The invention relates to a bending device for the production by thermoforming of bent tubes made of plastic material.
The tubes, so-called plastic tubing, made of plastic material, in particular of the thermoplastic polymer type, such as polyamide, used in particular in the automobile field and the aeronautical field, and having bent segments, are currently produced by thermoforming of tubes placed in shaping templates forming an open guide pipe that has the longitudinal profile of bent tubes.
Two thermoforming techniques are primarily used at present: a first technique consists of using heating furnaces into which are inserted the shaping templates, and a second technique consists of circulating, in the tubes positioned in the shaping templates, a heating fluid brought to a suitable temperature for achieving a brittle-ductile transition of the tubes.
One of the drawbacks of this second technique resides in the fact that its implementation requires multiple successive operations that lead to significant shaping cycle times and require consequent manual labor, which are reflected by high production costs.
It is an object of this invention to remedy the drawbacks of this second thermoforming technique, and it has as a primary objective to provide a bending device designed to automate the majority of the bending operations and to raise the rate of production in a significant way.
Another objective of the invention is to provide a bending device that makes possible an automated mounting of components on the ends of the bent tubes.
For this purpose, an object of the invention is a bending device for the production by thermoforming of bent tubes made of plastic material, comprising shaping templates forming an open guide pipe that has the longitudinal profile of the bent tubes, and, according to the invention, this bending device comprises:
A multi-articulated robotized system, comprising:
For each bent tube model, and therefore each shaping template model, such a bending device is therefore designed, after an initial manual stage of fixing shaping templates and supports of the connectors on the work stations and of indexing the position of the shaping templates, to carry out fully-automated shaping cycles during each of which, for each work station, a tube is charged on the shaping template positioned on the work station in succession, and then heated, cooled and finally brought into the discharging position.
In addition, it should be noted that the means for fixing the shaping templates can be of any standard type known in the art, with the indexing of the position of these shaping templates able to be of the material and/or software type.
In addition, such a bending device makes it possible to produce the bent tubes at high speed based on the time required for the longest operation (charging, heating, cooling).
According to an advantageous embodiment of the invention, the centralized heating-fluid supply comprise a water vapor production source.
The centralized fluid supply for supplying at least a cooling fluid advantageously comprises, according to the invention, a cold-water production source, and an air production source for drying tubes after the latter are cooled.
The bending device further advantageously comprises, according to the invention, a suitable automated plastic tube supply device for supplying the hand of the robotized system with plastic tube segments precut to a predetermined length.
In addition, these plastic tube supply device advantageously comprise according to the invention:
According to another advantageous embodiment of the invention, the displacement element of each connector is composed of a cylinder provided with a rod on which the connector is made integral, and a body fixed on the support.
Furthermore, so as to ensure perfect reproducibility of the shaping templates and consequently a perfect homogeneity of the bent tubes produced, each shaping template is advantageously provided with, according to the invention, a guide mechanism composed of specific guide elements comprising a channel with a cross-section mated to that of the tube, forming a guide pipe formed by a series of specific supports of the tube.
In addition, each of these guide elements advantageously comprises, according to the invention, a retentive-shaped channel having an opening for inserting and removing the tube provided with beveled longitudinal edges designed to facilitate inserting the tube into the retentive-shaped channel.
Furthermore, the robotized system of the bending device according to the invention advantageously has a hand that is articulated in such a way as to be able to be programmed so that the force for inserting the tube into the channel of each guide element is applied along an axis parallel to the plane of symmetry of the channel, thus facilitating inserting the tubes into the channels.
The press element of this robotized system advantageously is composed of, according to the invention, a wheel provided with a peripheral channel with a cross-section mated to that of the tube.
In addition, this press element is advantageously combined with a suitable elastic device for allowing the press element to travel in a direction that is parallel to the axis of the insertion force applied by the latter.
Furthermore, so as to prevent a possible longitudinal sliding of the tube inside the guide pipe, the bending device advantageously comprises, according to the invention, a retractable element for locking the end of the tube in the guide pipe of the shaping template, designed to be actuated during the insertion of a tube into a shaping template.
