RU2575532C1 - Air tire - Google Patents

Abstract

FIELD: motor car construction.

SUBSTANCE: tire (1 comprises the groove with multiple ledges (500) made at its bottom (50 B2). Ledges (500) extend from one groove sidewall (50B1) to opposite sidewall (50B3). Said ledges (500) are arranged in said groove at preset spacing P complying with the condition 0.75≤P≤10L, where L is the ledge length along central axis of the groove extending along the groove width centre. Distance (DL) in direction over the tread width from the end of the breaker shortest ply to the groove central line (WL) makes at least 200 mm.

EFFECT: reduced tire overheating, hence longer life.

9 cl, 21 dwg, 1 tbl

Description

Technical field

The invention relates to a tire that prevents overheating when driving.

State of the art

Typically, pneumatic tires (hereinafter referred to as "tires") mounted on vehicles use various methods to prevent them from overheating while the vehicles are moving. In particular, heavily loaded tires mounted on trucks, buses and construction vehicles are subject to noticeable overheating.

A tire is known, provided with a plurality of ridges in the form of ribs on the sidewall of the tire (for example, JP 2009-160994, pages 4 and 5, FIG. 2). In such a tire, ribs in the form of ribs create a turbulent air flow passing over the sidewall surface when the tire rolls along the road, and turbulent flows help dissipate heat from the tire, preventing the sidewall from overheating.

Disclosure of invention

Known tire has features that need to be improved. In particular, the use of protrusions on a part of the sidewall has in itself a limitation with respect to effectively preventing overheating of the tread.

When overheating, the rubber element of the tread 5 wears out under the influence of heat. Due to the wear of the rubber element, the breaker layer located in the tread exfoliates from the rubber element, which leads to a decrease in tire life.

The invention is a tire (tire 1), which includes a tread (tread 5) with a groove (circumferential groove 50B) extending in the circumferential direction of the tire (circumferential direction of the tire tcd), with a plurality of protrusions at the bottom of the groove (groove bottom 50B2) (protrusions 500), each of which extends from one side wall (side wall 50B1) to the opposite other side wall (side wall 50B3) of the groove, the protrusions in the groove located at predetermined intervals P, which correspond to the projection onto the tread surface the condition 0.75L≤P≤10L, where L is the length of the protrusions along the center line of the groove (center line WL of the groove), which runs in the center of the width of the groove, a plurality of layers (belt layer 30), belt located in the tread in the tire circumferential direction, and the plurality of belt layers includes the shortest layer (second belt layer 32), the length of which in the tread width direction (tread width direction twd) is the smallest, and the distance from the end of the shortest belt layer to the center line of the groove in the width direction not (DL length) (end of the belt 30s) is not more than 200 mm.

Brief Description of the Drawings

In FIG. 1 shows a tread pattern of a tire 1 in accordance with an embodiment of the invention;

in FIG. 2 is a sectional view of a tire according to an embodiment of the invention in the radial direction trd of the tire and in the twd direction along the tread width;

in FIG. 3 is a tread block 100, an enlarged perspective view;

in FIG. 4 - annular strip 70A, a top view of the tread surface;

in FIG. 5 (a) -5 (c) is a fragment of the tread pattern in the region of the recess 300 of the tread surface, enlarged views;

in FIG. 6 is a partial section along the annular groove 50B, perspective view;

in FIG. 7 is an annular groove 50B, a top view of the surface of the tread 5;

in FIG. 8 is an annular groove 50B, a sectional view along arrow F5 in FIG. 7;

in FIG. 9 is a section along the line F6-F6 in FIG. 7;

in FIG. 10 (a) - annular groove 50B, view of the tread surface;

in FIG. 10 (b) is an annular groove 50B, a sectional view along arrow F5 in FIG. 7;

in FIG. 11 is a graph of the heat transfer of the annular groove from the angle 9f (in the form of a coefficient);

in FIG. 12 is a graph of the coefficient of heat transfer coefficient of the annular grooves on the factor for the length L of the protrusions;

in FIG. 13 is a graph of the coefficient of heat transfer coefficient of the annular grooves on the factor at a depth D of the groove;

in FIG. 14 is a graph of tire life coefficient versus distance DL in the twd direction along the tread width;

in FIG. 15 is an annular strip 70A with tread blocks in accordance with another embodiment of the invention, a top view of the tread surface;

in FIG. 16 is an annular strip 70A with tread blocks in accordance with another embodiment of the invention, a top view of the tread surface;

in FIG. 17 is a tread 5 in accordance with another embodiment of the invention, an enlarged perspective view;

in FIG. 18 is an annular strip 70A with tread blocks in accordance with another embodiment of the invention, a top view of the tread surface;

in FIG. 19 is a tread 5 in accordance with another another embodiment of the invention, an enlarged perspective view;

in FIG. 20 is an annular strip 70A with tread blocks in accordance with another another embodiment of the invention, a top view of the tread surface;

in FIG. 21 (a) to 21 (g) are exemplary of various cross-sectional shapes of protrusions 500.

Embodiments of the invention

The further description is divided into the following sections:

1 - a general diagram of the design of the tire 1;

2 is a general design diagram of air supply means;

3 is a general design diagram of a recess 300;

4 is a general design diagram of the protrusions 500;

5 - work and results;

6 - comparative assessment;

7 are other embodiments of the invention.

In the drawings, the same or similar reference numbers indicate the same or similar elements and sections. In addition, it should be noted that the drawings are schematic, and aspect ratios, etc. differ from the actual. Specific dimensions, etc. should be installed in accordance with the description below. In addition, the drawings also include sections that have mutual arrangements and aspect ratios that differ from each other.

1. General scheme of the design of the bus 1

A general construction diagram of a tire 1 according to the invention will be described with reference to FIG. 1 and 2. In FIG. 1 shows a tread pattern of a tire 1, and in FIG. 2 is a sectional view of a plane extending in the radial direction trd and in the twd direction along the tread width.

Tire 1 is assembled on a standard-type rim. Tire 1 has normal internal pressure and is subjected to normal load. The rim has a flange supporting the side parts 3 in the twd direction along the tread width.

For convenience of description, it is assumed that the tire 1 is mounted on the vehicle and rolls in the direction of rotation tr1 when the vehicle is moving forward. The rotation direction of the tire 1 mounted on the vehicle is not particularly limited.

The term “standard type rim” refers to a standard rim of the appropriate size specified in JATMA (The Japan Automobile Tire Manufacturers Association, Inc.). In countries other than Japan, the term “standard-type rim” refers to standard rims of the accepted sizes specified in the standards given.

The term "normal internal pressure" means the pneumatic pressure determined by the tire measurement method described in Year Book 2008 (p. 0-3, section 5), which was issued by the JATMA (The Japan Automobile Tire Manufacturers Association, Inc.). In countries other than Japan, the concept of "normal internal pressure" refers to pneumatic pressures during tire size measurements, which are specified in the relevant standards.

The term "normal load" means the load corresponding to the highest load capacity of a single wheel, indicated in the Year Book 2008, which was issued by the JATMA (The Japan Automobile Tire Manufacturers Association, Inc.). In countries other than Japan, the concept of "normal load" refers to the highest loads (highest load capacities) of single wheels of the appropriate sizes specified in the relevant standards.

Standards are defined by industry standards in the areas where tires are manufactured and used. For example, in the USA the standard is referred to as “Year Boor of The tire and Rim Association Inc.,” and the standard in Europe is referred to as “Standards Manual of The European Tire and Rim Technical Organization”.

As shown in FIG. 1 and 2, tire 1 includes side parts 3, tread 5, sidewall 7 and sidewall 9 of the tread.

The side portion 3 has a side core 10 and are in contact with the rim.

The tread 5 has a surface 5a that is in contact with the road surface. The tread 5 has an end face 5e, which is the outer end of the tread 5 in the twd direction along its width. The tread pattern 5 has a shape symmetrical with respect to a point on the center line CL of the tire.

