Technical field

The disclosed solution relates to tires, particularly prefabricated tires, comprising inserts. In particular, the disclosed solution relates to methods for inserting such in inserts into such tires.

Background

It is known that inserts, such as studs, may be inserted into tires by way of first bringing about insert-appropriate holes with molds in conjunction with fabricating, i.e. manufacturing, of the tires, then removing the molds, and eventually inserting inserts into the mold-shaped holes in the tires.

Such a method, however, requires the holes for inserts to be made in conjunction with fabricating the tires, which has the drawback that the number, position(s) and the shape(s) of the holes for the inserts need to be known before the tires are manufactured.

Consequently, such a method is not suitable for retro-fitting already manufactured tires with inserts whose number, position(s), shape(s) and/or dimension(s) are/were not already known or otherwise completely anticipated in advance of manufacturing the tires.

Furthermore, the aforementioned known mold-based method is mainly suitable, especially with respect to efficiency and expediency, for large-batch manufacturing with little or preferably no variation in tires with respect to their equipping with inserts.

Consequently, such method is not suitable for variably equipping tires with application-appropriate inserts, including their number, positioning, shape and dimensioning. Such inappropriateness concerns over the known mold-based method are particularly pronounced in - but not exclusive to - the case of so-called‘smart’ tires. Such‘smart’ tires may comprise various inserts with variable functionality - such as measuring wear, friction, moisture and acceleration - shape, dimensioning and positioning in the tire. In other words,‘smart’ tires may be made differentially‘smart’ by way of differentially incorporating application- appropriate inserts in them. In other words, ‘smart’ tires preferably can be tailored in terms of their insert configuration, and most preferably such tailoring can be accomplished at the level of an individual tire.

Such problems cannot be satisfactorily addressed with drilling, with a normal drill bit, holes for inserts, because - as is known - the resulting cylindrical holes do not offer structural, geometry-induced support against inserts coming off from such cylindrical holes.

In addition, inserts that are typically required in‘smart’ tires usually comprise electronic components or are otherwise more fragile than metal- and/or ceramics-based friction-increasing inserts typically used in studded tires.

Consequently, the currently employed robotized or automatized methods for inserting inserts into a tire, such as those based on a so-called‘stud gun’, bear the risk of damaging fragile inserts such as those typically required in‘smart’ tires.

In view of the foregoing, the aim of the disclosed solution is to address and alleviate the above-mentioned problems in inserting inserts into tires, particularly vulcanized tires and, analogously, into prefabricated tires fabricated in another way.

Summary

The disclosed solution comprises a method for making a blind hole in a prefabricated tire. The method comprises arranging available a prefabricated tire comprising tread blocks forming the tread of the tire, and thereafter machining such a blind hole to a tread block of the tire that the blind hole has a first cross section at a first depth and a second cross section at a second depth, wherein the second cross section is greater than the first cross section and the second depth is greater than the first depth.

The principles of the disclosed solution apply also to tires which do not comprise distinct tread blocks, as would be in the case of a slick tire or a grooved tire. In such cases, the blind hole is machined to a tread of such a tire.

The disclosed solution also comprises a method for inserting an insert into a tread of a prefabricated tire, the method comprising arranging available the insert, making a blind hole as mentioned above, in a prefabricated tire, and thereafter inserting the insert into the blind hole.

Thus, according to the disclosed solution, such a blind hole may be machined in a prefabricated, i.e. an already fabricated, tire that the blind hole is capable of providing structural, geometry-induced support for an insert against the insert coming off from the blind hole. For example, an insert with a bottom flange may installed in such a blind hole so that the second cross section at a second depth may accommodate the flange while the rest of the body of the insert is accommodated by the first cross section of the blind hole.

As the blind holes are, according to the disclosed solution, machined in a prefabricated tire, such blind holes may be machined in any desired number and/or position in the tire. Furthermore, by appropriately selecting the machining implements and methods, the shape and dimensionality of a blind hole may be selected, as will be described more in detail further below.

With respect of the shape of an insert installable in such a blind hole, according to the disclosed solution, the insert may extend in a longitudinal direction from a bottom of the insert to a top of the insert. Such an insert may have a first cross section at a first longitudinal position from the bottom and a second cross section at a second longitudinal position from the bottom. Therein, the first longitudinal position is located closer to the top than the second longitudinal position and the second cross section is greater than the first cross section. According to the disclosed solution, such an insert may be inserted into the blind hole such that the bottom of the insert is inserted deeper in the blind hole than the top of the insert. Thus, the shape of the insert may be selected co-operatively with the shape of the blind hole in such a manner that the insert may gain structural support from the blind hole against coming off from the blind hole. For example, the insert may comprise a bottom flange which is dimensionally compatible with the second cross section of the blind hole.

