ROTARY-TOOL MANDREL, UNIT FOR CONVERTING A FLAT SUBSTRATE, AND OPERATING METHOD

Abstract

A rotary-tool mandrel for a unit for converting a flat substrate, on which a sleeve (13) is intended to be fitted, the mandrel includes a cylindrical core (14), a peripheral wall (17) that is able to take up a rest position and a locking position by exerting a radial pressure on the sleeve (13) in order to lock it in position on the mandrel (12), a pressure fluid circuit (21) provided between the peripheral wall (17) and the cylindrical core (14) for exerting the radial pressure on the sleeve (13), and a cooling fluid circuit (24) for allowing a fluid to flow in the region of the cylindrical core (14) and for cooling the mandrel (12).

Claims

1. A rotary-tool mandrel for a unit for converting a flat substrate, the mandrel being configured to receive a sleeve thereon, the mandrel comprising: a cylindrical core; a peripheral wall, that is able to take up a rest position and a locking position by exerting a radial pressure on the sleeve in order to lock the sleeve in position on the mandrel; a pressure fluid circuit provided between the peripheral wall and the cylindrical core for exerting the radial pressure on the sleeve; and a cooling fluid circuit for allowing a fluid to flow in the region of the cylindrical core and for cooling the mandrel.

2. (canceled)

3. The mandrel according to claim 1, wherein the pressure circuit and the cooling circuit are connected together.

4. The mandrel according to claim 1, wherein a docking port for the cooling circuit is arranged at a front end of the mandrel, and a docking port for the pressure circuit is arranged at a rear end of the mandrel.

5. The mandrel according to claim 4, wherein the docking ports are aligned along an axis of rotation the mandrel.

6. The mandrel according to claim 4, wherein each docking port comprises a connection element of the mandrel configured to engage with a complementary connection element of the conversion unit in order to connect the pressure circuit to the cooling circuit.

7. The mandrel according to claim 6, wherein the connection elements and the complementary connection elements are of the quick-connector type, taking up a closed-off position when the connection elements and the complimentary connection elements are disconnected, and taking up an open position, allowing the passage of a fluid, when the connection elements and the complimentary connection elements are connected.

8. The mandrel according to claim 1, wherein the pressure circuit has a portion in the form of a tube around the cylindrical core and coaxial with the axis of rotation of the mandrel.

9. The mandrel according to claim 1, wherein the pressure circuit has at least one axial duct portion provided in each journal of the mandrel, the axial duct portion linking a docking port.

10. The mandrel according to claim 9, wherein the pressure circuit comprises at least one duct portion linking each axial duct portion to the portion in the form of a tube.

11. A unit for converting a flat substrate, comprising at least one mandrel according to claim 1.

12. The unit according to claim 11, wherein the cooling circuit is connected to a cooling module for cooling the fluid.

13. The unit according to claim 11, wherein the pressure circuit connected to the cooling circuit forms a closed circuit.

14. A method for operating a conversion unit according to claim 11, the method comprising the steps of: connecting only one of the two docking ports of the pressure circuit to the cooling circuit; exerting a radial pressure on the sleeve with the peripheral wall by sending a fluid through the pressure circuit to lock the sleeve in position on the mandrel; and connecting the two docking ports of the pressure circuit to the cooling circuit and causing a cooled fluid to flow through the pressure circuit in order to cool the mandrel.

15. The method according to claim 14, wherein the flow of the fluid through the pressure circuit in order to cool the mandrel is realized in a closed circuit.

16. The method according to claim 14, wherein the docking port of the pressure circuit connected to the cooling circuit in order to secure the sleeve to the mandrel is the docking port arranged at the rear of the mandrel, on the opposite side from the driver.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0034] Further advantages and features will become apparent from reading the description of the invention and from the appended figures, which show a nonlimiting exemplary embodiment of the invention and in which:

[0035] FIG. 1 is an overall view of an example of a conversion line for converting a flat substrate;

[0036] FIG. 2 shows a perspective view of an upper rotary tool and of a lower rotary tool;

[0037] FIG. 3 shows a perspective view of a mandrel;

[0038] FIG. 4 shows a view of a pressure circuit connected to a cooling circuit, forming a closed circuit; and

[0039] FIG. 5 shows a partial view in vertical section of a conversion unit in which two rotary tools are mounted that each comprise a mandrel and a sleeve secured to the mandrel.

