Method for installing a monitoring device in a tyre for vehicle wheels

Abstract

A positioning device for keeping a monitoring device for tyres of vehicle wheels in an installation condition, includes: two separate active portions, each having a main surface the shape of which matches that of a respective portion of an outer surface of a monitoring device, said separate active portions being adapted to cooperate with at least base portions of said monitoring device so that, when said positioning device is associated with said monitoring device, the base portions of said monitoring device are maintained at a given mutual distance by said active portions.

Claims

1. A positioning device for keeping a monitoring device for tyres of vehicle wheels in an installation condition, said positioning device comprising two separate active portions, each having a main surface the shape of which matches that of a respective portion of an outer surface of a monitoring device, said separate active portions being adapted to cooperate with at least base portions of said monitoring device so that, when said positioning device is associated with said monitoring device, the base portions of said monitoring device are maintained at a given mutual distance by said active portions.

2. The positioning device as claimed in claim 1, wherein, when said positioning device is associated with said monitoring device, each of said main surfaces is in contact with the respective outer-surface portions of said monitoring device.

3. The positioning device as claimed in claim 1, wherein said positioning device, when it is associated with said monitoring device, surrounds said monitoring device in a peripheral manner according to at least one plane parallel to base surfaces of said base portions in at least one portion thereof.

4. The positioning device as claimed in claim 1, wherein each of said active portions comprises a respective expansion extending from a respective main surface.

5. The positioning device as claimed in claim 4, wherein, when said positioning device is associated with said monitoring device, each respective expansion is inserted between said base portions of said monitoring device.

6. The positioning device as claimed in claim 5, wherein said respective expansions are inserted between said base portions from opposite sides of said monitoring device relative to an electronic unit, the electronic unit being part of said monitoring device.

7. The positioning device as claimed in claim 1, wherein each of said active portions seen in plan view has a C-shaped conformation having a pair of ends in which, when said positioning device is associated with said monitoring device, the ends of each of said active portions are in contact with the ends of the other active portion.

8. The positioning device as claimed in claim 1, wherein said monitoring device comprises a connecting member having an upper structure and a lower structure, wherein each of said main surfaces in a section evaluated when said positioning device is associated with said monitoring device according to at least one plane perpendicular to a plane defined by base surfaces of said base portions, has a L shaped conformation comprising a first and a second portion, said first portion of said L shaped conformation matching a shape of an outer surface of a side wall of said lower structure, and said second portion of said L shaped conformation matching a shape of an outer surface of a base wall of said lower structure.

9. The positioning device as claimed in claim 1, further comprising a ring nut adapted to be fitted around said positioning device and to maintain said active portions of said positioning device associated.

10. The positioning device as claimed in claim 9, further comprising a piston adapted to be inserted into said ring nut, said ring nut being slidably associable with an outer surface of said piston.

11. The positioning device as claimed in claim 1, further comprising a pair of lever elements, each extending from a respective one of said active portions, each of said lever elements having a distal end relative to a corresponding active portion, the distal ends of said lever elements being mutually associated in such a manner that said positioning device is configurable between an open condition, at which said monitoring device is interposable between said active portions, and a closed condition at which said active portions are closed around said monitoring device under action of said lever elements.

12. The positioning device as claimed in claim 11, further comprising a hooping member adapted to be at least partly fitted around said lever elements and/or said active portions to keep said positioning device in said closed condition.

13. The positioning device as claimed in claim 12, further comprising a thrust element associated with said hooping member and adapted to be positioned, when said hooping member is fitted around said lever elements and/or said active portions, in contact with said monitoring device on an opposite side relative to said base surfaces.

14. The positioning device as claimed in claim 1, further comprising an actuator member configured for driving said active portions between a mutually moved apart position and a mutually moved close position, wherein in said mutually moved apart position the monitoring device is interposable between said active portions, wherein in said mutually moved close position the monitoring device is associated with said active portions.

15. The positioning device as claimed in claim 14, wherein said actuator member comprises: a rotationally actuatable command element; a transmission element interlocked with said command element, for moving said active portions upon actuation of said command element.

16. The positioning device as claimed in claim 15, wherein said transmission element is configurable in a first condition, at which said transmission element causes mutual moving apart between said active portions, and a second condition at which said transmission element allows mutual moving close between said active portions.