Specifically, with respect to ensuring and/or improving the staying of an insert in its installed position in the blind hole, according to the disclosed solution, such a blind hole may be machined to a tread block that the shape of the blind hole is geometrically congruent with the insert. Preferably, the blind hole is machined such that a wall of the blind hole comprises a marking being indicative of the blind hole having been machined to the tread block after the tread block was fabricated.

Consequently, a tire according to the disclosed solution may be such that a wall of the blind hole comprises a marking being indicative of the blind hole having been machined to the tread block after the tread block was fabricated. Alternatively or in addition, a tire according to the disclosed solution may be such that removal of an insert from the tread block exposes such a blind hole that a wall of the blind hole comprises a marking being indicative of the blind hole having been machined to the tread block after the tread block was fabricated.

With respect to inserts typically required in ‘smart’ tires, according to the disclosed solution, the insert may comprise a primary capacitive component and a primary inductive component. Such an insert may be configured to measure a condition, such as wear, of the tire, and/or be configured to measure an environmental parameter, such as humidity or friction - as an example, the insert may comprise a sensor for the purpose - and/or be configured to indicate a condition, such as wear, of the tire, and/or be configured to improve the friction of the tire.

In order to protect the integrity of the insert(s) during installation into a blind hole, according to the disclosed solution, before inserting the insert into the blind hole at least a part of the insert may be arranged into a sleeve, followed by inserting the insert to the blind hole with the sleeve. Brief description of the drawings

Fig. 1 a illustrates a tire.

Fig. 1 b illustrates, in a half cross section, a tire comprising an insert in a blind hole.

Fig. 1 c illustrates, in a half cross section, a tire comprising an insert in a blind hole, and an interrogator.

Figs. 2a-2i illustrate inserts according to examples.

Fig. 3a illustrates a blind hole in a tread block of a tire, as viewed cross- sectionally from a side.

Fig. 3b illustrates, in a tread block of a tire, a blind hole comprising markings on its wall(s), as viewed cross-sectionally from a side

Figs. 4a-4c illustrate an insert in a blind hole according to examples, as viewed cross-sectionally from a side.

Fig. 5a illustrates a insert according to an example, as viewed cross- sectionally from a side.

Fig. 5b illustrates an insert in a blind hole according to examples, as viewed cross-sectionally from a side.

Figs. 6a-6c illustrate sequentially progressing phases of machining, with a drill bit comprising a protrusion, a blind hole into a tread block of a tire, as viewed cross-sectionally from a side

Figs. 7a-7c illustrate sequentially progressing phases of machining, with a drill bit comprising a radially expanding part, a blind hole into a tread block of a tire, as viewed cross-sectionally from a side

Figs. 8a-8c illustrate sequentially progressing phases of machining, with a drill bit used in various angles, a blind hole into a tread block of a tire, as viewed cross-sectionally from a side

Fig. 9 illustrates a drill bit according to an example

Fig. 10a illustrates an insert with a sleeve, as viewed cross-sectionally from a side.

Fig. 10b illustrates an insert with a sleeve, as viewed from above

Fig. 10c1 illustrates an insert comprising a flange, as viewed from above Fig. 10c2 illustrates the insert of Fig. 10c1 with a sleeve, as viewed from above.

Fig. 10d 1 illustrates an insert comprising a flange, as viewed from above Fig. 10d2 illustrates the insert of Fig. 10d 1 with a sleeve, as viewed from above. Fig. 10e1 illustrates an insert comprising a flange, as viewed from above Fig. 10e2 illustrates the insert of Fig. 10e1 with a sleeve, as viewed from above.

Figs. 1 1 a -1 1 b illustrate, according to examples, a sleeve, as viewed cross- sectionally from a side.

Fig. 12a illustrates an insert and a punch comprising a sleeve, according to an example and as viewed cross-sectionally from a side

Fig. 12b illustrates a punch comprising a sleeve with an insert in the sleeve, according to an example and as viewed cross-sectionally from a side.

Fig. 12c illustrates, according to an example, expelling an insert form a sleeve with a rod.

Fig. 13a illustrates an insert and a punch comprising a sleeve, according to an example and as viewed cross-sectionally from a side Fig. 13b illustrates a punch comprising a sleeve with an insert in the sleeve, according to an example and as viewed cross-sectionally from a side.

Fig. 13c illustrates, according to an example, expelling an insert form a sleeve with a rod.

Fig. 14 illustrates, in a blind hole, an insert in a sleeve, as viewed cross- sectionally from a side.

Figs. 15a- 15b illustrate sequentially progressing phases of removing a sleeve from a blind hole such that a sleeve-installed insert remains in the blind hole, as viewed cross-sectionally from a side.

Figs. 16a- 16b illustrate sequentially progressing phases of inserting an insert into a blind hole with a tool, as viewed cross-sectionally from a side.

