JP4118390B2 - Pneumatic radial tire - Google Patents

Description

【００５７】
実施例１〜３、比較例および従来例のタイヤを供試タイヤとし、前記リム及び空気圧を用いて下記２項目の試験を下記試験条件の下で実施した。
（１）キャンバースラストＦｃの測定：フラットベルト式室内試験機を用い、ベルト速度を６０km/hとし、このベルトに各供試タイヤをキャンバー角度５°の下で最大負荷能力６５０kgの７０％に相当する荷重４５０kgf で押圧し、キャンバースラストＦｃを測定した。測定結果は比較例を１００とする指数にてあらわすものとした。値は小なる程良い。
（２）実車による直進走行安定性のテスト：個々の供試タイヤを国産乗用車２５００ｃｃクラスのＦＲ車の全輪に装着し、前席に２名乗車し轍を形成した乾燥アスファルトのテスト路面を１００km/hの速度で走行したときのワンダリング現象発現度合い、すなわち直進走行安定性をテストドライバのフィーリングにより１０点満点で評価した。評点は大きいほど良い。
以上の２項目のテスト結果を表１の下側に示す。
【００５８】
表１に示すテスト結果から、実施例１〜３のタイヤはいずれも、従来例のタイヤに比しキャンバースラストＦｃ発生量が著しく低減し、実車による乾燥轍路面走行試験における直進走行安定性が格段に優れていることがわかり、実施例１〜３のタイヤそれぞれを詳細に比較すれば、キャンバースラストＦｃ低減及び直進走行安定性向上について、細溝１０の傾斜効果が大きく、分断陸部９ａ面取り部Ｙの効果はさらに一層大きく、これらに加え領域幅Ｂに中央溝１３を設ける効果が最良であることがわかる。
【００５９】
【発明の効果】
この出願の請求項１〜３に記載した発明によれば、轍に代表されるような両側に登り勾配の傾斜面を有する凹部が形成されている路面走行でのワンダリング現象の発生が抑制され、その結果高速での直進走行安定性に優れる、特に偏平率が６０％以下の高性能ラジアルタイヤと呼ばれる空気入りラジアルタイヤを提供することができる。
【図面の簡単な説明】
【図１】 この発明に係る技術的課題の解決手段例を示すタイヤの左半断面図である。
【図２】 図１に示すトレッド部の、フットプリントによる接地形状転写図である。
【図３】 図２のIII − III線に沿うトレッド部の拡大断面図である。
【図４】 図３に示すトレッド部の変形例を示す拡大断面図である。
【図５】 トレッド部の他の変形例を示す拡大断面図である。
【図６】 図２〜図５に示すトレッド部と異なるトレッド部の、フットプリントによる接地形状転写図である。
【図７】 図６のVII − VII線に沿うトレッド部の拡大断面図である。
【図８】 図７に示すトレッド部の変形例を示す拡大断面図である。
【図９】 さらに他のトレッド部のフットプリントによる接地形状転写図である。
【図１０】 図９のX − X線に沿うトレッド部の拡大断面図である。
【図１１】 この発明に係るタイヤの実施形態を示すものであって、図６及び図９に示す接地形状を有するトレッド部のタイヤ赤道面と平行な平面による要部の一部断面図である。
【図１２】 図１１に示す要部の変形例になる、要部の一部断面図である。
【図１３】 図１１に示すトレッド部の平坦路面への接地状態の説明図である。
【図１４】 図１２に示すトレッド部の平坦路面への接地状態の説明図である。
【図１５】 傾斜路面走行タイヤの図２に示すフットプリント最外側縁取り線図である。
【図１６】 傾斜路面走行タイヤの図６、図９に示すフットプリント最外側縁取り線図である。
【図１７】 従来タイヤのトレッド部のフットプリントによる接地形状転写図である。
【図１８】 傾斜路面を走行するタイヤの正面図又は背面図である。
【図１９】 図８に示すタイヤの部分拡大断面図である。
【図２０】 図１８及び図１９に示すタイヤをキャンバー角度１０°で平板に押圧したトレッド部のフットプリントの接地部縁取り図である。
【図２１】 図２０に示すタイヤを平板へ垂直に押圧したトレッド部のフットプリントの接地部縁取り図である。
【符号の説明】
１ 空気入りラジアルタイヤ
２ ビード部
３ サイドウォール部
４ トレッド部
４ｔ 踏面
５ ビードコア
６ カーカス
６−１、６−２ カーカスプライ
７ ベルト
８ トレッドゴム
８ｔ トレッドゴム表面
９ 段下がり部
９ａ 分断陸部
１０ 細溝
１０ｂ 細溝の切り込み底
１１、１３ トレッド周方向中央溝
１２ トレッド周方向側方溝
１４、１６ 傾斜溝
１５ 傾斜枝溝
Ｅ タイヤ赤道面
Ｗｃ 接地幅
Ｒｃ 中央領域
Ｒｓ ショルダ領域
Ｄ タイヤ回転方向
δ 段下がり部の段差量
Ｙ 面取り部
ＶＬ 垂線
α 細溝の垂線ＶＬに対する傾斜角度
Ｉ_S 傾斜路面
Ｓ 平板表面
Ｆｃ キャンバースラスト
Ｆｙ 横力
Ｓcr、Ｓｂ せん断力
Ｆxb タイヤへの制動力
Ｚ 図形の重心を通るタイヤ半径方向軸
Ｍｚ 復元モーメント[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a pneumatic radial tire, and more particularly to a pneumatic radial tire for use in a vehicle such as a passenger car, a truck, and a bus. Pneumatic radial tires that improve the straight running stability by suppressing the so-called wandering phenomenon, which is a driver's unpredictable tire behavior that occurs when traveling on the road at high speed, and has a particularly small flatness Related to high performance radial tires.
