Expander of tubular assembly

Abstract

An expander of a tubular assembly having a tubular covering element inserted into a tubular element includes a tip for pushing a first internal wall of the tubular covering element towards a second internal wall of the tubular element so as to enable the adhesion of a first external wall of the tubular covering element to the second internal wall. The expander includes a rotary joint sliding along a first longitudinal axis, to which the tip is coupled so as to arrange the tip radially and enable it to rotate around the first axis. The expander further includes a sensor operatively connected to the tip to detect a radial displacement of the tip owing to a current thrust exerted by the tip, and a logic control unit operatively connected to the sensor and the tip to adjust a future thrust as a function of the radial displacement.

Claims

1. An expander for expanding a tubular assembly having a tubular covering element inserted inside a tubular element to be covered, the expander comprising: a tip shaped to push a first internal wall of the tubular covering element toward a second internal wall of the tubular element to be covered so as to enable adhesion of a first external wall of the tubular covering element to the second internal wall of the tubular element to be covered; a rotary joint slidable along a longitudinal first axis of the tubular assembly, the tip being coupled to the rotary joint so as to arrange the tip radially with respect to the first axis and to enable the tip to rotate around the first axis; a motor coupled to the rotary joint and causing the rotary joint to slide along the first axis and to rotate; a sensor operatively connected to the tip at least to detect a radial displacement of the tip following a current thrust exerted by the tip; and a logic control unit operatively connected to the sensor and to the tip for adjusting a future thrust exerted by the tip according to the radial displacement.

2. The expander according to claim 1, further comprising a pusher interposed between the tip and the rotary joint.

3. The expander according to claim 1, further comprising a memory circuit connected to the logic control unit so as to memorize at least the radial displacement of the tip.

4. The expander according to claim 3, wherein the memory circuit is configured to also memorize a travelled path followed by the expander along the first axis.

5. The expander according to claim 4, further comprising a processor configured to calculate the future thrust also based on the traveled path.

6. The expander according to claim 5, wherein the processor is further configured to calculate the future thrust as a function of at least a plurality of radial displacements stored in the memory circuit.

7. A method of manufacturing a tubular assembly using the expander according to claim 3, comprising the following steps: starting the motor so as to cause the rotary joint to slide along the first axis and to rotate; detecting, with the sensor, the radial displacement of the tip following the current thrust exerted by the tip; calculating, with the logic control unit, the current thrust; and adjusting, with the logic control unit, the future thrust exerted by the tip as a function of at least the radial displacement.

8. The method according to claim 7, further comprising a step of storing, in the memory circuit, at least the radial displacement of the tip.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further features and advantages of the invention will become more apparent in the light of the detailed disclosure of a preferred, but not exclusive, embodiment of an expander of a tubular assembly and a method of expanding a tubular assembly according to the invention, illustrated by way of example only with the aid of the accompanying drawings wherein:

(2) FIG. 1 represents an expander of a tubular assembly in an operational phase in a partially sectioned view;

(3) FIG. 2 represents a block diagram of the method for manufacturing a tubular assembly according to the invention.

DETAILED DISCLOSURE OF EMBODIMENTS OF THE INVENTION

(4) With reference to the above-mentioned Figures, an expander 1 of a tubular assembly 2 is disclosed according to the invention.

(5) In particular, the expander 1 is applicable to a tubular assembly 2 having a tubular covering element 3 inserted within a tubular element to be covered 4. Said expander 1 comprises a tip 6 shaped to push a first internal wall 7 of the tubular covering element 3 towards a second internal wall 8 of the tubular element to be covered 4. To this end, it is evident that the tip 6 is arranged radially with respect to the tubular assembly 2.

(6) Advantageously, the presence of the tip 6 allows the course of the second internal wall 8 of the tubular element to be covered 4 to be monitored more precisely than in the known technique.

(7) It follows, again advantageously, that the foregoing allows the tubular covering element 3 to be expanded more correctly at the cavities on the second internal wall 8 of the tubular element to be covered 4 than is the case with the known technique.

(8) Advantageously, this makes it possible to avoid the risk of formation of air chambers between the two tubular elements 3 and 4, significantly reducing, if not zeroing, the possibility of generating pressure differences between the inside and the outside of the tubular covering element 3.