Fig. 16c illustrates, insertion of an insert in a blind hole with a tool, as viewed cross-sectionally from a side.

Fig. 16d illustrates, in a close-up, one end of the tool of Fig. 16c with an insert, as viewed cross-sectionally from a side

Fig. 16e illustrates, the tool of Fig. 16d, according to an alternative example, with an insert, as viewed cross-sectionally from a side

Fig. 17 illustrates determining a distance between a tread and a reinforcing belt, as viewed cross-sectionally from a side. The Figures are intended to illustrate the general principles of the disclosed solution. Therefore, the illustrations in the Figures are not necessarily in scale or suggestive of precise layout of system components.

Detailed description

In the text, references are made to the Figures with the following numerals and denotations:

100 Tire

1 10 T read block, of tire

1 12 Blind hole

1 12a Bottom, of blind hole

1 12b Aperture, of blind hole

1 12c Wall, of blind hole

1 13 Marking

1 14 Adhesive

120 Tread, of tire

122 Groove

130 Inner surface, of tire

150 Reinforcing belt

155 Ply

200 Insert

202 Bottom, of insert

204 Top, of insert

205 Side, of insert

207 Flange, of insert

210 Primary capacitive component

220 Primary inductive component

230 Flard metal pin

235 Supportive flange

240 Sensor

300 Interrogator

310 Communication circuit

320 Secondary inductive component

330 Power source

340 Sensor 400 Drill bit

410 Shaft, of drill bit

420 Protrusion, of drill bit

430 Flange, of drill bit

450 Part, of drill bit shaft

500 Tool

502 Jaw, of tool

504 Jaw, of tool

510 Cylinder

512 Punch

514 Rod

550 Sleeve

555 Wall, of sleeve

560 First aperture, of sleeve

565 Cavity, of sleeve

570 Second aperture, of sleeve

600 Position sensor

900 Surface

a Angle

A1 First cross section, of insert

A2 Second cross section, of insert

A3 First cross section, of sleeve

Amax Maximal cross-sectional area, of insert

AXR Axial direction

C1 First cross section, of blind hole

C2 Second cross section, of blind hole d l 12 Depth, of blind hole

dl50 Distance, between tread and reinforcing belt del First depth, in blind hole

de2 Second depth, in blind hole

N1 Normal, of tread

Pmax Plane of maximum cross section

r1 First longitudinal position, in insert r2 Second longitudinal position, in insert

SR Radial direction

t555 Thickness, of sleeve wall

z200 Longitudinal direction Referring to Fig. 1 a, the disclosed solution relates to a tire 100. Such a tire 100 may be pneumatic and/or prefabricated.

As a terminological clarification, and as readily appreciated by a person skilled in the art, a prefabricated tire 100 means a tire 100 which has been manufactured, i.e. fabricated, and could be used already as such without additional furnishings such as those described below. Such a prefabricated tire 100 may be, for example, a vulcanized tire 100, but may be prefabricated in another way as well .

Such a 100 tire may be, for example, a tire 100 for a passenger vehicle, such as a passenger car or a motorcycle. Such a tire 100 may be, for example, a so-called heavy tire, for a heavy machine such as a truck, a caterpillar, a harvester or a front loader. Such a tire 100 may be a tire for use on slippery surfaces, such as a winter tire.

Such a tire 100 typically comprises a tread 120, which is in contact with a surface 900 such as a road surface during the normal use of the tire 100. Such a tread 120 typically comprises a tread pattern which comprises a plurality of tread blocks 1 10. Such tread blocks 1 10 typically are surrounded by grooves 122.

The material of the tread blocks 1 10, or at least the tread block 1 10 in which an insert 200 is installed in accordance with what is described below, may have a Shore hardness of from 50 ShA to 80 ShA according to ASTM standard D2240, version 15e1 . According to an example, the tread block(s) have such a Shore hardness at a temperature of 23 °C.

As is known, a tire 100 may rotate around an axis of rotation AXR, in which case an outward centrifugal force acts on the constituent parts of the tire 100 along a radial direction SR.

As is typical for certain types of tires 100, and as is illustrated in Figs. 1 b-1 c, the tire 100 may comprise a reinforcing belt 150 arranged between the tread 120 and the inner surface 130 of the tire 100. According to the disclosed solution, such a tire 100 may be equipped with an insert 200 and, therefore, comprise an insert 200. Such an insert 200 may be, for example, a friction-increasing stud as is typical in winter tires. As another example, such an insert 200 may be configured to sense a measure of interest such as the wear of the tread 120 of the tire 100. As yet another example, such an insert 200 may combine the above-mentioned capabilities of a stud and sensing a measure of interest.

