Patent Application
20160243648
The use of flexible tubular hoses, mainly manufactured with silicone, is widely used in the sector of the industry for transporting fluids of different types which may be subjected to extreme temperatures and to high pressures. An example of a flexible tubular hose is that formed by an internal layer, which forms the internal surface of the tube, proceeding from which there are provided various concentric tubular layers consisting of reinforcing and silicone materials, finishing with an external layer, also made of silicone.
Due to the great number of flexible tubular hoses in one single installation or within an industry, it is necessary to identify them expediently, not just by the function of the hose or the type of fluid or gas which it is going to transport for its assembly verification, but also for the data of the hose per se, such as for example the characteristics of its materials, its origin and date of manufacture or any other relevant data regarding the life of the hose, with the aim of determining whether it can be maintained, be reused in another installation or whether it must be replaced.
The use of plastic or metallic labels adhered to the external surface of the hoses is impractical due to the conditions of use of the hoses themselves, subjected to frictions, impacts, high pressures and temperatures, which leads to the damage or loss of the label. Another option, which has shown improved results, is the use of electronic labels inserted between the layers of material of which the flexible tubular hose is made, although there is the drawback of having to insert the electronic label during the manufacturing process of the flexible tubular hose, which does not apply to hoses which have already been manufactured.
It would be desirable to provide flexible tubular hoses which carry the necessary associated information for the identification thereof and for the tracking at all times of the hoses, independently of the external conditions to which the hoses are subjected, facilitating the access to said information and the integrity thereof.
With the object of providing a solution to the problems set out, a tubular hose to be used for transporting fluids in industrial installations is made known. The hose comprises an external layer made of a polymeric material provided with a code, intaglio engraved using a laser on the external surface of the external layer formed by a plurality of grooves arranged according to a pattern of the code. The grooves are at least partially filled with a filler material with colored polymeric base which produces a visual contrast with the rest of the external surface of the external layer.
Preferably the polymeric material of the external layer of the tubular hose is silicone and the filler material is an ink which comprises silicone. This ink, since it is composed of silicone, creates a bond with the silicone of the external layer of the hose and thus adheres perfectly.
The ink of the filler material, depending on its formulation, is either curable or not by temperature, that is to say, hardens with the application of heat. For example, according to a preferred embodiment of the invention, the ink is cured at a temperature of between 100° C. and 180° C. by means of any heat source, during a period of approximately between 3 and 15 minutes.
According to another characteristic of the invention, the filler material may completely occupy the hollow of the grooves until it is level with the rest of the surface of the external layer.
Preferably, the code engraved using the laser is a QR CODE, which is a matrix or two-dimensional code. This QR CODE contains the information necessary for each end client of the tubular hose, that is to say, the information contained is personalizable as a function of their requirements.
According to another characteristic of the invention, the depth of the grooves which form the code is between 0.001 mm and 1 cm.
In accordance with another characteristic of the invention, the hose is preferably a flexible hose, although according to other embodiments of the invention, the hose may be rigid or of any other structure.
According to another aspect of the invention, the invention also provides a method for manufacturing a tubular hose provided with a code as the hose previously described, wherein the method comprises the steps of:
The engraving of the code in step b) is realized using a laser tube applying a laser beam displacement technique. Preferably the engraved code is a QR CODE and the depth of the grooves realized using the laser may be from 0.001 mm to 1 cm.
According to another characteristic of the method, the polymeric material of the external layer is silicone and the filler material is an ink comprising silicone.
In accordance with a variant of the invention, the ink of the filler material is curable by temperature and after step c) follows step d) for curing the ink in which the hose, or at least the part of the hose which comprises the code, is exposed to the action of a heat source by way of which the hose or the cited part of the hose reaches the curing temperature of the ink of the filler material.
Preferably, the curing temperature of the filler material is between 100° C. and 180° C. According to the preferred variant of the invention, the ink of the filler material is cured at 160° C. over a period of between 3 and 15 minutes. The curing of the ink may be carried out by means of any known suitable heat source, for example an oven.
Also in a preferred manner, in step c), the hollow of the grooves formed by the laser is completely filled with the filler material until it is level with the rest of the surface of the external layer of the tubular hose.
The method which is the object of the invention is applicable to flexible tubular hoses but also to rigid hoses, as long as they have an external silicone layer.
In the attached drawings, an embodiment of the tubular hose which is the object of the invention according to the method for the manufacture thereof is shown in an exemplary and non-limiting manner. In said drawings:
It is observed in
Laser tube is understood to be a hermetically sealed receptacle, already known, which mainly contains CO2, in addition to other gases such as nitrogen, hydrogen or helium. The ends of the receptacle are provided with respective mirrors, one of which being partially transparent. The gas in the interior of the tube is activated by means of electrical energy, produced by a radio frequency unit and emits energy in the form of light. One part of this light—the more intense part—exits through the partially transparent mirror and forms the beam of the laser. The other part of the light bounces and returns back, gathering intensity.
The technique normally used to realize a marking or engraving by means of the use of a laser tube is by means of the displacement of the beam. Using this technique, a medium-strength laser beam is focused on the surface to be marked. The beam is orientated by means of a combination of galvanometric mirrors such that it follows the course of the design to be marked, in this case, the design of the pattern of the QR CODE 3.
Prior to engraving the QR CODE 3 using the laser, the QR CODE 3 is generated using the information necessary for each client of the user of the hose 1 to be manufactured, that is to say, the information which the QR CODE 3 of the hose 1 contains is personalizable as a function of the requirements of each client. This QR CODE 3 is transferred to a drawing program which allows it to be vectored. Once the QR CODE 3 is provided, the parameters of the laser, with which the work is to be carried out, are configured, for example the velocity of the engraving, the height of the lens, the power, etc. As a function of these parameters, the engraving will have greater or less definition, possibly being a few microns in depth (superficial engraving) or tens of millimeters (deep engraving).
With the engraving by laser, when part of the material of the external layer 2 of the hose 1 is removed, in this case silicone, a groove or a plurality of grooves 4 can be configured, forming the determined drawing or scheme of the QR CODE 3.
The engraving on silicone, whether it is superficial or deep, is difficult to observe with the naked eye, thus to make it stand out, the space formed by the grooves 4 is filled (see
Advantageously, the filler material 5 is ink which comprises silicone as part of its composition, facilitating the establishing of a bond between the ink and the silicone of the walls and bottom of the grooves 4, that is to say, with the silicone of the external layer 2 of the hose 1, achieving excellent adherence.
Depending on the formulation of the ink, once the hollow space of the grooves 4 engraved by the laser has been filled, it may or may not be necessary to cure the area of the hose 1 which has the code 3. The curing may be realized by means of any known heat source (for example an oven) at a curing temperature of between 100° C. and 180° C., for example at 160° C., over a period of between 3 and 15 minutes for normal hose sections 1.
Following the method described, the correct reading of the data stored in the QR CODE 3 is ensured by means of the use of any reader device authorized for this purpose, such as a mobile, PDA, USB reader, etc., ensuring traceability of the manufactured tubular hose 1 at all times, even in the most adverse conditions in which the hose 1 may be operating.
Lastly, it should be mentioned that the code 3 engraved and subsequently filled with the filler material 5 is preferably a QR CODE 3, although other types of codes are not ruled out, for example barcodes or product references.