The sidewall 7 forms the side surface of the tire 1 and is located between the side portion 3 and the sidewall 9 of the tread. Sidewall 7 connects the side 3 with the tread 5 through the sidewall 9 of the tread.

The tread side 9 extends inward in the radial direction trd of the tire from the tread end 5e, which is the outer end of the tread 5, in the twd direction along the tread width. The sidewall 9 of the tread runs continuously to the sidewall 7 of the tire. The sidewall of the tread 9 is located between the tread 5 and the sidewall 7 of the tire.

The internal position of the sidewall of the tread 9 in the radial direction trd of the tire corresponds to the most remote in the radial direction trd of the tire inner position of the exit zone of the tread end 5e to the lateral grooves (lug grooves 60). The sidewall 9 of the tread does not come into contact with the road surface during normal movement.

As shown in FIG. 2, tire 1 is a pneumatic tire. Tire 1 has a larger caliber of rubber compound (rubber thickness) in the tread 5 compared to pneumatic tires mounted on passenger cars, etc.

In particular, the outer diameter of the OD tire and the caliber of the DC tread rubber compound 5 at the location of the tire center line CL correspond to the condition DC / OD≥0.015.

The outer diameter OD (in mm) is the largest outer diameter of the tire 1 (in general, in the tread area 5 near the center line CL of the tire). The DC rubber gauge (in mm) is the thickness of the rubber of the tread 5 on the center line CL of the tire. The DC rubber gauge does not include the thickness of the layers of the breaker 30. As shown in FIG. 2, in the case where the annular groove 50C is formed in an area including the tire center line CL, the caliber of the rubber composition is the thickness of the tread rubber 5 in an area adjacent to the annular groove 50C.

As shown in FIG. 2, the tire 1 includes a pair of side cores 10, a carcass ply 20, and a plurality of belt layers 30.

The side core 10 is located in the side portion. The side core 10 is formed of a side wire (not shown).

The carcass ply 20 forms the carcass of the tire and connects the tread 5 to the bead portions 3 through the sidewalls 9 of the tread and the sidewalls 7 of the tire.

The frame layer 20 covers the space between the pair of side cores 10 and has a toroidal shape. In this embodiment, the carcass ply 20 contacts the side cores 10. Both ends of the carcass ply 20 in the tread width direction twd are supported by two side parts 3.

The carcass ply 20 comprises a cord extending in a predetermined direction in a projection of the tread surface. In this case, the carcass cord extends in the direction along the tread width twd. The frame cord is, for example, steel wire.

The belt layer 30 is located in the tread 5. The belt layer 30 is located outside the carcass layer 20 in the tire radial direction (trd). The belt layer 30 extends in the circumferential direction of the tire and comprises a belt cord extending obliquely with respect to the direction of passage of the carcass cord. For example, a cord used as a breaker cord is a steel cord.

The plurality of layers of belt 30 includes a first layer of belt 31, a second layer of belt 32, a third layer of belt 33, a fourth layer of belt 34. a fifth layer of belt 35 and a sixth layer of belt 36.

The first belt layer 31 is located outside the carcass layer 20 in the radial direction trd of the tire. The first layer 31 of the breaker is located in the outermost position of the plurality of layers of the breaker 30 in the radial direction trd of the tire. In the radial direction trd of the tire, the second belt layer 32 is located outside the first belt layer 31, the third belt layer 33 is located outside the second belt layer 32, the fourth belt layer 34 is located outside the third belt layer 33, the fifth belt layer 35 is located outside the fourth belt layer 34, and the sixth layer of the breaker 36 is located outside the fifth layer 35 of the breaker. The sixth layer 36 of the belt is located in the outermost position of the multiple layers of belt 30 in the radial trd direction of the tire. The first layer of the belt 31, the second layer of the belt 32, the third layer of the belt 33, the fourth layer of the belt 34. The fifth layer of the belt 35 and the sixth layer of the belt 36 are located from the inner side to the outer side in the radial direction trd of the tire.

In this embodiment, the width of the first belt layer 31 and the second belt layer 32 is 25-70%, inclusive, of the width TW of the tread surface 5a in the twd direction along its width. The width of the third belt layer 33 and the fourth belt layer 34 is 55-90%, inclusive, of the width TW of the tread surface 5a in the twd direction along the tread width. The width of the fifth belt layer 35 and the sixth belt layer 36 is 60-110%, inclusive, of the width TW of the tread surface 5a in the twd direction along the tread width.

In the twd direction, along the tread width, the width of the fifth belt layer 35 of the belt is greater than the width of the third layer of the belt 33, the width of the third layer 33 of the belt is equal to or greater than the width of the sixth layer 36 of the belt, the width of the sixth layer 36 of the belt is greater than the width of the fourth layer of 34 belt, the width of the fourth layer of 34 belt is greater the width of the first belt layer 31, and the width of the first belt layer 31 is greater than the width of the second belt layer 32. In the twd direction along the width of the tread, the fifth belt layer 35 has the largest width, and the second belt layer 32 has the smallest width of the many layers of the belt 30. Accordingly, the many layers of the belt 30 include the shortest belt layer having the shortest length in the twd direction in width tread (i.e., the second layer of the breaker 32).

The second breaker layer 32, being the shortest, has an end 30e in the twd direction along the tread width.

In this embodiment, each of the tilt angles of the breaker cords of the first breaker layer 31 and the second breaker layer 32 to the carcass cord in the projection onto the tread surface is 70-85 °, inclusive. Each of the angles of inclination of the cord of the belt of the third layer 33 of the belt and the fourth layer 34 of the belt to the cord of the frame is 50-75 °, inclusive. Each of the angles of inclination of the cord cords of the fifth layer 35 of the belt and the sixth layer 36 of the belt to the cord of the frame are 50-70 °, inclusive.

The plurality of belt layers 30 includes an inner group 30A of transversely directed layers of the belt, an intermediate group 30B of transversely directed layers of the belt, and an outer group 30C of transverse layers of the belt.

The inner group 30A of transversely oriented belt layers consists of a set of belt layers 30 and is located outside the carcass layer 20 in the radial direction trd of the tire. The inner group 30A of transversely directed belt layers includes a first belt layer 31 and a second belt layer 32. The intermediate group 30B of transverse layers of the belt consists of another set of layers of the belt 30 and is located outside the inner group 30A of the transverse layers of the belt in the radial direction trd of the tire. The intermediate group 30B of transverse layers of the belt includes a third belt layer 33 and a fourth belt layer 34. The outer group 30C of transverse layers of the belt consists of another set of layers of the belt 30 and is located outside the intermediate group 30B of transverse layers of the belt in the radial direction trd of the tire. The outer group 30C of transversely directed belt layers includes a fifth belt layer 35 and a sixth belt layer 36.

The width of the inner group 30A of the transversely directed belt layers is 25-70%, inclusive, of the width of the tread surface 5a in the twd direction along the tread width. The width of the intermediate group 30B of transverse layers of the belt is 55-90%, inclusive, of the width of the tread surface 5a in the twd direction along the tread width. The width of the outer group 30C of the transverse layers of the belt is 60-110%, inclusive, of the width of the tread surface 5a in the twd direction along the tread width.

The angle of inclination of the breaker cord of the inner group 30A of the transverse layers of the breaker to the carcass cord in the projection onto the tread surface is 70-85 °, inclusive. The angle of inclination of the cord of the breaker of the intermediate group of CSP transversely directed layers of the breaker to the cord of the carcass in the projection onto the tread surface is 50-75 °, inclusive. The angle of inclination of the breaker cord of the outer group 30C of the transverse layers of the breaker to the carcass cord in the projection onto the tread surface is 50-70 °, inclusive.

The angle of inclination of the breaker cord of the inner group 30A of the transverse layers of the breaker to the carcass cord in the projection onto the tread surface is the largest. The angle of the breaker cord of the intermediate group 30B of the transverse layers of the belt to the cord of the frame is equal to or greater than the angle of the cord of the breaker of the outer group 30C of the transverse layers of the belt.

