JP2006232170A - Pneumatic tire - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pneumatic tire used in a vehicle such as SUV capable of enhancing the driving stability and the resistance against eccentric wear in shoulder regions of the tread. <P>SOLUTION: The grounding width WS of a shoulder region land train 18 influencing the resistance against eccentric wear greatly is set properly, and the rigidity of the land train is heightened appropriately, so that the difference in rigidity from the intermediate region land train 22 lessens to result in suppression of eccentric wear of each shoulder region land train. Heightening of the rigidity of the shoulder region land train leads to enhancement of the driving stability. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a pneumatic tire, and more particularly, to a pneumatic tire having a tread pattern suitable for SUV (Sports Utility Vehicle).

As a tread pattern of a conventional pneumatic tire, for example, increase the rigidity of the land portion in the center area of the tread surface to improve the handling stability on the dry road surface and give the land portion excellent wear resistance. (Refer to Patent Document 1) and a center rib provided with a notch groove (Patent Document 2).
JP 2004-345603 A Japanese Patent Laid-Open No. 5-24415

  However, a vehicle such as an SUV has a larger vehicle weight than a general small vehicle, and therefore, a lateral force of a tire required for cornering is increased, which is generally more disadvantageous in terms of steering stability than a small vehicle. There was a problem of becoming.

  In addition, because the vehicle weight is large, the change in the center of gravity of the vehicle during cornering is large, which increases the lateral load on the shoulder region land portion row in particular, and it is easy to cause uneven wear in the shoulder region land portion row. There was a problem.

  Furthermore, since the deformation load of the tread increases, the amount of heat generated by the tread increases, which is disadvantageous in terms of durability at high speeds exceeding, for example, 200 km / h and handling stability during continuous driving. there were.

  In Patent Document 1 described above, although improvement in handling stability due to improved rigidity of the land portion in the tread tread surface central region is considered, regarding wear resistance, the wear resistance of the land portion in the tread tread center region is considered. However, there is no suggestion about the wear resistance of the shoulder region land row.

  Moreover, in patent document 2, although the notch groove is provided in the center rib, there is no suggestion about the wear resistance of the shoulder region land portion row.

  In view of the above fact, an object of the present invention is to improve steering stability and uneven wear resistance in a shoulder region of a tread in a pneumatic tire used for a vehicle such as an SUV.

  The invention according to claim 1 is a central region formed in the tread between a plurality of circumferential main grooves formed in the tire circumferential direction and the circumferential main grooves furthest away from the tire equatorial plane on both sides in the tire axial direction. A pneumatic tire having a land portion row and a shoulder region land portion row formed on the outer side in the tire axial direction further than the circumferential main groove farthest in the tire axial direction from the tire equator plane, The center region land portion row is formed on the outer side in the tire axial direction with respect to the center rib formed between the circumferential main grooves closest to both sides in the tire axial direction from the tire equatorial plane, and the circumferential main grooves. An intermediate region land portion row, the center rib is formed with a plurality of cutout grooves in the tire circumferential direction with one end opening in the circumferential main groove and the other end terminating in the center rib. The middle region land section row includes A first lug groove that crosses the area land portion row and opens in the circumferential direction main groove on both sides thereof, one end opens in the circumferential direction main groove, and the other end ends in the intermediate region land portion row A grounding width in the shoulder region land portion row on one side immediately below the load when a normal load is applied, and is assembled to a normal rim, is assembled to a normal rim, and is a total grounding width of the tread. It is characterized by being 20 to 30% of the above.

  Here, “regular rim” refers to a standard rim in the applicable size specified in the 2004 version YEAR BOOK issued by JATMA, and “normal load” and “regular internal pressure” are similarly issued by JATMA. This refers to the maximum load and the air pressure for the maximum load in the applicable size and ply rating defined in the 2004 YEAR BOOK.

  When the TRA standard or ETRTO standard is applied at the place of use or manufacturing, the respective standards are followed.

  The reason why the ground contact width in the shoulder region land part row on one side is set to 20 to 30% of the total contact width of the tread is below 20%, the rigidity of the shoulder region land part row becomes too small. This is because wear is likely to occur in the partial row, and if it exceeds 30%, the rigidity of the central region land portion row becomes conversely too small and wear is likely to occur in the central region land portion row. .