Correspondingly, the disclosed solution comprises a method for inserting an insert 200 into a tread 120 of a tire 100, preferably a prefabricated tire 100, such as a vulcanized tire 100.

A tire 100 according to the disclosed solution may comprise one or more inserts 200. Such inserts 200 may be of one or more different types.

Now referring to Fig. 1 c, in case a tire 100 comprises an insert 200 configured to sense a measure of interest, the tire 100 may comprise an interrogator 300 configured to communicate with the insert 200. Such an interrogator 300 may be attached to the inner surface 130 of the tire 100. Such an interrogator 300 may comprise a power source 330, preferably an electric power source 330, to provide electricity for powering the functionality of the interrogator 300 and an communication circuit 310 to perform measurements and communication to external device(s) (not depicted). Typically, the power source 330 is a battery configured to provide electricity by converting chemical energy into electricity. Alternatively or in addition, the power source 330 may comprise an energy harvesting device, such as a piezoelectric energy harvesting device or a triboelectric energy harvesting device, which device may comprise a battery and/or a capacitor as one of its elements.

For the purposes of communication between an insert 200 and an interrogator 300, the insert 200 may comprise a primary inductive component 200 and a primary capacitive component 210 - as is illustrated in Figs. 2a and 2f for example - and the interrogator 300 may comprise a secondary inductive component 320. In such a case, the communication between the insert 200 and the interrogator 300 may arise from the secondary inductive component 220 being capable of transforming magnetic energy into electricity, which becomes temporarily stored in a primary capacitive component 210. Such magnetic energy may originate from a primary inductive component 320 of the interrogator 300. The interrogator 300 may thereby comprise an energy source, such as a power source 330, for example a battery, to provide energy for the components and functioning of the interrogator 300, including an inductive component 320. Consequently, the interaction between the passive circuit 200 and the interrogator 300 may be premised on the mutual inductance of the secondary inductive component 220 and the primary inductive component 320. That is, the primary inductive component 320 and the secondary inductive component 220 may be in an electromagnetic connection with each other.

Specifically, the method according to the disclosed solution may comprise attaching an interrogator 300 onto an inner surface 130 of a prefabricated tire 100, wherein the interrogator 300 is configured to magnetically couple with the insert 200. Such an interrogator 300 may comprise comprises a power source 330, a communication circuit 310, and a secondary inductive component 320, and the secondary inductive component 320 may be configured to magnetically couple with a primary inductive component 220 of the insert 200.

Figs. 2a-2i illustrate examples of inserts 200 in accordance with the disclosed solution.

As illustrated in Fig. 2a, an insert 200 may comprise a primary capacitive component 210 and a primary inductive component 220, for example to enable communication with an interrogator 300. As illustrated in Fig. 2f, such an insert 200 may comprise a flange 207. If the insert 200 is arranged to sense the wear of the tread 120 for example, the secondary capacitive component 210 may wear with the tread 120 as a consequence of the insert 200 having been inserted into the tread 120, whereby the sensing of the wear of the tread 120 may be premised on the wear-induced change in the capacitance of the capacitive component 210. In view of the preceding, the insert 200 may, thus, be configured to measure a condition, such as wear, of the tire (100).

As illustrated in Fig. 2b, an insert 200 may comprise a hard metal pin 230 at that end of the insert 200 which is configured to be in contact with a surface 900. An insert 200 thusly equipped with a hard metal pin 230 may also comprise a flange at or towards the other end of the insert 200. Thus, an insert 200 may be configured to improve the friction of the tire 100.

As illustrated in Fig. 2c, an insert 200 comprising a hard metal pin 230 may comprise a supportive flange 235 movably connected to the body of the insert 200. Such a supportive flange 235 may therefore be configured to allow the insert 200 to move relative to supportive flange 235, i.e. have some travel through but without becoming separated from the supportive flange 235. With such a configuration, the pressing force of hard metal pin 230 against the surface 900 may be controllably reduced, and consequently the wear of the surface 900 reduced.

An insert 200 may be configured to indicate a condition, such as wear, of the tire 100. Towards such an end, as illustrated in Figs. 2d and 2g, an insert 200 may, for example, be variably colored along the vertical dimension of the insert 200. With such variable coloring, the degree of wear of the insert 200 may be visually observed based on the color of the insert 200. As illustrated by Figs. 2d and 2g, such a variably colored insert 200 may comprise, with respect to its vertical cross section, a conical shape or a double-conical shape, or another geometrical shape.

An insert 200 may be configured to measure an environmental parameter, such as humidity or friction. Towards such an end, as illustrated in Fig. 2e, an insert 200 may comprise a sensor 240 for the purpose. In such a case, the insert 200 may also comprise means for communicating with an interrogator 300, such as a primary inductive component 220.