17. The positioning device as claimed in claim 16, wherein said actuator member further comprises an elastic-return structure for moving said active portions close to each other when said transmission element is in said second condition.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Such description is provided hereinbelow with reference to the set of figures, which also have merely exemplifying and thus non-limiting object, in which:

(2) FIG. 1a schematically shows a tyre for vehicle wheels on which a monitoring device is mounted;

(3) FIG. 1b shows a block diagram of an electronic unit, the latter being part of the monitoring device of FIG. 1a;

(4) FIG. 2a schematically shows a perspective view of a positioning device, in accordance with a first embodiment, associated with a monitoring device;

(5) FIG. 2b schematically shows a perspective view of a portion of the device of FIG. 2a;

(6) FIG. 2c shows a plan view of the positioning device and the monitoring device of FIG. 2a;

(7) FIG. 2d shows a sectional view of the positioning device and the monitoring device along the line IId-IId shown in FIG. 2c;

(8) FIG. 2e shows a sectional view of the positioning device and the monitoring device along the line IIe-IIe shown in FIG. 2c;

(9) FIG. 2f schematically shows a plan view of the positioning device of FIG. 2a;

(10) FIG. 3a schematically shows an exploded view of a positioning device, in accordance with a second embodiment of the invention, associated with a monitoring device;

(11) FIG. 3b shows, in an operative configuration, the positioning device of FIG. 3a;

(12) FIG. 4a schematically shows a perspective view of a positioning device, in accordance with a third embodiment of the invention, associated with a monitoring device;

(13) FIG. 4b schematically shows a perspective view of the positioning device of FIG. 4a in a first operative condition;

(14) FIG. 4c schematically shows a sectional view of the positioning device of FIG. 4b, along the line IVb-IVb;

(15) FIG. 4d schematically shows a perspective view of the positioning device of FIG. 4a in a second operative condition;

(16) FIG. 4e schematically shows a side view of the positioning device of FIG. 4d;

(17) FIG. 5a schematically snows a perspective view of a positioning device, in accordance with a fourth embodiment, of the invention, in a first operative condition;

(18) FIG. 5b shows the positioning device of FIG. 5a, associated with a monitoring device;

(19) FIG. 5c shows the positioning device of FIG. 5a, 5b in a second operative condition;

(20) FIG. 5d shows the device of FIG. 5c with some parts removed, in order to better illustrate other parts thereof;

(21) FIG. 5e shows a sectional view, along the line Ve-Ve, of the positioning device and the monitoring device of FIG. 5c.

DETAILED DESCRIPTION OF THE INVENTION

(22) With reference to the attached figures, a tyre for vehicle wheels to which the installation method according to the present invention can be applied was indicated in its entirety

(23) The tyre 1 (FIG. 1a) comprises an inner surface 2, preferably comprising or constituted by the so-called “liner”.

(24) The monitoring device 10 is mounted on such inner surface 2.

(25) The monitoring device 10 comprises an electronic unit 20 (FIGS. 1a, 1b, 2c, 2d).

(26) Preferably, the electronic unit 20 comprises at least one sensor 21 and at least one antenna 22.

(27) For example, said sensor 21 is a pressure and/or temperature sensor, configured for detecting a pressure and/or a temperature inside the tyre 1.

(28) In a further embodiment, the sensor 21 cam be a sensor of the accelerometer type, configured for detecting mechanical stresses to which the tyre 1 is subjected.

(29) In addition or as an alternative, the sensor 21 can be a sensor of the inertial type.

(30) In one embodiment, the sensor 21 can be constituted at least in part by a self-powering (“energy scavenger”) system of the electronic unit, from which it is possible to obtain both the electrical power supply for the electronic unit itself, and signals, e.g. analogue signals, representative of the mechanical actions transmitted by the tyre.

(31) In general, the sensor 21 can also be employed for determining the number of revolutions of the tyre and/or the load acting on the tyre and/or the angular speed and/or parameters representative of operating conditions of the tyre (e.g. friction, wear and/or aquaplane conditions).

(32) The antenna 22 has at least the task of transmitting the data detected by the sensor 21 to the apparatuses on board the vehicle on which the tyre 1 is mounted.

(33) Preferably the electronic unit 20 also comprises a processing circuit 23, associated with the sensor 21 and with the antenna 22.