  In the pneumatic tire according to claim 1, the center rib is continuous in the tire circumferential direction to increase the rigidity of the center rib, and the second lug groove of the intermediate region land portion row is terminated in the land portion row. Since the rigidity of the central region land portion row is increased by using the bag path, the cornering power with respect to the road surface is increased, and the steering stability is improved.

  In addition, since the notch groove is provided in the center rib and the second lug groove is provided in the middle region land portion row, the ratio of the groove region to the land portion of the tread in the ground contact state is increased, and steering stability during wet running is improved. Can be increased.

  Furthermore, since the contact width of the shoulder region land row is set appropriately and the rigidity of the shoulder region land row is appropriately increased, the difference in rigidity from the intermediate region land row is reduced. This suppresses uneven wear of the shoulder region land row. Steering stability is improved by improving the rigidity of the shoulder region land row.

  As described above, by appropriately increasing the rigidity of the central region land portion row and the shoulder region land portion row, deformation of the tread can be suppressed and the amount of heat generation can be reduced. This makes it possible to ensure high-speed durability and steering stability during continuous running.

  According to a second aspect of the present invention, in the pneumatic tire according to the first aspect, a groove width of the first lug groove and the second lug groove is 5 to 40% of an average groove width of the circumferential main groove. It is characterized by that.

  Here, the groove width of the first lug groove and the second lug groove was set to 5 to 40% of the average groove width of the circumferential main groove. This is because the steering stability is lowered, and if it exceeds 40%, the land portion rigidity is lowered and the steering stability on the dry road surface is lowered.

  In the pneumatic tire according to claim 2, since the groove widths of the first lug groove and the second lug groove are appropriately set, steering stability can be ensured on both the dry road surface and the wet road surface. .

  The invention according to claim 3 is the pneumatic tire according to claim 1 or 2, wherein the shoulder region land portion row includes a plurality of first end lug grooves opened in the circumferential main groove, and the tire. A width of the inner region in the tire axial direction of the shoulder region land portion row within the ground contact width divided by the sub main groove, and the tire shaft. The ratio with the width of the outer region in the direction is from 2: 8 to 5: 5.

  Here, the ratio of the width of the inner region to the width of the outer region is set to 2: 8 to 5: 5. When the ratio is smaller than 2: 8 (the width of the inner region becomes narrower), This is because the rigidity of the land portion is reduced and wear of the inner region is accelerated, and when the ratio exceeds 5: 5 (the width of the outer region is narrowed), the rigidity of the land portion of the outer region is decreased and the outer region is reduced. This is because wear of the region is accelerated.

  In the pneumatic tire according to claim 3, since the first end lug groove is provided in the shoulder region land portion row, drainage can be improved, and the auxiliary main groove is formed in the shoulder region land portion row. Since it is provided at an appropriate position, drainage can be improved and the shoulder region land portion row can be evenly worn.

  According to a fourth aspect of the present invention, in the pneumatic tire according to the third aspect, in the tire circumferential center of a land portion defined by the first end lug groove adjacent to the tire circumferential direction in the outer region. A second end lug groove opened in the sub main groove is formed.

  In the pneumatic tire according to claim 4, since the second end lug groove is provided at the center in the tire circumferential direction of the outer region of the sub main groove in the shoulder region land portion row, the land portion rigidity in the outer region is appropriately set. It is possible to reduce the uneven wear of the shoulder region land portion row. In addition, the second end lug groove is not provided in the inner region, and the rigidity of the land portion is maintained, so that the difference in rigidity between the intermediate region land portion row having high rigidity and the inner region is reduced (the land portion rigidity). Is made uniform).

  According to a fifth aspect of the present invention, in the pneumatic tire according to the third or fourth aspect, the groove width of the sub main groove is 15 to 30% of the average groove width of the circumferential main groove, The groove depth of the sub main groove is 10 to 50% of the average groove depth of the circumferential main groove.

  Here, the lower limit of the groove width of the auxiliary main groove is 15% of the average groove width of the circumferential main groove, and the lower limit of the groove depth of the auxiliary main groove is 10% of the average groove depth of the circumferential main groove. This is because if it is less than this, the drainage performance is lowered and the steering stability on the wet road surface is deteriorated. Further, the upper limit of the groove width of the sub main groove is 30% of the average groove width of the circumferential main groove, and the upper limit of the groove depth of the sub main groove is 50% of the average groove depth of the circumferential main groove. If this is exceeded, the rigidity of the land portion will be reduced, and the steering stability and uneven wear resistance will deteriorate.