As illustrated in Figs. 2h and 2i, an insert 200 may comprise a more complex geometrical shape, which shape may be configured to facilitate the staying of the insert 200 in its installed position in a tread block 1 10 of a tire, such as in a blind hole 1 12 in a tread block 1 10 of a tire. As a specific example of such a more complex geometrical shape, an insert 200 may comprise, with respect to its vertical cross section, two or more flanges vertically separated from each other, as illustrated in Fig. 2h in the case of two flanges. As another specific example of such a more complex geometrical shape, an insert 200 may comprise, with respect to its vertical cross section, undulating side walls, as illustrated in Fig. 2i. Now referring to Fig. 3a, according to the disclosed solution an insert 200 is inserted to a tread 1 10 block of a tire 100, preferably a prefabricated tire 100. Towards that end, after arranging available a tire 100 comprising tread blocks 1 10 forming the tread 120 of the tire 100 and arranging available the insert 200, a blind hole 1 12 may be machined to a tread block 1 10 of the tire. Thereafter, the insert 200 may be inserted to the blind hole 1 12.

In case the tire 100 is a pneumatic tire 100, the tire 100 may be inflated at the time of machining to the blind hole 1 12.

Such a blind hole 1 12 may be manufactured to the tread block 1 10 by drilling. Herein, by drilling is referred to cutting a hole with a rotary cutting implement. Below, such a rotary cutting implement is also referred to as a drill bit.

Still referring to Fig. 3a, such a blind hole 1 12 extends, from its bottom 1 12a to an aperture 1 12b in the tread block 1 10, in a longitudinal direction z200, the longitudinal direction z200 being parallel to or forming an angle a of at most 75 degrees with a radial direction SR of the tire at the location of the blind hole 1 12.

According to an example, a blind hole 1 12 is a hollow of revolution, i.e. a hollow space in a shape of a solid of revolution. In such a case, the revolution is around the longitudinal direction z200.

Still referring to Fig. 3a, between the bottom 1 12a and the aperture 1 12b, the blind hole 1 12 is delimited by wall(s) 1 12c. As seen in Fig. 3a, the wall(s) 1 12c may be non-linear in terms of its/their vertical progression. That is, a blind hole 1 12 has a first cross section C1 at a first depth del and a second cross section C2 at a second depth de2, and those cross sections C1 and C2 may be different from each other. For the purposes of improving the staying of an insert 200 in its installed position in a blind hole 1 12 - especially in the case of an insert 200 comprising a flange 207 at its non-surface 900-facing end - the blind hole 1 12 may be wider from one depth than at another depth. That is, it may be the case that the blind hole 1 12 has a first cross section C1 at a first depth del and a second cross section C2 at a second depth de2, wherein the second cross section C2 is greater than the first cross section C1 and the second depth de2 is greater than the first depth del . Now referring to Fig. 3b, the wall(s) 1 12c of the blind hole 1 12 may comprise a marking 1 13 or several markings 1 13 being indicative of the blind hole 1 12 having been machined to the tread block 1 10 after the tread block 1 10 was fabricated. Such a marking 1 13 or markings 1 13 may be provided upon machining the blind hole 1 12, i.e. machining the blind hole 1 12 in such a way that the wall(s) 1 12c comprise(s) marking(s) 1 13. In effect, the marking(s) 1 13 entail that it is possible to discern the blind hole 1 12 as having been manufactured by machining instead of, for example, with metal rods during fabrication of the tire 100. Such marking(s) 1 13 may be constituted by, for example, the inherent or controlled resultant roughness brought about the implement with which the blind hole 1 12 is manufactured.

Thus, the disclosed solution also comprises a prefabricated tire 100 comprising tread blocks 1 10 forming a tread 120 of the tire 100, wherein at least one of the tread blocks 1 10 defines such a blind hole 1 12 that the blind hole 1 12 has a first cross section C1 at a first depth del and a second cross section C2 at a second depth de2, wherein the second cross section C2 is greater than the first cross section C1 and the second depth de2 is greater than the first depth del . Furthermore, and in particular, in such a tire 100, a wall 1 12c of the blind hole 1 12 comprises a marking 1 13 being indicative of the blind hole 1 12 having been machined to the tread block 1 10 after the tread block 1 10 was fabricated.

Correspondingly, the disclosed solution also comprises a prefabricated tire 100 comprising tread blocks 1 10 forming a tread 120 of the tire 100, and a removable insert 200 arranged in one of the tread blocks 1 10 such that removal of the insert 200 from the tread block 1 10 exposes such a blind hole 1 12 that the blind hole 1 12 has a first cross section C1 at a first depth del and a second cross section C2 at a second depth de2, wherein the second cross section C2 is greater than the first cross section C1 and the second depth de2 is greater than the first depth del . Furthermore, and in particular, in such a tire 100, a wall 1 12c of the blind hole 1 12 comprises a marking 1 13 being indicative of the blind hole 1 12 having been machined to the tread block 1 10 after the tread block 1 10 was fabricated.