(34) The processing circuit 23 can have the task of managing (for example acquiring, and/or filtering, and/or processing) the signals detected by the sensor 21, for the purpose of obtaining the data to be stored and/or transmitted by means of the antenna 22.

(35) Preferably, the electronic unit 20 further comprises a power supply system 24, predisposed to supply electrical power to the electronic unit 20.

(36) Preferably the power supply system 24 comprises at least one battery. In addition or as an alternative to such battery, the power supply system 24 can comprise a device capable of transforming the mechanical energy transmitted to the device itself during the rolling of the tyre into electrical energy (energy scavenger).

(37) The antenna 22 can also receive signals from the apparatuses on board the vehicle and/or from systems placed outside the vehicle itself. For example, the electronic unit 20 can comprise two antennas, of which one is predisposed to transmit (e.g. at a frequency of 433 MHz) the processed and/or stored data, and another predisposed to receive (e.g. at a frequency of 125 kHz) signals from systems placed on board the vehicle and/or outside the vehicle itself (e.g. wake-up signals for the monitoring device, and/or signals containing pre-configuration data for the monitoring device, and/or signals containing programming instructions for the monitoring device).

(38) The electronic unit 20 can also comprise a memory 25, in which data relative to the operation of the tyre and/or configuration/setup data typically referred to the characteristics the tyre itself, and/or identification data of the monitoring device 10 and/or of the tyre 1 is stored. By way of example, in the memory 25 there can be stored data representative of the distance travelled by the tyre, preferably determined as a function of the overall number of revolutions carried out by the tyre itself. In the memory 25, it is also possible to store one or more procedures for processing the signal detected by the at least one sensor 21, and/or algorithms for calculating predetermined parameters starting from signals detected by the at least one sensor 21 (or on pre-processed signals), and/or signal filtering logic).

(39) Preferably the electronic unit 20 comprises a holding body 26, preferably rigid, in which the different elements (sensor, antenna, power supply system etc.) are housed.

(40) The holding body 26 can be obtained according to techniques that are very well known, for example embedding the circuitry of the electronic unit 20 in a resin casting which stiffens following the solidification thereof, or by means of moulding.

(41) Preferably the holding body 26 has at least one first expansion 26a inside which the antenna (or at least one of the antennas) 22 extends at least partly.

(42) Preferably the holding body 26 has a second expansion 26b inside which the sensor 21 extends at least partly. In case of pressure sensor and/or temperature sensor, the second expansion 26b has an opening (not shown), for the purpose of allowing the sensor to carry out the necessary measurements.

(43) The monitoring device 10 further comprises a connecting member 30.

(44) When the monitoring device 10 is fastened to the tyre 1, the connecting member 30 maintains the electronic unit 20 constrained to the tyre 1, and in particular to the inner surface 2 of the latter.

(45) Preferably the connecting member 30 is made in a single piece. Preferably the connecting member 30 is made of elastomeric material. Such elastomeric material can for example comprise a thermoplastic elastomer. In a preferred embodiment, the elastomeric material comprises a halogenated butyl rubber and a synthetic rubber (e.g. polybutadiene, or polyisoprene).

(46) Examples of elastomeric materials which can be employed are described in the international patent application published with number WO 2010/043264 on behalf of the same Applicant.

(47) The connecting member 30 has a housing cavity for the electronic unit 20. Preferably, such housing cavity is configured in such a manner that the connecting member 30 substantially completely encloses the electronic unit 20 (except for some projecting portions, as will be described below), in a manner such that the latter cannot be extracted from the housing cavity once the connecting member 30 is fastened, by means of the base portions thereof, to the inner surface 2 of the tyre 1.

(48) Preferably, the housing cavity has size such to ensure the formation of at least one interspace between the outer surface of the electronic unit 20 (in particular the containment body 26 thereof) and the inner walls of said connecting member 30 defining said housing cavity. In this embodiment, the electronic unit 20 is therefore enclosed in a loose manner inside the cavity predisposed in the connecting member 30.

(49) The connecting member 30 comprises an upper structure 30a and a lower structure 30b.

(50) The upper structure 30a and the lower structure 30b define, in cooperation, a housing for the electronic unit 20.

(51) Preferably, the upper structure 30a comprises a top wall 38.

(52) Preferably the top wall 38 has a rounded perimeter profile, for a connection with the lower structure 30b.

