surface (16) of the bridge (14).

(37) By forming an edge, the rod (35) constitutes a return point or edge for the bridge (14). Each of the two bearings (34a and 34b) slides vertically (arrows B and H in FIGS. 2, 5 and 6) in a guide (37a and 37b).

(38) As FIGS. 2 and 5 show, when the two bearings (34a and 34b) and the two pistons (33a and 33b) of the two jacks (32a and 32b) move down by sliding vertically (B) in the two respective guides (37a and 37b), the rod (35) moves down. The two ball screws (23a and 23b) simultaneously return the two nuts (21a and 21b) in the upstream direction, and the rod (35) is thrust downward under the action of the two jacks (32a and 32b). The length of the upper surface (16) of the bridge (14) decreases (from L1 to L2).

(39) Conversely, (see FIG. 6), when the two bearings (34a and 34b) and the two pistons (33a and 33b) of the two jacks (32a and 32b) move up by sliding vertically (H) in the two respective guides (37a and 37b), the rod (35) rises. The two ball screws (23a and 23b) simultaneously return the two nuts (21a and 21b) in the downstream direction, and the rod (35) is returned upward. The length of the upper surface (16) of the bridge (14) increases (from L2 to L1).

(40) Under the action of the two jacks (32a and 32b), the tension of the bridge (14) is kept constant, regardless of the lengths (L1, L2 or intermediate) of the bridge (14).

(41) The present invention is not limited to the embodiments described and illustrated. Many changes can be made, without in any way departing from the framework defined by the scope of the set of claims.