Such marking(s) 1 13 may additionally increase the friction between the blind hole 1 12 and the insert 200 installed in the blind hole 1 12 and/or enable greater adhesive force between the blind hole 1 12 and the insert 200 if adhesive 1 14 is so used, as in an example illustrated in Fig. 5b. Thus, adhesive 1 14 may be applied in between the insert 200 and the tread block 1 10 in order to improve the staying of the insert 200 in its installed position in the blind hole 1 12.

Now referring to Fig. 4a, according to the disclosed solution, the insert 200 extends in a longitudinal direction z200 from a bottom 202 of the insert to a top 204 of the insert. Furthermore, the insert 200 comprises a side wall 205 or side walls 205 between its top 204 and its bottom 202. Further still, the insert 200 has a first cross section A1 at a first longitudinal position r1 from the bottom 202 and a second cross section A2 at a second longitudinal position r2 from the bottom 202, wherein the first longitudinal position r1 is located closer to the top 204 than the second longitudinal position r2 and the second cross section A2 is greater than the first cross section A1 .

According to an example, and preferably if a blind hole 1 12 is a hollow of revolution, the insert 200 is a solid of revolution.

Nonetheless, preferably the insert 200 and the blind hole 1 12 receiving the insert 200 are substantially of the same geometrical shape. That is, preferably, the blind hole 1 12 is machined to a tread block 1 10 such that the shape of the blind hole 1 12 is geometrically congruent with the insert 200. By doing so, the staying of the insert 200 in its installed position in the blind hole 1 12 may be improved as there is uniform and little to no clearance between the insert 200 and the blind hole 1 12. It is to be appreciated that in the case the insert 200 and the blind hole 1 12 being substantially of the same geometrical shape, the blind hole 1 12 may, in some cases, be smaller than the insert 200 in terms of the volume of the blind hole 1 12, as the material composition of its wall(s) 1 12c and its bottom 202 allow the blind hole 1 12 to stretch and thereby increase in volume.

Consistently with the foregoing, according to the disclosed solution, the insert 200 may be inserted to the blind hole 1 12 such that the bottom 202 of the insert 200 is inserted deeper in the blind hole 1 12 than the top 204 of the insert 200.

Thus, the insert 200 may comprise a flange 207 which is wider than the rest of the insert 200 such that the flange 207 resides at the non-surface 900-facing end of the insert 200. The flange 207 may be located such that it resides on the plane on which the cross section of the insert 200 is at its greatest - i.e. on the plane of maximum cross section Pmax there is the maximal cross-sectional area Amax for the insert 200. However, the maximal cross-sectional area Amax need not correspond to a specific flange 207 as illustrated according to examples in Figs. 4b-4c.

Now referring to Figs. 6a to 6c, a blind hole 1 12 may be machined to a tread block 1 10 of a tire 100 by drilling by using a drill bit 400 that comprises a shaft 410 extending in a longitudinal direction of the drill bit 400. Furthermore, such a drill bit 400 may comprise a protrusion 420 such as a flange 430 - as specifically illustrated in Fig. 9 - radially extending from the shaft 410. In such a case, the second cross section C2 of the blind hole 1 12 may be formed by using the protrusion 420 of the drill bit 400. Thus, as sequentially illustrated in Figs. 6a to 6c, a drill bit 400 comprising the protrusion 420 may penetrate along the longitudinal direction z200 into the tread block 1 10 thereby forming the first cross section C1 , and thereafter move perpendicularly to the longitudinal direction z200 thereby forming the second cross section C2 with the protrusion 420.

Alternatively or in addition, and now referring to Figs. 7a to 7c, a blind hole 1 12 may be machined to a tread block 1 10 of a tire 100 by drilling by using a drill bit 400 that comprises a shaft 410 extending in a longitudinal direction of the drill bit 400. Furthermore, a part 450 of the shaft 410 of the drill bit 400 may be configured to radially expand in use. In such a case, the second cross section C2 of the blind hole 1 12 may be formed by using the radially expanding part 450 of the shaft 410. In other words, the cross section C2 of the blind hole 1 12 may be formed with a diameter-expanding part of a drill bit 400. Thus, as sequentially illustrated in Figs. 7a to 7c, a drill bit 400 comprising the a radially expanding part 450 may penetrate, with the radially expanding part 450 in a non-expanded state, along the longitudinal direction z200 into the tread block 1 10 thereby forming the first cross section C1 . Thereafter, the radially expanding part 450 may be expanded, whereby the expanded part 450 in an expanded state may form the second cross section C2. And lastly, the drill bit 400 may be withdrawn, with the radially expanding part 450 in a non-expanded state, from the formed blind hole 1 12. Alternatively, or in addition, and now referring to Figs. 8a to 8c, a blind hole 1 12 may be machined to a tread block 1 10 of a tire 100 by drilling by using a drill bit 400 comprising a shaft 410 in such a way that the second cross section C2 of the blind hole 1 12 is made larger than the first cross section C1 by arranging the longitudinal direction of the shaft 410 at various angles relative to a normal N1 of the tread 120. Thus, as sequentially illustrated in Figs. 8a to 8c, the drill bit 400 may first penetrate along the longitudinal direction z200 into the tread block 100, after which the drill bit 400 may be tilted into various angles in such a manner that the bottom 1 12a of the blind hole 1 12 becomes cross- sectionally larger than its aperture 1 12b. The resulting blind hole 1 12 may be a hollow of revolution in shape.