[0040] The longitudinal, vertical and transverse directions indicated in FIG. 2 are defined by the trihedron L, V, T. The transverse direction T is the direction perpendicular to the longitudinal direction of movement L of the flat substrate. The horizontal plane corresponds to the plane L, T. The front and rear positions are defined with respect to the transverse direction T as being on the side of the driver and on the opposite side from the driver, respectively.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0041] A conversion line for converting a flat substrate, such as flat cardboard or a continuous web of paper wound on a reel, makes it possible to carry out various operations and obtain packaging such as folding boxes. As shown in FIG. 1, the conversion line comprises, disposed one after another in the order of passage of the flat substrate, an unwinding station 1, several printer units 2, one or more embossing units in series followed by one or more scoring units in series 3, followed by a rotary cutting unit 4 or platen die-cutting unit, and a station 5 for receiving the manufactured objects.

[0042] The conversion unit 7 comprises an upper rotary tool 10 and a lower rotary tool 11, which modify the flat substrate by printing, embossing, scoring, cutting, ejection of scrap, etc., in order to obtain packaging.

[0043] The rotary tools 10 and 11 are mounted parallel to one another in the conversion unit 7, one above the other, and extend in the transverse direction T, which is also the direction of the axes of rotation A1 and A2 of the rotary tools 10 and 11 (see FIG. 2). The rear ends of the rotary tools 10 and 11, on the opposite side from the driver, are driven and rotated by motorized drive means. In operation, the rotary tools 10 and 11 rotate in opposite directions about each of the axes of rotation A1 and A2 (arrows Fs and Fi). The flat substrate passes through the gap situated between the rotary tools 10 and 11 in order to be embossed and/or scored and/or cut and/or printed on therein.

[0044] At least one of the two rotary tools, the upper rotary tool 10 or the lower rotary tool 11, comprises a mandrel 12 and a removable sleeve 13 that is able to be fitted on the mandrel 12 in the transverse direction T (FIG. 2, arrow G). Thus, when changing the rotary tools 10 and 11 is desired, all that is necessary is to change the sleeves 13 rather than the entire rotary tool 10 and 11. Since it is easier to handle the sleeve 13 on account of its low weight relative to that of the entire rotary tool 10 and 11, the change of operation can be effected rapidly. Moreover, the sleeves 13 are inexpensive compared with the price of the rotary tool 10 and 11 as a whole. It is thus advantageous to use one and the same mandrel 12 in combination with several sleeves 13 rather than to acquire several entire rotary tools 10 and 11. The sleeve 13 has a cylindrical overall shape. It is made, for example, of aluminum material.

[0045] The mandrel 12 comprises a cylindrical core 14, a front journal 15, a rear journal 16 on either side of the cylindrical core 14, forming a rotating shaft of the rotary tool, and a peripheral wall 17 surrounding the cylindrical core 14 (FIG. 3). The front and rear journals 15 and 16 have a cylindrical overall shape. They are held by front and rear bearings 18, 19, respectively, of the conversion unit 7. In operation, the rear journals 16 of the rotary tools 10 and 11, on the opposite side from the driver, are driven and rotated by a motorized drive system 20. The elements of the mandrel 12, that is to say the cylindrical core 14, the front and rear journals 15 and 16, and the peripheral envelope 17, are made of a metal material, such as steel.

[0046] The cylindrical peripheral wall 17 can take up a rest position and a locking position in which the peripheral wall 17 exerts a radial pressure on the sleeve 13 in order to lock the latter in position on the mandrel 12, for example, by radial deformation of the peripheral wall 17.

[0047] The mandrel 12 also comprises a tool pressure fluid circuit 21 provided in part between the peripheral wall 17 and the cylindrical core 14 (FIGS. 4 and 5) in order to control the exertion of the radial pressure by the peripheral wall 17. The pressure circuit 21 is intended to receive a fluid in order to press the peripheral wall 17 against the interior envelope surface of the sleeve 13 in order to hold the sleeve 13 on the mandrel 12. The sleeve 13 thus held firmly on the mandrel 12 can be driven and rotated about the axis of rotation A1 and A2. The fluid is, for example, oil.

[0048] The pressure circuit 21 comprises a docking port 22 to a cooling fluid circuit 24 of the conversion unit 7 in order to allow a fluid to flow through the pressure circuit 21 in order to cool the mandrel 12. According to one exemplary embodiment, a docking port 22 is arranged at a front end of the mandrel 12. The pressure circuit 21 comprises another docking port 23 arranged at a rear end of the mandrel 12. The pressure circuit 21 can thus lead out of the mandrel 12 through an orifice of the docking port 22 provided in the front journal 15 and through an orifice of the docking port 23 provided in the rear journal 16. The docking ports 22 and 23 are aligned, for example, along the axis of rotation A1 or A2 of the mandrel 12, and arranged at the respective ends of the front and rear journals 15 and 16. According to one embodiment, the pressure circuit 21 has axial symmetry.