(9) It follows, still advantageously, that the presence of the tip 6 allows reduction, if not avoidance altogether, of the risk of breakage of the tubular covering element 3.

(10) Advantageously, therefore, this makes the tubular assembly 2 more resistant and durable, resulting in considerable cost savings.

(11) Obviously, the originator of the radial movement of the tip 6 is a pusher 9 which, according to another aspect of the invention, is interposed between the tip 6 and a rotary joint 10 which will be discussed below. Clearly, this feature is not to be regarded as limiting for different embodiments of the invention according to which the pusher is placed differently or the expander comprises different pushing elements.

(12) Obviously, as regards the presence of the tip 6, it should be specified that this feature should also not be considered limiting for different embodiments of the invention according to which there are two or more tips. The same applies to the conformation of the tip 6, which can be of any shape without any limitation for the present invention.

(13) According to another aspect of the invention, the expander 1 comprises, as mentioned above, a rotary joint 10 coupled to at least one motor 11 which makes it possible to slide the rotary joint 10 according to a first axis X coinciding with the longitudinal development axis of the tubular assembly 2 and to rotate it around the same first axis X.

(14) Moreover, according to a further aspect of the invention, the tip 6 is coupled to the rotary joint 10 in such a way that it is arranged radially with respect to the first axis X.

(15) Advantageously, the coupling of the tip 6 to the rotary joint 10 also allows the tip 6 to be rotated about the first axis X.

(16) Again advantageously, this allows the tip 6 to reach the entire first internal wall 7 of the tubular covering element 3.

(17) It follows, advantageously, that the foregoing makes possible an integral adhesion of the external wall 12 of the tubular covering element 3 with the second internal wall 8 of the tubular element to be covered 4.

(18) According to another aspect of the invention, although not shown in the Figures the expander 1 comprises a sensor operatively connected to the tip 6 to detect the radial displacement thereof following a current thrust exerted.

(19) Advantageously, the presence of the sensor makes it possible to measure the displacement in the radial direction travelled by the tip 6 due to the effect of the thrust exerted by the same and, therefore, implicitly, to detect the development of the second internal wall 8 of the tubular element to be covered.

(20) According to yet a further aspect of the invention, the expander 1 comprises a logic control unit, also not shown in the Figures, operatively connected to the sensor and to the tip 6 to adjust the future thrust exerted by the tip 6 as a function of radial displacement.

(21) Advantageously, the foregoing makes it possible to predict the next displacement to be made by the tip 6.

(22) Again advantageously, this makes it possible to predict the thrust that will be required for the tip 6 to reach the next displacement.

(23) It follows, advantageously, that the logic unit makes it possible to obtain a more precise execution than in the known technique, albeit with a fast execution time.

(24) According to another aspect of the invention, the logic control unit comprises a memory circuit not shown in the Figures.

(25) Advantageously, the presence of the memory circuit makes it possible to store the radial displacement of the tip 6.

(26) Moreover, the memory circuit is also configured to store a path taken by the expander 1 along the first axis X.

(27) This makes it advantageously possible to develop a historical record of the path taken by the expander 1.

(28) It follows, again advantageously, that the foregoing makes it possible to store the displacements as well as the force used for the radial displacement of the tip 6 and, therefore, to obtain a historical record of the course of the second internal wall 8 of the tubular element to be covered 4.

(29) Again advantageously, this increases the predictability of the future course of the second internal wall 8 of the tubular element to be covered 4 and thus the future force that will be required for the subsequent radial displacement of the tip 6.

(30) Obviously, for this purpose the expander 1 of the invention also comprises a computer product such as a processor.

(31) Operationally, the tubular assembly 2 is manufactured through a method 16 which comprises a first start-up step 17 of the motor 11.

(32) As mentioned, the motor 11 makes it advantageously possible to slide the rotary joint 10 along the first axis X and to rotate it inside the tubular assembly 2.

(33) Moreover, as mentioned above, the tip 6 is coupled to the rotary joint 10. It follows that, again advantageously, the motor 11 also makes it possible to rotate the tip 6 which, therefore, being arranged radially with respect to the first axis X, reaches the entire internal circumference of the tubular element to be covered 4.

(34) According to an aspect of the invention, the method 16 comprises a step of detecting 18, by means of the sensor, the radial displacement of the tip 6 following the current thrust exerted by the tip 6 itself.