Now referring to Figs. 16a and 16b, an insert 200 may be inserted into a blind hole 1 12 such that at least part of the blind hole 1 12 that has the first cross section C1 is laterally stretched while inserting the insert 200 into the blind hole 1 12. That is, the blind hole 1 12 may be stretched wider before inserting the insert 200 into the blind hole 1 12, thus making the insertion of the insert 200 into the blind hole 1 12 easier. To facilitate such stretching, the material of the tread block 1 10 comprising the blind hole 1 12 may have a Shore hardness of from 50 ShA to 80 ShA at a temperature of 23 °C.

According to an example, and as illustrated in Fig. 16b, such later stretching may be brought about by using at least three jaws 502, 504. Such jaws 502, 504 may be a part of a tool 500, which tool 500 may also comprise additional functionality, as described below.

After an insert 200 has been inserted into the blind hole 1 12, the jaws 502, 504 may be removed from the blind hole 1 12, thereby allowing the tread block 1 10 to envelop the insert 200 in accordance with what has been described above.

Regardless of whether any jaws 502, 503 are employed in conjunction with inserting an insert 200 into a blind hole, the insertion may be facilitated by applying a friction-reducing substance to the insert 200 and/or to the blind hole 1 12. Such friction-reducing substance may also facilitate the removal of a sleeve 550 from a blind hole as described below and as illustrated in Figs. 14 and 15a to 15b. Now referring to Figs. 10a and 10b, before inserting an insert 200 into a blind hole 1 12, in accordance with what has been described above, an insert 200 or at least a part of the insert 200 may be arranged into a sleeve 550. According to an example, the insert 200 or at least a part of the insert 200 may be arranged into the sleeve 550 by using suction. For this purpose, the sleeve 550 may comprise a conduit and/or an aperture through which suction pressure may conveyed from a source of suction pressure (not depicted) into the cavity 565 of the sleeve, which cavity 565 is to house the insert 200 or at least a part of the insert 200.

By arranging the insert 200 or at least a part of the insert 200 into a sleeve 550, the insert 200 may be protected during its insertion into the blind hole 1 12. For example, the use of a sleeve 550 may ensure the dimensional and shape integrity of the insert 200 during its insertion into the blind hole 1 12. Thus, the insert 200 may be inserted into the blind hole with the sleeve 550. After such insertion, and as sequentially illustrated in Figs. 14 and 15a to 15b, the sleeve 550 may be removed from the blind hole 1 12, with the insert 200 remaining in its installed position in the blind hole 1 12.

As illustrated in Figs. 10a and 10b, the sleeve 550 comprises a wall 555, which wall may be configured to laterally surround at least a part of the insert 200. Advantageously, the wall 555 is made of metal, ceramic, polymer or composite. Preferably, the thickness tsss of the wall 500 is at least 0.3 mm.

For example, and as illustrated in Figs. 10a and 10b, in case the insert 200 comprises a flange 207, the wall 555 of the sleeve 550 may surround that part of the insert 200 which does not constitute the flange 207. That is, the insert 200 minus the flange 207 may reside inside the sleeve 550 during the installation of the insert 200 into the blind hole 1 12. In such a case, advantageously the thickness tsss of the wall 555 of the sleeve 550 corresponds to the outward protrusion of the flange 207 so that the flange 207 may gain support from the sleeve 550 during the installation of the insert 200 into the blind hole 1 12. Furthermore, advantageously the cross-sectional shape of the sleeve 550 corresponds to the cross-sectional shape of the insert 200, also including the possible flange 207, as illustrated according to examples in Figs. 10c1 -2, 10d1 -2 and 10e1 -2. Now referring to Figs. 1 1 a to 1 1 b, such a sleeve 550 may comprise a cavity 565 configured to receive an insert 200 or a part of an insert 200. In addition, the sleeve 550 may comprise at least a first aperture 560 and possibly also a second aperture 570. The first aperture 560 has a first cross section A3.