According to another advantageous embodiment of the invention, the gripping hand of the robotized system comprises motorized rollers placed and driven in rotation in such a way that the tube engages between the rollers and is entrained toward the press element in a direction of travel that is opposite to the direction of displacement of the gripping hand.
In addition, these motorized rollers are advantageously mounted on the gripping hand by a mechanism ensuring relative displacement of the rollers between a close driving position of the tube and a separated escapement position of the tube.
According to a first advantageous variant embodiment of the invention, the shaping unit comprises stationary work stations, with the relative displacement elements of the robotized system and the shaping unit being suitable for moving the robotized system in such a way as to bring it opposite each of the stationary work stations in succession.
In addition, according to this variant embodiment, the work stations are advantageously aligned one behind another, with the displacement elements of the robotized system being suitable for moving the latter along a straight trajectory.
According to a second advantageous variant embodiment of the invention, the shaping unit comprises suitable displacement elements of the work stations for bringing, in succession, the latter opposite a stationary position on which the robotized system is located.
In addition, according to this variant embodiment, the shaping unit advantageously comprises a circular table divided into circular sectors, each constituting a work station, with the displacement elements of the work stations being composed of drive elements in rotation of the circular table.
Furthermore, according to this second variant embodiment, the shaping unit, the drive elements in rotation of the circular table, and the centralized cooling-fluid supply are suitable for defining a so-called cooling position of the work stations, in which the two cooling fluids are delivered into the circulation circuit in succession.
The cumulative circulation time of the two cooling fluids actually proves to be on the order of the time required for achieving the brittle-ductile transition, and this arrangement makes it possible to achieve essentially similar heating and cooling times.
Furthermore, according to this second variant embodiment, the discharging operation can also be automated and, for this purpose, according to a first solution, the shaping unit and the drive elements in rotation of the circular table are advantageously suitable for defining a position of the work stations, called charging/discharging, and the robotized system advantageously comprises a second hand for gripping the bent tubes for the purpose of their discharging.
For the purpose of the automation of the discharging operation and according to another solution, the shaping unit and the drive elements in rotation of the circular table are advantageously suitable for defining:
In addition, this second robotized system also advantageously comprises, according to the invention, a piece of equipment for mounting components on the ends of the bent tubes.
Other characteristics, objects, and advantages of the invention will emerge from the detailed description that follows with reference to the accompanying drawings that show two preferred embodiments of it by way of nonlimiting examples. In these drawings:
The bending devices according to the invention shown by way of examples in the figures consist of bending devices for the production by thermoforming of bent tubes 1 made of plastic materials in particular of the thermoplastic polymer type, such as the polyamide, used in particular in the automobile field and the aeronautical field.
In the first place, the bending device shown in
First of all, the shaping templates 2a-2d comprise, on the one hand, a base composed of two identical flat plates consisting of a lower base plate 4 and an intermediate base plate 5, and, on the other hand, specific guide elements 3a-3n that are suitable for delimiting the guide pipe.
First of all, the guide elements 3a-3n comprise a channel 6 with a diameter that is appreciably larger than the diameter of the tube 1, suitable for forming a pipe that is formed by a series of specific supports of the tube. These guide elements 3a-3n are adapted to a scale of specific guide elements provided with channels having planes of symmetry whose inclination in relation to the planes of the base plates 4, 5 varies over a range of values of between 0° and 90°.
By way of example,
In addition, each channel 6 comprises an opening 6a for inserting and removing the tube 1 having a width that is appreciably smaller than the diameter of the channel, suitable for imparting a retentive nature to the latter. This opening 6a for inserting and removing the tube 1 is also provided with beveled longitudinal edges 7, designed in particular to facilitate inserting the tubes 1 into the channels 6.
Regardless of the orientation of the channel 6, each of these elements 3a-3n comprises:
Each base plate 4, 5 has the general shape of a rigid plate strip whose flat faces are centered on an axis coinciding with the longitudinal axis of the guide pipe formed by the channels 6 of the guide elements 3a-3n.
These two base plates 4, 5 are also pierced by transverse slots:
As mentioned above, the shaping unit 8 comprises four identical work stations 11-14, each suitable for accommodating a shaping template 2a-2d.