As shown in FIG. 1 and 2, the tread 5 has a plurality of grooves (annular grooves 50) and a plurality of side grooves (lug grooves 60) extending in the tire circumferential direction tcd. The tread 5 also has a plurality of tread blocks (annular strips 70 with tread blocks) formed by a plurality of annular grooves 50 and a plurality of lug grooves 60.

A plurality of annular grooves 50 extend in the circumferential direction of the tire tcd. A plurality of annular grooves 50 includes annular grooves 50A, 50B, and 50C.

The annular groove 50A is located in the outermost position in the twd direction along the tread width. An annular groove 50C is located on the center line CL of the tire.

An annular groove 50B is located between the annular groove 50A and the annular groove 50C in the twd direction along the tread width. In particular, the annular groove 50B is formed so that the distance DL from the end of the layer 30e to the center line WL of the groove, which runs along the center of the width of the annular groove 50B, is less than or equal to 200 mm in the projection onto the tire tread surface in the twd direction.

As described below, the bottom 50B2 of the annular groove 50B has many protrusions 500. Thus, the temperature around the tread 5 in the annular groove 50B locally decreases. Since the distance DL from the belt end 30e to the center line WL of the groove in the twd direction along the tread width is equal to or less than 200 mm, the temperature of the belt end 30e is lowered. Such a decrease in temperature slows down the wear of the rubber element around the end of the belt 30e caused by the action of heat and thereby prevents the generation of heat and peeling of the second layer 32 of the belt from the end 30e of the belt as a starting point and the surrounding rubber element. Since peeling of the second layer 32 of the breaker, which is the shortest layer and is most susceptible to the heat of the tread 5, is prevented, the service life of the tire 1 can be increased.

The tread of heavily loaded tires mounted on trucks, buses and construction vehicles has a larger caliber of rubber compound (thickness) and a large volume of rubber. When such a heavily loaded tire undergoes repeated deformation, the tread temperature rises. In such a heavily loaded tire, in particular, the tread 5 located outside the tread 5 generates more heat than the tread 5 located next to the center line CL (in the twd direction along the tread width). Thus, due to the presence of a plurality of protrusions 500 at the bottom 50B2 of the annular groove 50B located outside the center line CL, heat can be intensively dissipated from the tread 5.

The lug grooves 60 extend from the annular groove 50B to the tread side 9. The lug grooves 60 have respective exits 60a to the tread side 9. Accordingly, the lug grooves 60 extend to the tread end 5e. The lug grooves 60 are in communication with the annular groove 50A and the annular groove 50B. The inner ends of the lug grooves 60 in the twd direction along the tread width are in communication with the annular grooves 50B.

The width between both ends (tread ends 5e) of the tread 5 in the tread width direction is designated TW. In this embodiment, both ends of the tread designate both ends in the twd direction along the width of the tread in the contact range where the tire is in contact with the road surface. The state when the tire is in contact with the road surface means the state when the tire is attached to a normal rim and has normal internal pressure and normal load.

In the projection onto the tread surface of the tire 1, the lug grooves 60 extend obliquely in the twd direction along the tread width. The inclination angle cf of the grooves 60 of the lugs in the twd direction along the tread width is 15-60 °, inclusive.

As shown in FIG. 1, when the tire 1 rotates in the rotational direction tr1, an air flow (incident flow) occurs in a direction opposite to the rotational direction tr1. The left in FIG. 1, the lug grooves 60 move forward in the rotational direction tr1, since they are located outside in the twd direction along the tread width. The inclination angle cf of the grooves 60 of the lugs in the twd direction along the tread width is 15-60 °, inclusive. In this regard, when the tire 1 rotates in the direction of rotation tr1, the air flow externally entering the lug grooves 60 may not collide with the side walls of the lug grooves 60 near the exits 60a and remain there. As a result, the thermal conductivity coefficient of the lug groove 60 is improved and the air flow is accurately guided into the annular groove 50B, thereby causing a decrease in the temperature of the tread 5.

On the other hand, when the tire 1 rotates in the rotation direction tr1 from the right in FIG. 1 of the tread side 5, the air flow (free flow) moves in a direction opposite to the direction of rotation tr1. Since the inclination angle cp of the grooves 60 of the lugs in the twd direction along the tread width is 15-60 °, inclusively, air in the lug grooves 60 can easily flow along them. As a result of the removal of air to the outside from the grooves 60 of the lugs in the twd direction along the tread width, the flow rate of air flowing in these grooves can increase. This can improve the thermal conductivity of the lug grooves 60 and lower tread temperature 5.

Air flowing in the annular groove 50B more easily enters the grooves 60 of the lugs. Air passing through the annular groove 50B removes heat fluxes out through the grooves 60 of the lugs, contributing to the dissipation of heat from the tread 5.

An angle of inclination φ of 60 ° or less can provide rigidity for the tread blocks 100 and 200 mentioned below. This can prevent the deformation of the blocks 100 and 200 due to the rotation of the tire 1 and, accordingly, prevent the increase of heat generation by the tread 5.

Several annular bands 70 with tread blocks extending in the tire circumferential direction include annular bands 70A, 70B, and 70C.

The annular strip 70A is located in the outermost position in the twd direction along the tread width. An annular strip 70B is located between the annular strip 70A and the annular strip 70C in the twd direction along the tread width. An annular strip 70C located in the innermost position in the twd direction along the tread width.

The annular strip 70A and the annular strip 70B have grooves 60 for lugs. Tread 5 has tread blocks 100 and 200 defined by lug grooves 60. In other words, the annular strip 70A is divided by lug grooves 60 to form tread blocks 100. The annular band 70B is divided by lug grooves 60 to form tread blocks 200.

In this embodiment, the tire 1 is a radial tire having, for example, a flat tire of 80% or less, a rim diameter of 57 "or more, a load capacity of 60 tons or more and a load factor (k-factor) of 1.7 or more It should be noted that bus 1 is not limited to these parameters.

2. General design of the air supply

The general construction diagram of the air supply means according to this embodiment of the invention will be described with reference to FIG. 1-4. In FIG. 3 shows an enlarged perspective view of the tread block 100. In FIG. 4 shows an annular strip 70A with tread blocks in projection onto the tread surface.

In the tire 1, the lateral grooves (grooves 60 of the lugs) are provided with appropriate air supply means. In this embodiment, the air supply means are constituted by a constricted surface 100R.

As shown in FIG. 1-4, the tread block 100 has a surface 100S that comes into contact with the road surface, a side surface 101 formed outside the tread block 100 in the tread direction twd, a side surface 102 formed inside the tread block 100 in the tread width twd the side surface 103 of the groove, which forms the wall of the groove of the lug 60, formed on one side of the tread block 100 in the circumferential direction tcd of the tire, and the side surface 104 of the groove, which forms the wall of the groove 60 of the grouser flail formed on the other side of the tread block 100, tcd in the circumferential direction of the tire. The tread block 100 has a tapered surface 100R that intersects the surface 100S, the side surface 101 and the side surface 103 of the grooves at the corner edge 100A formed by the tread surface, the side surface 101, and the side surface 103 of the groove. The angular edge 100A forms the above end 5e of the tread 5.

The side surface 101 is formed in the tread block 100 adjacent to the tread sidewall 9. The side surface 101 extends in the circumferential direction of the tire tcd. The side surface 101 is connected to the side surfaces 103 and 104 of the groove of the tread block 100, which form the walls of the side grooves 60. The side surface 102 faces the side surface 101 in the twd direction along the tread width. The side surface 102 forms a wall of an annular groove 50A adjacent to the inside of the tread block 100 in the twd direction along the tread width.

The side surface 103 of the groove extends in the twd direction along the tread width. The side surface 103 of the groove is located on one side of the tread block 100 in the circumferential direction of the tire tcd. The side surface 104 of the groove extends in the twd direction along the tread width. The side surface 104 of the groove is located on the other side of the tread block 100 in the circumferential direction of the tire tcd.