(35) Advantageously, during this phase the sensor makes it possible to measure the displacement in the radial direction of the tip 6 following the current thrust exerted by the same.

(36) Subsequently, the method 16 comprises a step of calculating 19 the current thrust, carried out by the logic control unit.

(37) Advantageously, the above makes it possible to understand the distance between the external wall 12 of the tubular covering element 3 and the second internal wall 8 of the tubular element to be covered 4.

(38) Again advantageously, this makes it possible to detect the possible presence of cavities on the second internal wall 8 of the tubular element to be covered 4.

(39) Moreover, according to another aspect of the invention, after the calculation step 19, the method 16 comprises a step of adjusting 20, again by means of the logic control unit, the future thrust exerted by the tip 6 as a function of the radial displacement.

(40) In other words, during the adjustment step 20, the logic control unit adapts the future thrust of the tip 6 as a function of the radial displacement. More specifically, if the radial displacement following the current thrust is greater than a previous radial displacement with the same thrust, it means that the expander 1 is in the vicinity of a cavity or, at any rate, of an enlargement of the second internal wall 8 of the tubular element to be covered 4. It follows that, since, by nature, a cavity begins with a descent and then ascends once the lowest point has been reached, the sensor makes it possible to detect implicitly the presence of a cavity, and the logic control unit, advantageously, makes it possible to exert a greater future thrust so as to enable the future radial displacement of the tip 6 that will be necessary to follow the course of the cavity present on the second internal wall 8 of the tubular element to be covered 4.

(41) This again makes it advantageously possible to obtain greater precision in the expansion of the tubular covering element 3.

(42) Again advantageously, this makes it possible to avoid the risk of creating air chambers between the tubular covering element 3 and the tubular element to be covered 4.

(43) It follows, advantageously, that the foregoing makes it possible to reduce or avoid altogether the risk of breakage of the tubular covering element 3 caused by pressure differences between the inside and the outside thereof.

(44) Again, this saves the time and costs of early replacement and/or maintenance of the tubular covering element 3.

(45) Not only that, but it also makes it possible, again advantageously, to create a durable tubular assembly 2.

(46) In addition, the prediction of the development of the second internal wall 8 makes it possible to optimise the tip 6 pushing phase, thereby optimising expansion execution times.

(47) According to a further aspect of the invention, the method 16 comprises a step of storing 21 the tip 6 radial displacement in the memory circuit.

(48) Moreover, as mentioned above, the memory circuit is also configured to store a path taken by the expander 1 along the first axis X.

(49) This makes it advantageously possible to develop a historical record of the path taken by the expander 1.

(50) It follows, again advantageously, that the foregoing makes it possible to store the displacements as well as the force used for the radial displacement of the tip 6 and, therefore, to obtain a historical record of the course of the second internal wall 8 of the tubular element to be covered 4.

(51) Again advantageously, this increases the predictability of the future course of the second internal wall 8 of the tubular element to be covered 4 and thus the future force that will be required for the subsequent radial displacement of the tip 6.

(52) In this way, advantageously, further considerable time saving is made possible in the execution of the method 16 of manufacturing the tubular assembly 2.

(53) In light of the foregoing, it is evident that the expander of a tubular assembly of the invention achieves all of its intended purposes.

(54) In particular, the expander of the invention allows the adhesion of the tubular covering element to the entire internal wall of the tubular element to be covered.

(55) Indeed, it makes it possible to adhere the tubular covering element to the tubular element to be covered also at the cavities created on the latter.

(56) It follows that the expander of a tubular assembly makes it possible to avoid the creation of air chambers between the two tubular elements.

(57) Accordingly, it makes it possible to avoid the risk of breakage of the tubular covering element due to pressure differences between the inside and the outside of the tubular covering element.

(58) Moreover, the expander of a tubular assembly of the invention makes it possible to save the costs of replacing the tubular covering element due to breakage of the same.

(59) Furthermore, it enables the above to be achieved in a suitably quick turnaround time compared to the known technique.

(60) The invention might be subject to many changes and variants, which are all included in the appended claims. Moreover, all the details may furthermore be replaced by other technically equivalent elements, and the materials may be different depending on the needs, without departing from the protection scope of the invention defined by the appended claims.