(53) Preferably the top wall 38 has at least one through window W, in which the abovementioned first and/or second expansion 26a, 26b of the containment body 26 can be at least partially extended.

(54) Preferably, the lower structure 30b comprises two base portions 31, 32.

(55) Preferably, each base portion 31, 32 comprises a respective side wall 33, 34 and a respective base wall 35, 36.

(56) Preferably, the side walls 33, 34 are separated by a pair of side windows 37a, 37b.

(57) Preferably the base portions 31, 32, and in particular the base walls 35, 36, are separated by a separation region Z. The separation region Z has a major extension direction X.

(58) Preferably each base portion 31, 32, and in particular each base wall 35, 36 has a respective base surface 35a, 36a, associable to the inner surface 2 of the tyre 1.

(59) Preferably the base walls 35, 36 have, in plan view, a substantially circular conformation.

(60) Preferably the major extension direction X of the separation region Z is directed along a diameter of said substantially circular conformation.

(61) The method according to the invention comprises providing a positioning device 40 for keeping the monitoring device 10 in an installation condition, i.e. a condition in which the base portions 31, 32 are maintained at a given mutual distance.

(62) The positioning device 40 comprises two separate active portions 41, 42.

(63) Preferably, the active portions 41, 42 are made of a substantially rigid material, for example a plastic or metallic material.

(64) Each active portion 41, 42 has a main surface 41a, 42a, the shape of which matches that of a respective portion P1, P2 of an outer surface S of the monitoring device 10.

(65) The active portions 41, 42 are adapted to cooperate with at least the base portions 31, 32 to keep the monitoring device 10 in the installation condition. In addition, the active portions 41, 42 are adapted to cooperate with at least the base portions 31, 32 in order to distribute the pressure exerted on the positioning device 40, in a substantially uniform manner along the perimeter of the monitoring device 10, in order to associate the connecting member 30 to the inner surface 2 of the tyre 1.

(66) Preferably, the abovementioned outer surface S, and the relative portions P1, P2, are extended along the side walls 33, 34 and/or on the base walls 35, 36 of the lower structure 30b.

(67) Advantageously, the outer surface S and the relative portions P1, P2 are extended both on the side walls 33, 34, and on the base walls 35, 36. In this manner, the active portions 41, 42 exert a hooping action around the monitoring device 10, and also allow distributing possible forces directed orthogonally to the inner surface 2 of the tyre 1 and aimed to promote the fastening operation in a substantially uniform manner.

(68) The method according to the invention further comprises associating the positioning device 40 to the monitoring device 10.

(69) Preferably such operation comprises placing each of the main surfaces 41a, 42a in a condition of substantial mutual contact with the respective outer-surface S portions P1, P2 of the monitoring device 10.

(70) Preferably, in order to associate the active portions 41, 42 with the monitoring device 10, the same active portions 41, 42 are moved along directions substantially parallel to the plane defined by the abovementioned base surfaces 35a, 36a.

(71) Preferably, such directions are substantially parallel to the major extension direction X of the separation region Z.

(72) Preferably the positioning device 40, when it is associated with the monitoring device 10, surrounds said monitoring device 10 in a substantially continuous peripheral manner according to at least one plane of substantially parallel to the base surfaces 35a, 36a in at least one portion thereof.

(73) Preferably each active portion 41, 42, seen in plan view, has a substantially C-shaped conformation having a pair of ends (41′, 41″, 42′, 42″).

(74) When the positioning device 40 is associated with the monitoring device 10, the ends of each of the active portions 41, 42 are substantially in contact with the ends of the other active portion. In practice, as schematically shown in FIG. 2f, the ends 41′, 41″ of the active portion 41 are substantially in contact with the corresponding ends 42′, 42″ of the active portion 42.

(75) Preferably, each of the active portions 41, 42 comprises a respective expansion 43, 44 extending from the respective main surface 41a, 42a.

(76) Preferably, when the positioning device 40 is associated with the monitoring device 10, each respective expansion 43, 44 is inserted between the base portions 31, 32.

(77) Preferably, the respective expansions 43, 44 are inserted between the base portions 31, 32 from opposite sides of the monitoring device 10 with respect to the electronic unit 20.

(78) In a preferred embodiment, the respective expansions 43, 44 are inserted in the abovementioned side windows 37a, 37b which separate the side walls 33, 34 of the lower structure 30b of the connecting member 30.