The tapered surface 100R extends in the tire circumferential direction tcd at an angular edge 100A formed by the tread surface 100S and the side surface 101. The tapered surface 100R is inclined inward in the radial tire direction trd in the cross section of the tread block 100 in the tire circumferential direction tcd and in the tire radial direction trd when it approaches one side in the circumferential direction of the tcd bus. The tapered surface 100R is also tilted inward in the radial direction trd of the tire, in the cross section of the tread block 100 in the twd direction in the tread width and in the radial direction trd of the tire as it approaches the outside in the twd direction in the tread width.

In other words, the tapered surface 100R is beveled at the apex of the tread surface 100S, the side surface 101 and the side surface 103 of the groove, i.e. the tapered surface 100R is formed so that it has at least one side on each of the tread surfaces 100S, the side surface 101, and the side surface 103 of the groove.

The tapered surface 100R has one side on the side surface 101 and has no side on the side surface 102, side surface 101 and side surface 102 of the tread block 100 in the twd direction along the tread width. In other words, in the tread block 100, one of the side surfaces 101 and 102 (side surface 102), which are opposite to each other in the twd direction along the tread width, does not intersect the narrowed surface 100R.

In addition, the tapered surface 100R has one side on the side surface 103 of the groove and does not have any side on the side surface 104 of the groove, side surface 103 of the groove and side surface 104 of the groove of the tread block 100 in the tire circumferential direction tcd. In other words, one of the side surfaces of the grooves 103 and 104 (side surface 104 of the groove), which are opposed to each other in the tread block 100 in the tire circumferential direction tcd, does not intersect the narrowed surface 100R.

The formation of a tapered surface 100R, as described above, facilitates the flow of air on this surface during the rotation of the tire 1 and collision with the side surface 104 of the grooves of another tread block 100 adjacent in the circumferential direction tcd of the tire. In other words, air flows over the narrowed surface 100R, easily enters the groove 60 of the lugs of the tread block 100 adjacent in the tire circumferential direction tcd.

In this embodiment, the tapered surface 100R is flat. In other words, the tapered surface 100R linearly extends along the tire cross section tcd in the tire circumferential direction and the tire radial direction trd or the cross section in the twd direction along the tire tread width and the tire radial direction trd.

As shown in FIG. 3, if the plane Sv passes through the vertex P2 of the tapering surface 100R, intersecting the tread surface 100S and the surface of the side 101, the top P1 of the tapering surface 100R, intersecting the tread surface 100S and the surface of the groove side 103, and the vertex P3 of the tapering surface 100R, intersecting the side surface 101 and the side surface 103 of the groove, it forms an angle θ2 with the tread surface 100S of 0 ° -45 °. Alternatively, the angle θ1 formed by the plane Sv and the side surface 101 is greater than 0 ° and less than 45 °. In other words, it is necessary that only one of the angles θ1 or θ2 is 0 ° -45 °. More preferably, the angle θ1 (or the angle θ2) is 10 ° -30 °. In this embodiment, the tapered surface 100R is flat, i.e. is the same plane as the plane Sv.

Preferably, the tapered surface 100R is formed such that the distance L2 between the peak P1 and the peak P3 in the tire radial direction (trd) is greater than the distance L1 between the peak P1 and the peak P2 in the tread width direction (twd). The reason for this is as follows. Since the distance L2 is greater than the distance L1, even in the case of wear of the pad block 100 of the tread surface 100S, the narrowed surface 100R remains. In other words, the action of the narrowed surface 100R may continue. More preferably, the distance L2 is at least 50 mm.

In the tire 1, the tread block 100 has a tapered surface 100R that intersects the tread surface 100S, the side surface 101 and the side surface 103 of the grooves at an angular edge 100A formed by the tread surface 100S and the side surface 101 located externally in the tread width direction twd.

Thus, as shown in FIG. 4, when the tire 1 rotates in the rotation direction tr1, the air flow (free flow) AR created by the rotation of the tire 1 flows along the narrowed surface 100R in the opposite direction to the rotation direction tr1. The air stream AR flowing over the narrowed surface 100R collides with the side surface 104 of the groove of the tread block 100, which is rearward in the direction of rotation tr1, and is directed into the groove 60 of the lug. As a result, an air stream AR is generated from the side surface 101 of the tread block 100 to the lug groove 60. In other words, air around the tire 1 enters the lug groove 60 to increase the flow rate of air flowing in the lug groove 60. This can improve the thermal conductivity of the lug grooves 60 and reduce the temperature of the tread 5.

When the tire 1 rotates in the rotation direction tr2, the air flow (free flow) AR created in the lug groove 60 due to the rotation of the tire 1 flows outward along the narrowed surface 100R in the opposite direction to the rotation direction tr2. This contributes to the outward air flow in the twd direction along the tread width through the lug groove 60, increasing the flow rate of air flowing in the lug groove 60. Accordingly, the thermal conductivity coefficient of the lug groove 60 is increased, and the temperature of the tread 5 can be reduced.

3. General design of the recess 300

The general design of the recess 300 according to this embodiment of the invention will be described with reference to FIG. 5. In FIG. 5 (a) -5 (c) show a recess 300 on an enlarged scale in various views in projection onto the tread surface.

As shown in FIG. 5 (a) -5 (c), the annular strip 70C has recesses 300. A recess 300 is located in the direction of the lug groove 60. A recess 300 is formed in the wall surface of the groove of the annular strip 70C opposite the lug groove 60.

In this embodiment, the recess 300 is triangular in projection onto the tread surface. In projection onto the tread surface, one wall surface 300a of the recess 300 extends along a line of one wall surface of the lug groove 60, and another surface 300b of the wall of the recess 300 intersects a line extending to the other surface of the lug groove 60. In the projection onto the tread surface, the intersection of the groove wall surface of the annular strip 70C opposite the lug groove 60 with a line extending one surface of the lug groove wall is indicated by the intersection “a”, and the intersection of the groove wall surface of the annular strip 70C opposite the groove 60 of the lug groove with the line extending the other surface the wall of the lug groove 60 is indicated by the intersection “b”. In projection onto the tread surface, end A of wall surface 300a adjacent to annular groove 50B and intersection “a” are located at the same location, and end B of wall surface 300b adjacent to annular groove 50B and intersection “b” are located in different places. End B is not between intersection “a” and intersection “b”. Accordingly, the distance from the end A to the end B is greater than the distance from the intersection "a" to the intersection "b". In the projection onto the tread surface, the contact point between the wall surface 300a and the wall surface 300b is the vertex C.

In the projection onto the tread surface, the angle formed by the line extending the wall surface of the groove of the annular strip 70C opposite the lug groove 60 and the wall surface 300a is the angle α, and the angle formed by the line extending the wall surface of the groove of the annular strip 70C opposite the lug groove 60, and the wall surface 300b is an angle β. In this embodiment, the angle β is less than the angle α. Preferably, the angle α is within 20 ° ≤α≤70 °, and the angle β≤45 °.

The recess 300 is formed so that its center in the direction of extension of the annular groove 50B is offset from the direction of extension of the groove 60 of the lug, and the center line of the transverse groove passes through the center in a direction perpendicular to the direction of extension. The center of the recess 300 refers at least to the center of the line connecting the end A to the end B, or to the top C.

As shown in FIG. 5 (b), the size 300W of the recess 300 in the twd direction along the tread width changes in the tire circumferential direction tcd. In other words, the size 300W in the tire circumferential direction tcd gradually increases from end B to top C and gradually decreases from top C to end A.

The size 300L of the recess 300 in the circumferential direction tcd of the tire gradually decreases from the side extending into the annular groove 50B in the opposite direction. In other words, size 300L has the largest distance between end A and end B and gradually decreases to the top C.

As shown in FIG. 5 (c), due to the formation of a recess 300, the airflow AR flowing through the lug groove 60 from the outside to the inside in the twd direction along the tread width collides with the surface 300b of the recess 300. As shown in FIG. 5 (c), since the wall surface 300a is located above the wall surface 300b, it is less likely that the air flow AR will flow over the wall surface 300b. Thus, the airflow AR flows precisely along the guide of the annular groove 50B.