  In the pneumatic tire according to claim 5, since the groove width and groove depth of the sub main groove are appropriately set, drainage performance can be enhanced while ensuring steering stability and uneven wear resistance. .

  As described above, according to the pneumatic tire of the present invention, in a pneumatic tire used for a vehicle such as an SUV, it is possible to improve steering stability and uneven wear resistance in a shoulder region of a tread. It has an excellent effect.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In FIG. 1, a pneumatic tire 10 according to the present embodiment includes a tread 12 and a plurality of circumferential main grooves 14 formed in the tire circumferential direction, and ends farthest from the tire equatorial plane CL on both sides in the tire axial direction. The central region land portion row 16 formed between the circumferential main grooves 14A and the shoulder formed on the outer side in the tire axial direction further than the end circumferential main grooves 14B farthest in the tire axial direction from the tire equatorial plane CL. Area land row 18. The tread pattern is point-symmetric with respect to the tire equatorial plane CL, for example.

  The center region land portion row 16 includes a center rib 20 formed between the center circumferential main grooves 14A closest to the tire equatorial plane CL on both sides in the tire axial direction, and a tire axial direction from the central circumferential main grooves 14A. And an intermediate region land row 22 formed on the outside.

  The center rib 20 is formed with a plurality of notch grooves 24 that open in the center circumferential main groove 14A at one end and terminate in the center rib 20 at the other end in the tire circumferential direction. The notch grooves 24 are formed so as to open alternately to the central circumferential main grooves 14A on both sides of the center rib 20 in the tire circumferential direction.

  The middle region land portion row 22 has a first lug groove 26 that opens across the middle region land portion row 22 to the center circumferential main groove 14A and the end portion circumferential main groove 14B on both sides thereof, and one end thereof. It has a second lug groove 28 that opens into the end circumferential main groove 14 </ b> B and that the other end terminates in the intermediate region land row 22. For example, the first lug grooves 26 and the second lug grooves 28 are alternately formed in the tire circumferential direction.

  When the pneumatic tire 10 is assembled to a regular rim (not shown), filled with a regular internal pressure, and directly under a load when a regular load is applied, the ground contact width WS in the shoulder region land portion row 18 on one side is the total ground of the tread It is 20 to 30% of the width W (the distance between the ground contact ends 12A on both sides of the tire equatorial plane CL). The reason for this is that if it is less than 20%, the rigidity of the shoulder region land portion row 18 becomes too small, and the shoulder region land portion row 18 is easily worn, and more than 30%. Conversely, the rigidity of the central region land row 16 is too small, and the central region land row 16 is likely to be worn.

  The groove widths of the first lug grooves 26 and the second lug grooves 28 in the central region land portion row 16 are 5 to 40% of the average groove width of the circumferential main grooves. The reason for this is that if it falls below 5%, the drainage performance deteriorates and the steering stability on the wet road surface decreases, and if it exceeds 40%, the rigidity of the land portion decreases, resulting in a dry road surface. This is because the steering stability is reduced.

  The shoulder region land portion row 18 includes a plurality of first end lug grooves 30 opened in the end circumferential main groove 14B, and sub main grooves 34 formed in the tire circumferential direction. The ratio of the width WSA of the inner region 18A in the tire axial direction to the width WSB of the outer region 18B in the tire axial direction is 2: 8 to 5 in the shoulder region land portion row 18 within the ground contact width WS divided by : 5.

  The reason for this is that if it is less than 2: 8 (the width of the inner region 18A becomes narrower), the rigidity of the land portion of the inner region 18A becomes lower, and the wear of the inner region 18A becomes faster, and This is because if it exceeds 5: 5 (the width of the outer region 18B becomes narrower), the rigidity of the land portion of the outer region 18B becomes lower and the wear of the outer region 18B becomes faster.

  A second end lug groove 32 opened to the sub main groove 34 is formed at the center in the tire circumferential direction of the land portion defined by the first end lug grooves 30 adjacent to each other in the tire circumferential direction in the outer region 18B. . For this reason, the tire circumferential direction is defined by the block length LA of the inner region 18A partitioned in the tire circumferential direction by the adjacent first end lug grooves 30, and the adjacent first end lug grooves 30 and second end lug grooves 32. The ratio of the outer region 18B divided into the block length LB is, for example, about 2: 1. The “center in the tire circumferential direction of the land portion” is not limited to the center in the tire circumferential direction of the land portion, and ranges from the center to both sides in the tire circumferential direction, for example, up to 80% of the block length LA, more preferably A range of up to 20% is included.