(79) In a different embodiment, the expansions 43, 44 are inserted between the base walls 35, 36.

(80) Preferably, each of said main surfaces 41a, 42a has a given conformation. Such conformation can be appreciated in section, evaluated when the positioning device 40 is associated with the monitoring device 10, according to at least one plane substantially perpendicular to a plane defined by the base surfaces 35a, 36a of the base portions 31, 32. The conformation of each of the main surfaces 41a, 42a is substantially L-shaped and comprises a first 45, 46 and a second 47, 48 portion.

(81) The first portion 45, 46 of the substantially L-shaped conformation substantially matches the shape of an outer surface of a respective side wall 33, 34 of the lower structure 30b of the connecting member 30.

(82) The second portion 47, 48 of the substantially L-shaped conformation substantially matches the shape of an outer surface of a respective base wall 35, 36 of the lower structure 30b.

(83) Once the monitoring device 10 is maintained in the installation condition, the base portions 31, 32, and in particular the base surfaces 35a, 36a, are fastened to the inner surface 2 of the tyre 1. This is due to a pressure action exerted (typically in a direction substantially orthogonal to the inner surface of the tyre 2) on the positioning device 40. Such pressure can be exerted for example manually on the outer surface of the active portions 41, 42.

(84) Preferably, the monitoring device 10 is fastened in such a manner that the major extension direction X of the separation region Z is disposed substantially in a radial plane of the tyre 1.

(85) The fastening of the monitoring device 10 to the inner surface 2 can be executed, for example, by means of bonding.

(86) Preferably, before proceeding with the fastening, the portion of the inner surface 2 of the tyre 1 where the monitoring device will be positioned undergoes a cleaning operation, for example by means of laser or chemical and/or mechanical agents.

(87) After the monitoring device 10 has been fastened to the inner surface of the tyre 1, the positioning device 40 is removed. Preferably the removal of the positioning device 40 comprises moving the main surfaces 41a, 42a away from the respective outer-surface S portions P1, P2 of the monitoring device 10.

(88) Preferably, in order to move the active portions 41, 42 away from the monitoring device 10, the same active portions 41, 42 are moved along directions substantially parallel to the plane defined by the abovementioned base surfaces 35a, 36a.

(89) Preferably such directions are substantially parallel to the major extension direction X of the separation region Z,

(90) In a first embodiment, the positioning device 40 comprises preferably only the two abovementioned active portions 41, 42 (FIGS. 2a-2f).

(91) Such active portions 41, 42 can be associated with the monitoring device 10, and removed from the same at the end of the fastening operation, also manually.

(92) In order to facilitate a correct orientation of the mounting device 10 (as said, the latter is preferably fastened in such a manner that the manor extension direction X of the separation region Z is disposed substantially in a radial plane of the tyre 1), at the ends 41′, 41″, 42′, 42″ graphical symbols 49 can be suitably predisposed, for example in relief; such graphical symbols 49 allow visually identifying a direction substantially orthogonal to the major extension direction X of the separation region Z (i.e. a circumferential direction of the tyre 1).

(93) In this manner, an installer who manually executes the fastening operation has all the indications required for a correct orientation of the monitoring device 10, even though the separation region Z is not visible, since it is covered by the active portions 41, 42.

(94) In a second embodiment (FIGS. 3a-3b), the positioning device 40 further comprises a ring nut 50, which can be fitted around the active; portions 41, 42 so as to maintain the same mutually associated.

(95) Preferably, the ring nut 50 is made of metallic material, such as aluminium or steel, or plastic material, such as nylon, Teflon or Bakelite.

(96) Preferably the positioning device 40 further comprises a piston 51, insert able into said ring nut 50 from the opposite side with respect to the monitoring device 10.

(97) Preferably, the piston 51 is made of metallic material, such as aluminium or steel, or plastic material, such as nylon. Teflon or Bakelite.

(98) Preferably the piston 51 has an outer surface 52, having substantially cylindrical extension, for example, along which the ring nut 50 can slide.