Since the recess 300 is formed to create a one-way airflow AR in the tire circumferential direction tcd, the airflow AR is not delayed in the annular groove 50B. This can improve the thermal conductivity of the annular groove 50B and reduces the temperature of the tread 5.

4. General design of the protrusions 500

The general design of the protrusions 500 according to this embodiment of the invention will be described with reference to FIG. 6-9.

In FIG. 6 is a perspective view of a local section along the circumferential groove 50B. In FIG. 7 shows an annular groove 50B in projection onto the tread surface (top view of the tread 5). In FIG. 8 shows an annular sectional groove 50B, a view along arrow F5 in FIG. 7. In FIG. 9 shows a section along line F6-F6 in FIG. 7 (ledge 500).

As shown in FIG. 6-9, at the bottom 50B2 of the annular groove 50B there are many protrusions 500.

In this embodiment, the protrusions 500 are located in the annular groove 50B at predetermined intervals P. In addition, the protrusions 500 extend from one side wall 50B1 of the groove to its other side wall 50B3. In this embodiment, the protrusions 500 continuously extend from one side wall 50B1 to the other side wall 50B3. In other words, all the protrusions 500 extend laterally along the width W of the annular groove 50B. In this embodiment, the side walls 50B1 and 50B3 extend substantially parallel to the tire circumferential direction and are located opposite each other.

All protrusions 500 are arranged vertically outward in the radial direction of the tire from the bottom 50B2 of the annular groove 50B. In this embodiment, the protrusions 500 are flat plate rubber elements extending vertically from the bottom 50B2 of the groove and inclined in the tire circumferential direction.

In particular, as shown in FIG. 7, the angle θf, which forms the center line WL of the groove with the protrusion 500, is 10-60 °, inclusive. The angle θf is formed by the longitudinal direction "x" of the protrusions 500 and the center line WL of the groove passing through its center, in the width direction in the projection onto the tread surface of the tire 1, and is opposite the direction of rotation of the tire 1. In other words, the angle θf is formed on the front side air flow AR generated by rotation of the tire 1 in the direction of rotation tr1.

The length L of the protrusions 500 along the center line WL of the groove and the predetermined intervals P between the protrusions in the projection onto the tread surface of the tire 1 correspond to the condition 0.75L Р P 10 10L.

Since all protrusions 500 meet the condition 0.75L≤P, the number of protrusions 500 in the annular groove 50B will not be too large, which prevents the deceleration of air flow in the annular groove 50B. Since all protrusions 500 meet the condition P≤10L, the number of protrusions 500 in the annular groove 50B will not be too small, and the air flow AR1 is effectively converted into a spiral flow (swirl flow).

Preferably, the intervals P between the protrusions are greater than 1.25L. More preferably, P> 1.5L, more preferably P> 2.0L. By meeting these conditions, the number of protrusions 500 in the annular groove 50B becomes appropriate. The bottom area 50B2 of the groove through which the airflow AR passes is not too small, effectively dissipating heat from the bottom 50B2 of the groove.

The length L of the protrusion is the distance from one end to the other in the direction ged of the extension of the annular groove 50B (in this embodiment, the tire circumferential direction). The interval P is the distance between the centers of the protrusions 500, in which the protrusions 500 intersect the center line WL of the groove.

If the distance between the side walls 50B1 and 50BZ of the annular groove 50B equal to the width of the groove is designated W and the width of the protrusion 500 in the lateral direction is designated TWf, then the length L can also be expressed as W / tgθf + TWf / sinθf. As shown in FIG. 9, the width of the protrusion TWf is the width in the direction perpendicular to the x direction along the protrusion.

Furthermore, as shown in FIG. 8, provided that the height of the protrusion 500 from the bottom of the groove 50B2 is Hf, and the depth of the annular groove 50B from the tread surface 5 and the bottom of the groove 50B2 (the deepest portion) is D, the protrusion 500 corresponds to the condition 0.03D≤Hf≤0, 4D. Provided that the width of the annular groove 50B is W, the bottom 50B2 of the groove is flat, at least its width is 0.2W. In other words, the center portion along the width W of the groove bottom 50B2 including the center groove line WL has a flat and smooth groove bottom 50B2 without any irregularities.

The width W of the annular groove 50B and the width TWf of the protrusion 500 in the perpendicular direction to its longitudinal direction "x" correspond to the condition: TWf / cosθf≤0.9W. Preferably, the protrusions 500 meet the condition 0.2 T TWf. Compliance with the condition 0.2≤TWf determines the width TWf of the protrusions, increasing their service life. As a result, damage to the protrusions 500 during use of the tire 1 can be prevented, which effectively prevents overheating of the tread 5 when the vehicle is in motion.

For example, the dimension L is 10-100 mm, the interval P is 1.25 mm - 4.00 mm, the height Hf of the protrusion is 5-15 mm, the width TWf of the protrusion is 0.5-10 mm, the depth D of the groove is 40-120 mm, the width W of the bottom of the 50B2 groove is 5-20 mm.

5. Work and results

In the tire 1, at the bottom 50B2 of the annular groove 50B, there are many protrusions 500 that extend from one side wall 50B1 of the groove to its other side wall 50B3. The protrusions 500 are located in the annular groove 50B at predetermined intervals P, which correspond to the condition 0.75L≤P10L, and the distance in the twd direction along the tread width from the end 30e of the second belt belt 32, which is the shortest layer in the tread width direction (twd) up to the center line WL of the groove does not exceed 200 mm.

When the tire 1 rotates in the annular groove 50B in a direction opposite to the direction of rotation tr1, air flows AR1 and AR2 (incident flows) are created. As shown in FIG. 10 (a) and 10 (b), the air flow AR1 along the side wall 50B3 located on one end side of the protrusion 500, which is the lower side in the direction of the air flow, is kept from flowing along the annular groove 50B, since the protrusion is located on the air flow path 500, but continues to move, deviating in the ged direction of the annular groove 50B, overcoming the protrusions 500. As a result, the air flow becomes spiral (swirling). As the airflow continues to move, ambient air is captured, increasing the airflow in AR1. This facilitates heat dissipation from the tread 5.

The air flow AR2 along the side wall 50B1 located on the other end side of the protruding part 500, which is the upper side in the direction of air flow, continues to move in the longitudinal direction "x" of the protrusions 500. Then, the air flow AR2 flows from the annular groove 50B around the other side wall 50B3 ring groove 50B. Air that retains heat passing through the annular groove 50B flows outward, thereby contributing to the dissipation of heat from the tread 5.

Since all protrusions 500 meet the condition 0.75L≤P, the number of protrusions 500 in the annular groove 50B is not too large, which prevents the deceleration of air flow through the annular groove 50B. Since all the protrusions 500 meet the condition P≤10 L, their number in the annular groove 50B is not too small, and the air flow AR1 becomes spiral (swirl). This facilitates heat dissipation from the tread 5.

The temperature around the tread 5 with the annular groove 50 decreases. Since the distance DL in the tread width direction (twd) from the belt end 30e to the center line WL of the groove does not exceed 200 mm, the temperature of the belt end 30e is reduced. Since fracture due to heating of the rubber element around the end of the belt 30e is prevented, delamination of the second layer of the belt 32 from the end of the belt 30e is prevented. In addition, peeling of the second layer of the belt 32, which is the shortest layer of the belt, easily exposed to heat from the tread 5, can be prevented. Thus, the temperature of the tread 5 due to vehicle movement is easily prevented, therefore, the tire service life can be increased. .

Preferably, the condition 1.25L <P is fulfilled. By satisfying this condition, the number of protrusions 500 in the annular groove 50B becomes more suitable. The bottom area 50B2 of the groove through which the air stream AR passes is not too small, which allows heat to be effectively dissipated from the bottom 50B2 of the groove.

Preferably, the angle θf formed by the longitudinal direction "x" of the protrusion 500 and the center line WL of the groove is 10-60 °, inclusive. Since the angle θf is equal to or greater than 10 °, the acute-angled portion formed by the protrusion 500 and the side wall 50B1 (or the side wall 50B3) can prevent the weakening of the airflow AR flowing through the annular groove 50B. Since the angle θf is equal to or less than 60 °, the air flow AR2 flowing through the annular groove 50B can be effectively converted into a spiral. This increases the flow rate passing along the bottom 50V2, providing effective heat dissipation from the tread 5.