Each of these work stations 11-14 is also equipped with two connectors 15, 16 that incorporate a seal 17 and with each being suitable for being connected in an airtight way to one of the ends of the tube 1 inserted into the guide pipe 3a-3n of the shaping template 2a-2d.
One of these so-called supply connectors 15 is mounted on a feed pipe 18 connected to a suitable distribution valve 19, for example by means of a rotary joint, for making it possible to supply this feed pipe 18:
The second connector 16 is mounted on a pipe 20 for draining fluid downstream from the tube 1.
Each of the connectors 15, 16 is also mounted on the rod of a cylinder 21, 22 whose body is made integral on a bracket 23, 24 whose base is suitable for being made integral on the support plate 9 in the extension of one of the ends of the shaping template 2a-2d in such a way as to make it possible to move each connector 15, 16 between a position for airtight connection to the tube 1 that is inserted into the shaping template and a position that is disconnected and distant from the tube.
The first robotized system is composed of a six-axis robot 28 combined with a programmable guidance unit 29 and comprising an arm 30 on the end of which is articulated a hand 31 for gripping tubes 1 and for inserting the latter into the guide pipe 3a-3n of the shaping template 2a-2d fixed on the work station 11-14 positioned opposite the robotized system.
The hand 31 for gripping and inserting this robot 28 comprises, first of all, a first press element 32 that has a bearing surface that can apply on the tube 1 a force of inserting the latter into the guide pipe 3a-3n of the shaping template 2a-2d. This press element is composed of, in the example, a wheel 32 provided with a peripheral channel with a cross-section mated to that of the tube 1, whose rotating shaft is acted upon by a suitable elastic device 33 for allowing the press element to travel in a direction that is parallel to the axis of the insertion force applied by the latter.
This hand 31 for gripping and inserting also comprises two motorized rollers 36, 37, placed and driven in rotation in such a way that the tube 1 engages between the rollers and is entrained toward the press element 32 in a travel direction opposite to the displacement direction of the gripping and inserting hand.
In addition, these motorized rollers 36, 37 are mounted on the gripping and inserting hand 31 by way of a device ensuring relative displacement of the rollers between a close driving position of the tube 1 and a separated escapement position of the tube.
Finally, the gripping and inserting hand 31 comprises a second press element 34 also composed of a wheel whose rotating shaft is acted upon by an elastic device 35. This second press element 34 is positioned:
According to the invention, and as is shown in particular in
Furthermore, so as to prevent a possible longitudinal sliding of the tube inside the guide pipe 3a-3n, a retractable element, such as a cylinder 60, is suitable for locking the end of the tube in the guide pipe during the insertion of this tube into a shaping template 2a-2d.
The first robotized system 28, 29 is also combined with an automated plastic tube supply device that is suitable for supplying the gripping and inserting hand 31 with plastic tube segments precut to a predetermined length.
According to the example shown, these plastic tube supply device comprise:
The second robotized system is placed in such a way as to be positioned opposite one of the work stations 11-14 close to the work station positioned opposite the first robotized system 28, 29.
This second robotized system is composed of a six-axis robot 43 combined with a programmable guidance unit 44 and comprising an arm 45 on the end of which is articulated a hand 46 provided with elements 47 for gripping the bent tube 1 inserted into the guide pipe 3a-3n for the purpose of discharging this tube.
In addition, the robot 43 can also comprise a second hand (not shown) that is equipped and programmed in such a way as to make possible the mounting of components on the ends of the bent tubes 1.
After an initial manual stage of fixing shaping templates 2a-2d and supports 23, 24 of connectors 15, 16 on each of the work stations 11-14 and of indexing the position of the shaping templates 2a-2d, the shaping cycles comprise, for each of the work stations 11-14, the following stages, between each of which the work station is moved in rotation on a course of 90°:
Apart from the initial positioning stage of the shaping templates 2a-2d and supports 23, 24 on the work stations 11-14, this bending device makes it possible to produce by thermoforming, at high speed, bent tubes 1 made of plastic material.
Number | Date | Country | Kind |
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1302050 | Sep 2013 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2014/000191 | 8/28/2014 | WO | 00 |