[0049] For example, the pressure circuit 21 has a portion in the form of a tube 21a, two axial duct portions 21b and two radial duct portions 21c (FIG. 5). The axial and radial duct portions 21b, 21c are linear. The portion in the form of a tube 21a is coaxial with the axis of rotation A1 or A2 of the mandrel 12 and formed around the cylindrical core 14. The peripheral wall 17 is, for example, shrunk onto and then welded to the cylindrical core 14, leaving a gap of a few millimeters forming the portion in the form of a tube 21a of the pressure circuit 21.

[0050] The axial duct portions 21b are aligned along the axis of rotation A1 and A2 of the mandrel 12 and are formed in a respective journal 15 and 16. Each axial duct portion 21b links a docking port 22 and 23 to a radial duct portion 21c, forming a right angle. Each radial duct portion 21c extends radially in order to link an axial duct portion 21b at two diametrically opposite points of one end of the portion in the form of a tube 21a. This embodiment of the pressure circuit 21 is simple to realize and makes it possible to hold the sleeve 13 uniformly over its entire interior envelope surface.

[0051] The pressure circuit 21 is intended to be connected to the cooling circuit 24, for example, forming a closed circuit (see FIG. 4). The conversion unit 7 also comprises a cooling module 25 configured to cool the fluid flowing through the cooling circuit 24. The cooling module 25 comprises for example a pump for causing the fluid to flow through the cooling circuit 24, and a heat exchanger that is able to cool the fluid flowing through the cooling circuit 24.

[0052] According to one exemplary embodiment, each docking port 22, 23 comprises a connection element 26 of the mandrel 12, intended to engage with a complementary connection element 27 of the conversion unit 7 in order to connect the pressure circuit 21 to the cooling circuit 24.

[0053] The connection elements 26 are, for example, separate elements that are mounted tightly in an orifice of the respective docking port 22 and 23 of the pressure circuit 21. The connection elements 26 and the complementary connection elements 27 are, for example, of the quick-connector type. The ends of the connection elements 26 and 27 engaging with one another are, for example, of the male/female type.

[0054] The quick connectors are also configured to take up a closed-off position when they are disconnected from one another and an open position allowing the passage of the fluid when they are connected together. This makes it possible to automatically close the pressure circuit 21 when they are disconnected, which is necessary in order for the radial pressure to be exerted by the peripheral wall 17 in order to secure the sleeve 13 to the mandrel 12.

[0055] In an example of a method for operating the conversion unit 7, in order to lock the sleeve 13 in position on the mandrel 12, only one of the two docking ports 22 and 23 of the pressure circuit 21, such as the docking port 23 arranged at the rear of the mandrel 12, is connected. The connection element 26 of the docking port 22 arranged at the front of the mandrel 12 is then in the closed-off position, closing the pressure circuit 21 (FIG. 5).

[0056] Next, a fluid is sent through the pressure circuit 21. The cooling circuit 24 is isolated from the cooling module 25. The pressure exerted by the fluid in the pressure circuit 21 then pushes the peripheral wall 17 radially, into the locking position, pressing the peripheral wall 17 against the interior envelope surface of the sleeve 13, thereby fixing the sleeve 13 firmly to the mandrel 12.

[0057] At least one of the two connection elements 26 of the mandrel 12 remains connected to the complementary connection element 27 of the conversion unit 7. The sleeve 13 thus held firmly on the mandrel 12 can be driven in rotation by the mandrel 12 in order to carry out operations of converting the flat substrate.

[0058] At the end of the operations, once the conversion unit 7 has been stopped, that is to say when the rotary tools are no longer rotating, the pressure of the fluid is reduced in order to disconnect the sleeve 13 from the mandrel 12.

[0059] Next, the other of the two docking ports 22 of the pressure circuit 21 is connected to the cooling circuit 24. The connection elements 26 thus connected to the complementary connection elements 27 allow the fluid to flow through the cooling circuit 24, forming a closed circuit, in order to be cooled by the cooling module 25 and to cool the mandrel 12. The mandrel 12 and the sleeve 13 can then be cooled. When the mandrel 12 has been sufficiently cooled and the peripheral wall 17 is in its rest position, the sleeve 13 can be removed easily.

[0060] The pressure circuit 21 used to secure the sleeve 13 to the mandrel 12 is thus also used for cooling the mandrel 12 when the conversion unit 7 is stopped. This second use of the pressure circuit 21 makes it possible to accelerate the cooling of the mandrel 12 in order to release the sleeve 13 more easily and rapidly. Moreover, the act of securing the sleeve 13 to the mandrel 12 or of cooling the mandrel 12 can be controlled and automated easily by the acts of connecting or disconnecting the pressure circuit 21.

[0061] The present invention is not limited to the embodiments described and illustrated. Numerous modifications can be made without otherwise departing from the scope defined by the set of claims.