Preferably, the condition 0.03D <Hf≤0.4D is satisfied. Under the condition 0.03D <Hf, the height Hf of the protrusions 500 is equal to or greater than a predetermined height, so that the protrusions 500 can efficiently convert the AR2 flowing through the annular groove 50B into a spiral flow. This increases the flow passing along the bottom of the groove 50B2 and provides sufficient heat dissipation from the tread 5. Compliance with the condition Hf≤0,4D, in all likelihood, causes the spiral-shaped air flow AR1 to reach the bottom 50B2 of the groove. As a result, heat is effectively removed from the bottom of the 50B2 groove.

The bottom 50B2 of the groove is flat on at least a width of 0.2W. Thus, the air flow AR passing through the bottom 50B2 of the groove does not encounter obstacles, which allows more efficient to prevent the overheating of the tread 5.

Preferably, the condition DC / OD≥0.015 is fulfilled. In a tire that meets this condition, the tread 5 has a larger caliber of the rubber composition and therefore retains heat. Thus, in a tire that meets this condition, when the vehicle is moving, overheating of the tread 5 is effectively prevented, which prevents its destruction due to overheating.

The protrusions 500 extend from one side wall 50B1 to the other side wall 50B3. Accordingly, the air flow AR1 passing along the protrusions 500 can overcome them near the side 50B3 and, thus, spiral (swirl) is effectively transformed. This allows for efficient heat dissipation from the tread 5.

The width of the inner group 30A of the transversely directed belt layers is 25-70%, inclusive, of the width of the tread surface 5a in the twd direction along the tread width. The width of the intermediate group 30B of transverse layers of the belt is 55-90%, inclusive, of the width TW of the tread surface 5a in the twd direction along the tread width. The width of the outer group 30C of the transverse layers of the belt is 60-110%, inclusive, of the width TW of the tread surface 5a. In addition, in the projection onto the tread surface, the angle of inclination of the breaker cord of the inner group 30A of the transverse layers of the breaker to the carcass cord is 70-85 °, inclusive, the angle of inclination of the breaker cord of the intermediate group 30A of the transverse layers of the breaker to the carcass cord is 50-75 °, inclusive, and the inclination angle of the breaker cord of the outer group 30C of transversely directed layers of the breaker to the carcass cord is 50-70 °, inclusive.

In the tire of the above construction, delamination of the layer of belt 30 and the rubber element may occur, since the number of layers of belt 30 is large. Thus, the service life of the tire can be increased through the use of the present invention with respect to a tire with a specified breaker design.

6. Comparative evaluation

To confirm the results achieved by the invention, the following tire tests were performed. However, the invention is not limited to the working sample used.

As a test tire, a tire (59 / 80R63) was used for mining. Lugs were made in the annular groove of the tire, and the thermal conductivity was measured at a tire rotation speed of 20 km / h. In this case, the angle θf formed by the center line of the groove and protrusions, the factor at L (the size of the protrusion in the direction of the groove), and the factor at D (depth of the groove) were varied. The coefficient of thermal conductivity in the absence of protrusions was determined equal to 100, and it was compared with the measured coefficient of thermal conductivity. The results are shown in FIG. 11-13. the relationship between the angle θf and the thermal conductivity of the annular groove is shown; in FIG. 12 shows the relationship between the factor at L and the thermal conductivity of the annular groove; in FIG. 13 shows the relationship between the factor at D and the thermal conductivity of the annular groove.

From the graph in FIG. 11 it follows that the angle θf equal to 10-60 °, inclusive, provides an acceptable coefficient of thermal conductivity. In particular, an angle θf of 15-40 °, inclusive, provides a more acceptable coefficient of thermal conductivity.

From the graph in FIG. 12 it follows that the factor at L equal to 0.75-10, inclusive, provides an acceptable coefficient of thermal conductivity. A factor of 1.25 or more provides more acceptable thermal conductivity. A factor of 1.5-7, inclusive, provides even more acceptable thermal conductivity.

From the graph in FIG. 13 it follows that the factor at D equal to 0.03-0.4, inclusive, provides an acceptable coefficient of thermal conductivity.

Further, to confirm the effect of the relative location of the annular groove and the end of the breaker, the following measurement was performed using a tire similar to the above.

A load of 101.6 kN was applied to the tires for samples 1-11 and comparative samples 1-12, then they were moved at a speed of 8 km / h, after which the service life of each tire was estimated.

In the tires for samples 1-11 and comparative sample 12, the tread thickness in the radial direction trd of the tire was 140 mm, the depth of the annular groove in the radial direction trd of the tire was 70 mm, and the width of the annular groove in the direction along the width of the tread was 10 mm. At the bottom of the annular groove, projections were made. The protrusion angle θf was 20 °, the spacing P between the protrusions was 2.5 mm, and the protrusion height Hf was 0.1 mm.

In the tire of specimen 1, the distance DL in the tread width direction (twd) from the end of the breaker to the center line WL of the groove of the annular groove was 0 mm. In other words, in the tread width direction (twd), the end of the breaker and the center line WL of the groove were in the same position. In the tire for sample 2, the distance DL was 20 mm. In the tire for sample 3, the DL distance was 40 mm. In the tire for specimen 4, the DL distance was 60 mm. In the tire for sample 5, the distance DL was 80 mm. In the tire for specimen 6, the distance DL was 100 mm. In the tire for specimen 7, the distance DL was 120 mm. In the tire for specimen 8, the DL distance was 140 mm. In the tire for specimen 9, the DL distance was 160 mm. In the tire for specimen 10, the DL distance was 180 mm. In the tire for specimen 11, the distance DL was 200 mm. In the tire for comparative sample 12, the distance DL was 220 mm.

In tires for comparative samples (with the exception of comparative sample 12), the tread thickness in the radial direction trd of the tire was 140 mm, the depth of the annular groove in the radial direction trd of the tire was 100 mm, and the width of the annular groove in the direction along the width of the tread was 10 mm. The bottom of the annular groove had no protrusions.

In the tire for comparative sample 1, the distance DL was 0 mm. In the tire for comparative sample 2, the distance DL was 20 mm. In the tire for comparative sample 3, the distance DL was 40 mm. In the tire for comparative sample 4, the distance DL was 60 mm. In the tire for comparative sample 5, the distance DL was 80 mm. In the tire for comparative sample 6, the distance DL was 100 mm. In the tire for comparative sample 7, the distance DL was 120 mm. In the tire for comparative sample 8, the distance DL was 140 mm. In the tire for comparative sample 9, the distance DL was 160 mm. In the tire for comparative sample 10, the distance DL was 180 mm. In the tire for comparative sample 11, the distance DL was 200 mm.

The results are presented in Table 1 and in FIG. 14. In FIG. 14 is a graph of the relationship between the service life of each tire and the DL distance. In FIG. 14 “O” stands for samples, and “×” stands for comparative samples. As the tire service life, the service life of comparative sample 1 was used, equal to the reference value (100), and other tires were indicated by coefficients.

In tires for samples 1-11, the depth of the annular groove is small compared to tires for comparative samples, however, the service life of tires for samples was not less than 100, as shown in Table 1 and in FIG. 14. Accordingly, in tires for samples 1-11, the tire service life has been increased.

It was found that in the case where the DL distance was at least 80 mm, the tire service life was increased to a greater extent, and in the case where the DL distance was at least 40 mm, the tire service life was further increased.

7. Other embodiments of the invention

Although the invention has been described in specific embodiments, it is understood that the description and figures do not limit it. The invention includes various options for its implementation, which are not described.

The following embodiments of the invention can be combined as necessary with the above option without compromising the effects of the invention.

7.1 Air supply

Although the air supply means in the above embodiment is constituted by a narrowed surface 100R, it is not limited to only a narrowed surface.