(99) The piston 51 can be advantageously employed for promoting fastening of the monitoring device 10 to the inner surface 2 of the tyre 1. Indeed, after positioning the monitoring device 10 on the inner surface 2 of the tyre 1, associating the active portions 41, 42 with the monitoring device 10, fitting the ring nut 50 outside the active portions 41, 42, and inserting the piston 51 into the ring nut 50, a force can be exerted on the piston 51 itself in a direction substantially orthogonal to the inner surface 2 of the tyre 1. Given that the piston 51 is substantially in contact with the monitoring device 10, such force is transmitted to the monitoring device 10 itself, thus promoting the fastening of the latter to the inner surface 2. The pressure is distributed substantially uniformly along the perimeter of the monitoring device 10 due to the active portions 41, 42. Indeed, possible forces in a direction parallel to the inner surface 2 of the tyre 1 tending to move the base portions 31, 32 of the connecting member 30 close together are obstructed by the presence of the expansions 43, 44; possible forces in a direction parallel to the inner surface 2 of the tyre 1 tending to move the base portions 31, 32 of the connecting member 30 apart are obstructed by the presence of the ring nut 50.

(100) Once the fastening operation has terminated, the ring nut 50 and the piston 51 can be removed, preferably before the active portions 41, 42 are moved away from the monitoring device 10.

(101) Preferably, the piston 51 has an end stop element 53 for said ring nut 50. The end stop element 53 intercepts the ring nut 50 in the movement thereof away from, the inner surface 2 of the tyre 1 so that, by continuing such movement, the ring nut 50 and the piston 51 can be integrally moved away from the monitoring device 10.

(102) By way of example, the end stop element 53 can comprise a plate-like element, with substantially circular element, having greater diameter relative to said piston 51 and mounted in a substantially concentric manner on the latter.

(103) In a third embodiment (FIGS. 4a-4e), the positioning device 40 comprises, in addition to the active portions 41, 42, also a pair of lever elements 61, 62.

(104) Each lever element 61, 62 is extended from a respective one of the active portions 41, 42.

(105) Each lever element 61, 62 has a distal end 61a, 62a relative to the corresponding active portion 41, 42.

(106) Preferably the distal ends 61a, 62a of the lever elements 61, 62 are mutually associated with each other in such a manner that the positioning device 40 can be configured between an open condition and a closed condition.

(107) In the open condition, the active portions 41, 42 are sufficiently spaced so that the monitoring device 10 can be positioned between the active portions 41, 42 themselves.

(108) In the closed condition, the active portions 41, 42 are closed around monitoring device 10 under the action of the lever elements 61, 62.

(109) The mutual bond between the distal ends 61a, 62a of the lever elements 61, 62 can be obtained, for example, by making the two lever elements 61, 62 as a single piece, made of elastically deformable material, or by means of a pin that allows the two lever portions 61, 62 to rotate with respect to each other along a rotation axis defined by the longitudinal extension of the pin itself.

(110) In this embodiment, the positioning device 40 further comprises a hooping member 63, which can be fitted at least partly around said lever elements 61, 62 and/or said active portions 41, 42 to keep the positioning device 40 in the closed condition.

(111) Preferably, the hooping member 63 is fitted on the lever elements 61, 62 at the distal ends 61a, 62a, i.e. on the opposite side with respect to the active portions 41, 42.

(112) Preferably at least one of the lever elements 61, 62 has a shoulder 65, 66 having a respective abutment surface 65a, 66a which acts as an end stop for the hooping member 63, when the latter is fitted around the lever portions 61, 62.

(113) Preferably, the hooping member 63 is associated with a thrust element 64 which, when the positioning device 40 is in the closed condition and the hooping member 63 is fitted on the lever elements 61, 62 and/or on the active portions 41, 42, is extended between the lever elements 61, 62 themselves and comes into contact with the monitoring device 10. The thrust element 64 thus allows exerting a force, on the monitoring device 10, which promotes the fastening of the latter to the inner surface 2 of the tyre 1.

(114) Preferably, graphical signs 67 are predisposed on the top of the hooping member 63, such graphical signs 67 allowing a correct orientation of the monitoring device 10 during the fastening operation.