Now referring to Figs. 12a to 12b, the first cross section A3 of the sleeve 550 may be configured to be less than the second cross section A2 of the insert 200, in which case a part of the insert 200, such as its flange 207, remains outside the cavity 565 of the sleeve 550, as illustrated in Fig. 12b. In such a case, preferably the geometrical shape of the cavity 565 is substantially congruent with the geometrical shape of the part of the insert 200 to be housed within the cavity 565.

Alternatively, and now referring to Figs. 13a to 13b, the first cross section A3 of the sleeve 550 may be configured to be at least equal to the second cross section A2 of the insert 200, in which case the whole insert 200 or substantially the whole insert 200 may be housed within the cavity 565 of the sleeve 550, as illustrated in Fig. 13b. In such a case, preferably the geometrical shape of the cavity 565 is substantially congruent with the geometrical shape the insert 200 to be housed within the cavity 565.

As a possibility, the sleeve 550 may be arranged to be an integral part of a punch 512, as illustrated in Figs. 12a to 12c and 13a to 13c. Such a punch 512 may be used to insert the insert 200 into the blind hole 1 12. As illustrated in Figs. 16a to 16e, such a punch 512 may be a part of a tool 500 configured to be employed to insert the insert 200 into the blind hole 1 12, which tool 500 may also comprise the above-described jaws 502, 504.

If the sleeve 550 is arranged to be an integral part of a punch 512, the sleeve 550 may comprise a cavity 565 configured to receive substantially a whole insert 200, as illustrated in Fig. 16e consistently with Figs. 13a and 13b, or a part of an insert 200, as illustrated in Fig. 16d consistently with Figs. 12a and 12b.

In case the sleeve 550 is an integral part of such a punch 512 that is used to insert the insert 200 into the blind hole 1 12, the sleeve 550 may be removed from the blind hole 1 12 after inserting the insert 200 to the blind hole 1 12 with the sleeve - in accordance with what is illustrated in Figs. 14 and 15a to 15b. In doing so, according to examples and in accordance with what is illustrated in Figs. 12c and 13c, the insert 200 may be expelled from the sleeve 550, or such expelling may be facilitated, by using a rod 514, which rod 514 may push the insert 200 out of the sleeve 550. Alternatively or in addition, pressurized gas can be used for the same expelling purpose. Thus, for the purposes of such use of a rod 514 and/or pressurized gas, the sleeve 550 may be furnished with a second aperture 570, as denoted in Figs. 1 1 a and 1 1 b.

As illustrated in Figs. 16a to 16d, a tool 500 configured to be used in inserting an insert 200 into a tire 100 may comprise the jaws 502, 504 and/or the punch 512 - also possibly including the sleeve 550 - and/or the expelling rod 514 and/or the pressurized gas-based expelling functionality.

As noted above, and now referring to Fig. 17, a tire 100, for example a prefabricated tire 100, may comprise a reinforcing belt 150 between the tread 120 and the inner surface 130 of the tire 100. In such a case it is preferable that the blind hole 1 12 machined to a tread block 1 10 of the tire does not penetrate and thereby damage the reinforcing belt 150. Consequently, preferably the method of machining the blind hole 1 12 comprises determining a distance diso between the tread 120 and the reinforcing belt 150 and machining such a blind hole 1 12 to a tread block 1 10 that a depth d 2 of the blind hole 1 12 is less than the distance diso between the tread 120 and the reinforcing belt 150. That is, preferably the blind hole 1 12 is machined in such a way that it will not extend from the tread 120 to the reinforcing belt 150, but extends to a lesser depth into the tread block 1 10.

As an additional possibility, if the tire 100 comprises further elements on top of the reinforcing belt 150, which elements preferably are not to be damaged with machining a blind hole 1 12 into them, the thickness of such elements may be taken into account in machining the blind hole 1 12 in accordance with what is described immediately above. That is, in such a case, preferably the method of machining the blind hole 1 12 comprises determining a distance diso between the tread 120 and the reinforcing belt 150 and machining such a blind hole 1 12 to a tread block 1 10 that a depth d 2 of the blind hole 1 12 is less than the distance diso between the tread 120 and the reinforcing belt 150 plus the thickness of other elements not to be penetrated into with the blind hole 1 12. Determining a distance diso between the tread 120 and the reinforcing belt 150 may, for example, be premised on the reinforcing belt 150 comprising ferromagnetic or paramagnetic material such as ferromagnetic or paramagnetic metal, such as steel. In such a case, the determining of the distance diso between the tread 120 and the reinforcing belt 150 may be accomplished by using an inductive position sensor 600. Such an inductive position sensor 600 may be configured to sense the distance to a ferromagnetic or paramagnetic target.