For example, as shown in FIG. 15 and 16, the length of the tread block 100 in the twd direction along the tread width may decrease from one side to the other side in the tire circumferential direction tcd.

In FIG. 15 shows an annular strip 70A according to another embodiment of the invention, a view in projection onto the tread surface.

One end 100D of the tread block 100 in the tire circumferential direction tcd is located on the rear side in the rotation direction tr1 when the vehicle to which the tire 1 belongs. Another end 100E of the tread block 100 in the tire circumferential direction tcd is located on the front side in the rotation direction tr1. The length La1 of the end face 100D in the tread width direction is less than the length La2 of the end face 100E of the tread block 100 in the tread width direction. The difference between the length Lb1 and the length La1 is expressed as the length Lw1, which is preferably 5 mm or more.

The side surface 101 extends obliquely to the inside of the tread block 100 from the plane in the tire circumferential direction and extends continuously to the side surface 103 of the groove of the tread block 100, which forms the inner wall of the groove 60 of the lug. The end face 100D of the tread block 100 in the tire circumferential direction tcd, which is located on the rear side in the rotation direction, is located inside from the sidewall 7 along the length Lw1 in the twd direction along the tread width. In other words, the rear side of the tread sidewall 9 in the rotational direction tcd of the tire of the tread block 100 is located inside of the sidewall 7 along the length Lw in the twd direction along the tread width. For this reason, a step is formed between the tread sidewall 9 and the side surface 101. The bottom 60b of the lug groove 60 extends from the end 100D in the tire circumferential direction tcd, which is located on the rear side in the rotation direction, to the end face 100E. The bottom 60b of the groove is located between the sidewall 9 of the tread and the side surface 101.

As shown in FIG. 15, when the tire 1 rotates in the rotation direction tr1, the air flow AR (free flow) generated by the rotation of the tire 1 flows along the side surface 101 of the tread block 100 in the opposite direction to the rotation direction tr1. Flowing along the side surface 101, the airflow AR collides with the side surface 104 of the groove of the tread block 100, which is rearward in the direction of rotation tr1, and is directed into the groove 60 of the lug. As a result, air around the tire 1 enters the lug groove 60 and increases the flow rate of air flowing in the lug groove 60. This can improve the thermal conductivity of the lug groove 60 and reduce the temperature of the tread 5.

In FIG. 16 shows an annular strip 70A according to another embodiment of the invention, a view in projection onto the tread surface. A curved rounded surface 100Ru is formed between the upper surface 100S of the tread 5, which comes into contact with the road surface, the side surface 101 and the side surface 103 of the grooves in the tread block 100 of the tire 1. In other words, the tread surface 100S, the side surface 101 and the side surface 103 of the groove beveled. As shown in FIG. 15, the surface area 100S of the tread 5 in contact with the road surface in the tread block 100 of the tire 1 is smaller than the area of the tread block 100 along the bottom 60b of the lug groove 60. The tread block 100 gradually increases from the tread surface 100S coming into contact with the road surface to the connecting portion for connecting to the bottom 60b of the groove.

As shown in FIG. 17 and 18, the side surface 101 of the tread block 100 may have a recess 130 that is cut in the tread block 100 from the side surface 101 and communicates with at least one side of the lug groove 60.

In FIG. 17 shows an enlarged scale of the tread 5, and FIG. 18 shows an annular strip 70A according to another embodiment of the invention in projection onto the tread surface.

A recess 130 is formed in a tread sidewall 9, which is a side surface of the tread block 100. A recess 130 is formed outside the line connecting the bottom 60b of the grooves 60 of the lugs in front and behind the tread block 100 in the tire circumferential direction tcd to each other.

A recess 130 is formed at one end of a side surface 101 of the tread block 100 in the tire circumferential direction tcd. The recess 130 extends inwardly from the side of the side surface 101 of the tread block 100 (in the twd direction along the tread width) and communicates with the lug groove 60. The side surface 101 of the tread block 100 and the side surface 103 of the grooves have an opening 131.

The length Lk of the recess 130 in the tire circumferential direction is less than the length WB of the tread block 100 in the tire circumferential direction tcd.

The depth ds of the recess 130 from the side surface 101 of the tread block 100 in the twd direction along the tread width is constant in the tire circumferential direction tcd. The opening 131 of the recess 130, which is formed in the side surface 101 of the tread block 100, is rectangular in the twd direction along the tread width. The recess 130 is formed parallel to the surface of the tread 5.

As shown in FIG. 18, when the tire 1 rotates in the rotational direction tr1, an air stream AR (free flow) is created which enters the recess 130 and flows along it in the opposite direction to the rotational direction tr1. The airflow AR flowing through the recess 130 hits the lateral surface 104 of the groove of the tread block 100, which is rearward in the direction of rotation tr1, and is guided into the grooves 60 of the lugs. As a result, air around the tire 1 enters the grooves 60 of the lugs and increases the air flow rate in the grooves 60 of the lugs. This can improve the thermal conductivity of the lug grooves 60 and reduce the temperature of the tread 5.

The depth ds of the recess 130 may increase as it approaches the groove 60 of the lug with which it communicates.

As shown in FIG. 19 and 20, the side surface 101 of the tread block 100 may have a protrusion 150 in the twd direction along the tread width.

In FIG. 19 shows an enlarged scale of the tread 5 according to another embodiment of the invention, and FIG. 20 shows an annular strip 70A according to this embodiment of the invention.

A protrusion 150 is formed adjacent to a lug groove 60 located on one side of a side surface 101 of the tread block 100 in the tire circumferential direction tcd. The other side of the side surface 101 of the block of the platform 100 in the circumferential direction tcd of the tire is essentially smooth. The expression “substantially smooth” means slight irregularities due to variations in the manufacturing process. Minor irregularities, for example, are irregularities within 10% of the length of the tread block 100 in the twd direction along the tread width.

The size Lr of the protrusion 150 in the tire circumferential direction tcd is smaller than the size WB of the tread block 100 formed in the annular band 70A in the tire circumferential direction tcd.

The protrusion 150 is rectangular, linearly extending in the radial direction trd of the tire, although the longitudinal direction of the rectangle may be inclined to the radial direction of the tire. In this case, an angle is formed between the center line of the protrusion 150, which runs in the center of the protrusion in the tire circumferential direction tcd, and the tire radial direction trd, which can be | γ | ≤60 °. The protrusion 150 shown in FIG. 19 and 20, is arranged so that the radial direction trd of the tire corresponds to the longitudinal direction of the rectangle, and the direction twd of the tread width corresponds to the lateral direction of the rectangle.

A plurality of protrusions 150 may be formed on the side surface 101 of the block of the platform 100. The plurality of protrusions 150 may be linearly located in the radial direction of the trd bus.

The plurality of protrusions 150 may be inclined to the tire radial direction trd in the twd direction along the tread width.

The protrusions 150 need not be rectangular. The cross section of the protrusion 150, which is perpendicular to the longitudinal direction, may be triangular. The cross section of the protrusion 150, which is perpendicular to the longitudinal direction, can be in the form of a trapezium, the larger base of which is connected to the side surface 101 of the tread block 100. The cross section of the protrusion 150, which is perpendicular to the longitudinal direction, can be in the form of a trapezium, the smaller base of which is connected to the side surface 101 tread block 100. A cross section of the protrusion 150, which is perpendicular to the longitudinal direction, can be tilted in the direction of rotation. The protrusion 150 may be a parallelogram in the direction of the axis of rotation of the tire. The protrusion 150 can be formed so that the width of its Central part in the longitudinal direction is less than the width of the tire at the end in the longitudinal direction along the axis of rotation of the tire. The protrusion 150 may be elliptical in the direction along the axis of rotation of the tire. The protrusions may also have other forms capable of disrupting the air flow passing over the tire surface.

In the above embodiment, both tread blocks 100 in the twd direction along the tread width have appropriate air supply means, but the invention is not limited to this. In the twd direction along the tread width, only one tread block 100 may have air supply means. Various tread blocks 100 may have air supply means of various shapes.