(115) Therefore, by employing a positioning device 40 in accordance with this third embodiment, the installation method can comprise one or more of the following actions: configuring the positioning device 40 in the open condition; this operation can be executed, for example, by manually mutually moving the active portions 41, 42 apart, by acting on the same and/or on the respective lever elements 61, 62; positioning the monitoring device 10 between the active portions 41, 42; while the monitoring device 10 is interposed between the active portions 41, 42, configuring the positioning device 40 in the closed condition; even this operation can be manually executed, for example, by acting directly on the active portions 41, 42 and/or on the respective lever elements 61, 62; fitting the hooping member 63 around the lever elements 61, 62 and/or the active portions 41, 42, and bringing the thrust element 64 in contact with the monitoring device 10; executing the fastening operation, preferably promoting it by exerting on the monitoring device 10, by means of the thrust element 64, a force substantially orthogonal to the surface 2 of the tyre 1; at the end of the fastening operation, configuring the positioning device 40 in the open condition, mutually moving the active portions 41, 42 apart.

(116) In a fourth embodiment (FIGS. 5a-5d), the positioning device 40 comprises, in addition to the two active portions 41, 42, an actuator member 70 configured for driving said active portions 41, 42 between a mutually moved apart position and a mutually moved close position.

(117) Preferably, the actuator member 70 comprises a command element 71, that can be actuated in rotation, and a transmission element 72, interlocked with said command element 71, for moving the active portions 41, 42 upon the actuation of the command element 71 itself.

(118) Preferably, the transmission element 72 can be configured in a first condition, in which it causes mutual moving apart between the active portions 41, 42, and a second condition, in which it allows mutual moving close between the active portions 41, 42.

(119) Preferably, the actuator member 70 further comprises at least one elastic-return structure 73 for moving the active portions 41, 42 close to each other when the transmission element 72 is in the second condition.

(120) Preferably the positioning device 40 further comprises a support structure 74, for example having a substantially cylindrical conformation.

(121) The active portions 41, 42, together with the actuator member 70, are advantageously mounted on the support structure 74.

(122) By way of example, the elastic-return structure 73 can comprise a pair of springs, each having a first end fastened to a respective one of the active portions 41, 42, and a second end fastened to the other active portion.

(123) Preferably, said positioning device 40 further comprises a stop element 75, which is moved upon the movements of said command element 71 and/or transmission element 72. In a preferred embodiment, the stop element 75 is substantially integral with the command element 71 and/or with the transmission element 72.

(124) The stop element 75 is adapted to cooperate with one or more abutment surfaces 76a, 76b, defining respective end stop positions for said stop element 75.

(125) Preferably, said one or more abutment surfaces 76a, 76b are internal surfaces of a recess 77 obtained in the support structure 74.

(126) In practice, when the command element 71 and/or the transmission element 72 are moved, typically for driving the active portions 41, 42 between the mutually moved close position and the mutually moved apart position, the stop element 75 is moved along the recess 77. When the stop element 75 is in abutment on one of the abutment surfaces 76a, 76b, it stops the command element 71 and the transmission element 72, since the active portions 41, 42 have reached the end configuration thereof, i.e. one of the abovementioned mutually moved close or mutually moved apart positions.

(127) Hence, by employing a positioning device 40 in accordance with this fourth embodiment, the installation method can comprise one or more of the following actions: operating the actuator member 70 for driving the active portions 41, 42 in the mutually moved apart position; positioning the monitoring device 10 between the active portions 41, 42; while the monitoring device 10 is interposed between the active portions 41, 42, operating the actuator member 70 for driving the active portions 41, 42 themselves in the mutually moved close position; executing the fastening operation; once the fastening operation has terminated, operating the actuator member 70 for driving the active portions 41, 42 in the mutually moved apart position.

(128) A kit for installing the monitoring device 10 in the tyre 1 is also an object of the present invention.

(129) Such kit comprises the monitoring device 10 and the positioning device 40. The kit typically comprises an adhesive (e.g. cyanoacrylate-based glue) to be affixed to the base surfaces 35a, 36a of the connecting member 30 for the purpose of fastening the monitoring device 10 to the inner surface 2 of the tyre 1. The kit typically also comprises materials for the treatment and cleaning of the inner surface 2 of the tyre 1 (e.g. chemical and/or mechanical agents).

(130) By employing the abovementioned first embodiment of the positioning device 40, which substantially comprises the single active portions 41, 42, a kit can be sold having the active portions 41, 42 already associated with the monitoring device 10. In other words, the kit thus achieved allows supplying the monitoring device 10 already correctly configured and maintained, by means of the active portions 41, 42, in the installation condition. The monitoring device 10 is then ready to be fastened to the inner surface 2 of the tyre 1.