  The groove width of the sub main groove 34 is 15 to 30% of the average groove width of the circumferential main groove, and the groove depth of the sub main groove 34 is 10 to 50% of the average groove depth of the circumferential main groove. It is characterized by being.

  Here, the lower limit of the groove width of the sub main groove 34 is 15% of the average groove width of the circumferential main groove, and the lower limit of the groove depth of the sub main groove 34 is 10% of the average groove depth of the circumferential main groove. The reason for this is that below this value, the drainage performance decreases and the steering stability on the wet road surface deteriorates. Further, the upper limit of the groove width of the sub main groove 34 is 30% of the average groove width of the circumferential main groove, and the upper limit of the groove depth of the sub main groove 34 is 50% of the average groove depth of the circumferential main groove. This is because, if this is exceeded, the rigidity of the land portion becomes small and the steering stability and uneven wear resistance deteriorate.

The first end lug groove 30 and the second end lug groove 32 communicate with the outside ground contact region 18C on the outer side in the tire axial direction than the ground contact end 12A, respectively. Wrapped. In addition, about the 1st edge lug groove 30, it has branched in the folding | turning direction and the direction opened to the tread end 12B in the area | region 18C outside grounding. The reason why the first end lug groove 30 is opened to the tread end 12B is because drainage is taken into consideration.
(Function)
In the pneumatic tire 10, the center rib 20 is made continuous in the tire circumferential direction to increase the rigidity of the center rib 20, and the second lug groove 28 of the intermediate region land portion row 22 is terminated in the land portion row. Since the rigidity of the central region land portion row 16 is increased by adopting the shape of the narrow path, the cornering power with respect to the road surface is increased, and the steering stability is improved.

  In addition, since the notch groove 24 is provided in the center rib 20 and the second lug groove 28 is provided in the intermediate region land portion row 22, the ratio of the groove region to the land portion of the tread 12 in the ground contact state is increased, so that during wet running Can improve the steering stability.

  Furthermore, since the ground contact width WS of the shoulder region land portion row 18 having a great influence on the uneven wear property is appropriately set and the rigidity of the shoulder region land portion row 18 is appropriately increased, the rigidity with the intermediate region land portion row 22 is increased. The difference is reduced, thereby suppressing uneven wear of the shoulder region land portion row 18. Due to the improved rigidity of the shoulder region land portion row 18, the steering stability is also increased.

  By appropriately increasing the rigidity of the central region land portion row 16 and the shoulder region land portion row 18, deformation of the tread 12 can be suppressed and the amount of heat generation can be reduced. This makes it possible to ensure high-speed durability and steering stability during continuous running.

  Moreover, since the groove width of the 1st lug groove 26 and the 2nd lug groove 28 is set appropriately, steering stability can be ensured in any of a dry road surface and a wet road surface.

  Further, since the first end lug groove 30 is provided in the shoulder region land row 18, drainage can be improved, and the auxiliary main groove 34 is provided at an appropriate position in the shoulder region land row 18. Therefore, drainage can be improved and the shoulder region land portion row 18 can be evenly worn.

  Further, a second end lug groove 32 is provided at the center in the tire circumferential direction of the outer region 18B of the auxiliary main groove 34 in the shoulder region land portion row 18, and the block length LA of the inner region 18A is set to be the block length LB of the outer region 18B. Therefore, the difference in rigidity between the intermediate region land row 22 having high rigidity and the inner region 18A is reduced (the land portion rigidity is made uniform), and the land portion rigidity in the outer region 18B is reduced. Is moderately reduced, and uneven wear of the shoulder region land portion row 18 is suppressed.

  And since the groove width and groove depth of the sub main groove 34 are also set appropriately, drainage performance can be enhanced while ensuring steering stability and uneven wear resistance.

Therefore, the pneumatic tire 10 according to the present embodiment is suitable for an SUV vehicle having a high speed traveling performance.
(Test example)
Under the conditions shown in Table 1, tires according to Example 1 (FIG. 2), Example 2 (FIG. 3), and the conventional example (FIG. 4) were manufactured and tested for uneven wear resistance and steering stability. . The tire sizes are 255 / 50R18, and the vehicle used for the test is Porsche Cayenne.

  Here, in FIG. 4, 100 is a pneumatic tire according to the conventional example, 102 is a tread, 102A is a ground contact end, 104 is a circumferential main groove, 106 is a lug groove, 108, 110, 118 are notched grooves, 112 is The center rib, 114 is an intermediate region land row, and 116 is a shoulder region land row.