7.2 Projections

In the above embodiment, the protruding portion 500 has a flat plate shape, however, the invention is not limited to this. The protruding portion 500 may have a wavy shape in the projection of the tread surface or may have a shape with a larger thickness near the center line WL of the groove and with decreasing thickness in the direction of the side wall 50B1 and the side wall 50B3 (or vice versa).

In FIG. 21 (a) to 21 (g), embodiments of sectional views of protrusions 500 are shown. As shown in FIG. 21 (a) to 21 (g), in cross section, the shape of the protrusions 500 (shown as in FIG. 9) may not necessarily have a flat upper surface. In cross section, the shape of the upper surface of the protrusion 500 may be inclined or arched.

The angle θf, the groove depth D and the groove width W may not correspond to the conditions set in the above embodiment.

The protrusions 500 are located only in the annular groove 50B, however, they can be performed in other places. The protrusions 500 may be formed in an annular groove 50C formed in an area including a tire center line CL, or may be formed in an annular groove 50C.

7.3 Miscellaneous

Although the annular groove 50B extends parallel to the tire circumferential direction tcd in the above embodiment, the invention is not limited to this. The annular groove 50B need not be parallel to the tire circumferential direction tcd. For example, the annular groove 50B may not be parallel to the tire circumferential direction tcd, provided that the angle that the annular groove 50B forms with the center line CL of the tire is not more than 45 °. The annular groove 50B need not be linear and may be curved externally in the twd direction along the tread width or may have a zigzag profile. Preferably, the annular groove 50B has a zigzag profile so as not to reduce the speed of the air flowing through it.

The lug grooves may extend to the annular groove 50C, and the bottom of each of the annular grooves 50 may have protrusions 500. In other words, annular grooves provided with protrusions 500 may be formed in an area including a tire center line CL. This can reduce the temperature of the tread 5.

All lug grooves 60 are located at the same angle to the circumferential direction of the tire tcd, but can also be located at different angles. In one tire, the tilt angles φ of the lug grooves 60 need not be the same. The pitch angle φ of the lug groove 60 may vary between the lug groove 60 located adjacent to one end in the twd direction along the tread width and the lug groove 60 located adjacent to the other end in the twd direction along the tread width. In addition, the tilt angles φ may vary between the lug grooves 60 located adjacent to one end in the twd direction along the tread width.

Tires 1 according to this embodiment of the invention are very suitable for use as oversized, but can also be used for conventional tires.

A tire in accordance with the invention may be pneumatic or continuous, filled with rubber. Alternatively, the tire may be filled with gas, excluding air, for example, an inert gas such as argon, nitrogen, etc.

Industrial applicability

A tire in accordance with the invention can effectively prevent overheating of the tread due to vehicle movement and can extend the life of the tire.

Claims (9)

1. The tire containing
a tread with a groove extending in the tire circumferential direction,
a plurality of protrusions located at the bottom of the groove, each of which extends from one side wall to the opposite other side wall of the groove, and the protrusions in the groove are arranged at predetermined intervals P, which in the projection onto the tread surface correspond to the condition 0.75L≤P≤10L, where L - the length of the protrusions along the center line of the groove, which runs in the center of the width of the groove,
a pair of onboard cores
a frame layer of a toroidal shape passing between a pair of side cores;
a plurality of belt layers arranged in a tread in a circumferential direction of the tire, wherein the plurality of belt layers includes a shortest layer whose length in the tread width direction is the smallest and a distance in the tread width direction from the end of the shortest belt layer to the center line of the groove is not more than 200 mm,
moreover, the plurality of belt layers in the tire radial direction comprises an internal group of transverse layers of the belt containing a set of belt layers and located outside the frame layer, an intermediate group of transverse layers of the belt containing another set of belt layers and located outside the inner group of transverse layers of the belt, and an external a group of transverse layers of the belt containing another set of layers of the belt and located outside the intermediate group transversely layer of the belt, the inner group of transversely directed layers of the belt includes the shortest layer of the belt. 2. The tire according to claim 1, in which the angle θf between the longitudinal direction of the protrusions and the center line of the groove in the direction opposite to the direction of rotation of the tire in the projection onto the tread surface is 10-60 °, inclusive. 3. The tire according to any one of claims 1 or 2, in which the height Hf of the protrusions from the bottom of the groove and the depth D of the groove from the tread surface to the bottom of the groove correspond to the condition 0.03D <Hf≤0.4D. 4. The tire according to any one of claims 1 or 2, in which the outer diameter of the OD tire and the caliber of the DC tread rubber composition along the center line of the tire correspond to the condition DC / OD≥0.015. 5. A tire according to any one of claims 1 or 2, in which the protrusions extend continuously from one side wall to the other side wall. 6. A tire according to any one of claims 1 or 2, in which the carcass ply comprises a cord extending in a predetermined direction, and the belt layer includes a cord extending obliquely with respect to the direction of the carcass cord, the width of the inner group of transversely oriented belt layers being 25 % -70%, inclusive, of the width of the tread surface in the direction along its width, the width of the intermediate group of transversely directed layers of the belt is 55% -90%, inclusive, of the width of the tread surface in the direction of its width, the width of the outer groups The width of the transverse layers of the breaker is 60% -110%, inclusive, of the width of the tread surface in the direction along its width, and the angle of inclination of the cord of the breaker of the inner group of transversely directed layers of the belt to the cord of the frame in the projection onto the tread surface is 70-85 °, inclusive , the angle of inclination of the cord of the breaker of the intermediate group of transversely directed layers of the belt to the cord of the carcass in the projection onto the tread surface is 50-75 °, inclusive, the angle of inclination of the cord of the breaker of the outer group of the transversely directed layer belt to the carcass cord in the projection onto the tread surface is 70-85 °, inclusive. 7. A tire according to any one of claims 1 or 2, further comprising a tread sidewall extending inward in the radial direction of the tire from the tread end, which is the outer end of the tread in the tread width direction, the tread side extending continuously to the sidewall of the tire, which forms a sidewall tire surface; a side groove extending from the groove to the side of the tread, the side groove having an exit to the side of the tread; an annular strip opposite the side groove and a groove located between them, and in the annular strip is formed a recess located along the direction of the side groove, having a triangular projection onto the tread surface, and the size of the recess in the direction along the tread width gradually increases from one end between the groove and recess to the top of the recess, and gradually decreases from the top of the recess to the other end between the groove and the recess, and the top of the recess is located on the the direction of the lateral groove and is offset from the center line of this lateral groove, passing through the center of the lateral groove in a direction perpendicular to the direction of extension of the lateral groove. 8. A tire according to any one of claims 1 or 2, comprising a tread sidewall extending inwardly in the radial direction of the tire from the tread end, which is the outer end of the tread in the tread width direction, the tread side extending continuously to the sidewall of the tire forming the side surface of the tire ; a side groove extending from the groove to the side of the tread, the side groove having an exit to the side of the tread; several strips formed by a side groove and a groove, each of the strips having a tread surface for contacting a road surface and a side surface formed outside the strip in a direction along the tread width; a first side surface of the groove forming a side groove wall on one side of the strip in the tire circumferential direction, and a second side surface of the groove forming the side groove wall on the other side of the strip in the tire circumferential direction; the strip is provided with means for supplying air to the side groove, said means being a narrowed surface intersecting the tread surface, a side surface and a first side surface of the groove at an angular edge formed by the tread surface, the side surface and the first side surface of the groove; however, two strips opposite each other with a side groove between them are located so that the first side surface of the groove of one strip is opposite the second side surface of the groove of the other strip, and the second side surface of the groove does not have a tapered surface. 9. A tire according to any one of claims 1 or 2, comprising a tread sidewall extending inward in the radial direction of the tire from the tread end, which is the outer end of the tread in the tread width direction, the tread side extending continuously to a sidewall that forms a side surface of the tire , a lateral groove extending from the groove to the tread side, the side groove having an exit to the tread side and extending at an angle to the tread width that is 15-60 ° inclusively.

Images