  In Table 1, WS is the ground contact width of the shoulder region land row, W is the total ground contact width, LA is the block length of the inner region of the sub main groove in the shoulder region land row, and LB is the outer region of the sub main groove. The block length, WSA is the width of the inner area, and WSB is the width of the outer area.

  For uneven wear resistance, a traveling course combining urban areas, highways and mountain slopes was run for 10,000 km, and the average amount of wear in the central region land row and the average amount of wear in the shoulder region land row were measured. The numerical value of the evaluation result shown in Table 1 is the ratio of the average wear amount of the central region land portion row to the average wear amount of the shoulder region land portion row, and the smaller the value, the more the wear amount of the shoulder region land portion row 18 is. It is shown that.

  Regarding the handling stability, the piloting ground owned by the applicant of the present application was used to comprehensively evaluate the handling stability on the dry road surface and the driving stability on the wet road surface. The evaluation results shown in Table 1 are based on the 10-point scale method, and the larger the value, the better the steering stability.

  According to this test example, the tires according to Example 1 and Example 2 have significantly improved uneven wear resistance compared to the conventional example, and the handling stability also improved the feeling compared to the conventional example. Yes.

It is a figure which shows the tread pattern of a pneumatic tire. It is a figure which shows the grounding state of the tread which concerns on Example 1 in a test example. It is a figure which shows the grounding state of the tread which concerns on Example 2 in a test example. It is a figure which shows the grounding state of the tread which concerns on the prior art example in a test example.

Explanation of symbols

10 Pneumatic tire 12 Tread 14 Circumferential main groove 14A Central circumferential main groove (circumferential main groove)
14B End circumferential main groove (circumferential main groove)
16 Central region land portion row 18 Shoulder region land portion row 18A Inner region 18B Outer region 20 Center rib 22 Middle region land portion row 24 Notch groove 26 First lug groove 28 Second lug groove 30 First end lug groove 32 First 2 end lug grooves 34 secondary main groove W total ground width WS ground width of shoulder area land row WSA width of inner area WSB width of outer area LA block length of inner area LB block length of outer area

Claims (5)

A plurality of circumferential main grooves formed on the tread in the tire circumferential direction, a central region land row formed between the circumferential main grooves furthest from the tire equatorial plane to both sides in the tire axial direction, and the tire A pneumatic tire having a shoulder region land portion row formed on the outer side in the tire axial direction further than the circumferential main groove farthest in the tire axial direction from the equator plane,
The central region land portion row is formed on the outer side in the tire axial direction with respect to the center rib formed between the circumferential main grooves closest to the tire equator plane on both sides in the tire axial direction. And intermediate region land part row,
The center rib is formed with a plurality of notch grooves that open in the circumferential main groove at one end and terminate in the center rib at the other end in the tire circumferential direction.
The intermediate region land portion row includes a first lug groove that crosses the intermediate region land portion row and opens to the circumferential main grooves on both sides thereof, and one end that opens to the circumferential main groove, and the other end. Having a second lug groove terminating in the middle region land row,
Assembled in a regular rim, filled with regular internal pressure, and directly under the load when a regular load is applied, the ground contact width in the shoulder region land part row on one side is 20 to 30% of the total ground contact width of the tread. A featured pneumatic tire.   2. The pneumatic tire according to claim 1, wherein a groove width of the first lug groove and the second lug groove is 5 to 40% of an average groove width of the circumferential main groove. The shoulder region land portion row has a plurality of first end lug grooves opened in the circumferential main groove, and a sub main groove formed in the tire circumferential direction,
The ratio of the width of the inner region in the tire axial direction to the width of the outer region in the tire axial direction of the shoulder region land portion row within the ground contact width divided by the sub main groove is 2: 8. It is thru | or 5: 5, The pneumatic tire of Claim 1 or Claim 2 characterized by the above-mentioned.   In the outer region, a second end lug groove that is open to the sub main groove is formed at the center in the tire circumferential direction of the land portion defined by the first end lug groove adjacent in the tire circumferential direction. The pneumatic tire according to claim 3. The groove width of the sub main groove is 15 to 30% of the average groove width of the circumferential main groove,
The pneumatic tire according to claim 3 or 4, wherein a groove depth of the sub main groove is 10 to 50% of an average groove depth of the circumferential main groove.

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