[0002]
[Prior art]
Pneumatic radial tires, especially high-performance radial tires, have high lateral rigidity to generate lateral force commensurate with the centrifugal force of the vehicle that occurs when the vehicle turns due to the recent increase in output of vehicles. Therefore, the tire must have a tire shape that reduces the flatness ratio and suppresses the height of the sidewalls to make the contact width of the tread as wide as possible. is doing.
[0003]
[Problems to be solved by the invention]
High-performance radial tires exhibit excellent handling stability when running on flat roads, but when traveling at high speeds on road surfaces with sloping surfaces such as saddle recesses, the tires are subject to the degree of inclination of the recesses on the road surface. As a result of inhomogeneous forces acting, complex behavior is exhibited.
[0004]
For example, a tire having a small flatness, particularly a passenger car radial tire having a flatness of 60% or less, is shown in FIG. 18 showing the front or back of a tire traveling on an inclined road surface. Tire 20 The camber thrust Fc in the climb gradient direction (the direction indicated by the arrow) receives the lateral force Fy that is a component force in the direction of the axis XX of the tire 20, and the vehicle uses the lateral force Fy to drive up the slope road surface Is. As a result, the straight running stability is impaired. In general, when the slope of the inclined road surface Is is the same, the value of the lateral force Fy is larger as the tire has a smaller flatness.
Force F R Is a reaction force component perpendicular to the inclined road surface Is with respect to the load W applied to the tire 20.
[0005]
The reason why the camber thrust Fc is generated in the tire 20 traveling on the inclined road surface Is is as follows. That is, the tire 20 shown in FIG. The main part In FIG. Magnify As shown, the running tire 20 is caused by a load W acting in a direction perpendicular to the rotational axis XX. , The higher the slope on the slope Is, the higher the slope , It is pressed more strongly by the road surface Is, and rather floats from the road surface Is on the downhill side.
[0006]
As a result, the deflection deformation amount of the sidewall portion 21 of the tire 20 that presses the upward slope upward side of the inclined road surface Is under the vertical load W applied to the tire 20 is the deflection deformation amount of the downward slope sidewall portion 21. The large bending deformation on the upper side of the uphill gradient causes the carcass ply to fall down in the direction of arrow A, and the belt 22 near the carcass ply that falls down and deforms along with this deformation is bent in the direction of arrow B. Since deformation occurs, shear deformation occurs in the tread rubber 23 portion that covers the belt 22 portion that undergoes bending deformation. As a result, the tread rubber 23 of the tire 20 as a whole climbs on the inclined road surface Is, a shearing force in the direction of arrow C is generated, and the resultant force of the shearing force on the entire contact surface is nothing but the camber thrust Fc. .
[0007]
In other words, as described above, when the tread portion of the running tire 20 gets on the inclined road surface Is, the tire 20 generates a camber thrust Fc in the upward inclination direction of the inclined road surface Is, and the lateral force Fy component causes the driver. Regardless of the intention of the vehicle, the vehicle traveling at high speed exhibits a so-called wandering phenomenon in which the vehicle rapidly climbs up the inclined road surface Is, and the straight running stability of the vehicle is significantly impaired.
[0008]
In order to improve this wandering, it has been proposed to chamfer the edge of the tread part or to apply a large number of sipe (slit) processes, thereby reducing the camber thrust Fc. This is only a countermeasure, and it must be said that a high-performance radial tire with a flatness ratio of 60% or less is inadequate, and a tire capable of exhibiting highly straight running stability suitable for a high-performance radial tire. What is desired is the current situation.
[0009]
Therefore , this application Claims 1 to 1 3 The pneumatic radial which is excellent in straight running stability at a high speed by suppressing the occurrence of wandering phenomenon on road running in which concave portions having slopes with upward slopes are formed on both sides like a kite. An object is to provide a tire, particularly a high-performance radial tire having a flatness ratio of 60% or less.
[0010]
[Means for Solving the Problems]
To achieve the above purpose As one means, A pair of bead portions and a pair of sidewall portions, and a toroidal tread portion connected to both sidewall portions, and a radial carcass of one or more plies that reinforces each portion between bead cores embedded in the bead portions; A belt that reinforces the tread on the outer periphery of the radial carcass Ingredients In the pneumatic radial tire having the tread rubber on the outermost side of the tread portion,
Ground contact state of a tread portion in which a tire filled with air pressure corresponding to the maximum load capacity of the tire is pressed perpendicularly to a flat plate under a load load corresponding to 70% of the maximum load capacity so, The tread rubber of the tread portion is divided into three regions, a central region including the tire equatorial plane and having 30% of the contact width Wc in the tire rotation axis direction and a shoulder region on both sides thereof, and at least a part of the central region Rubbing contact with the road surface under rolling of the tire in the area And In the non-contact area, it has a step-down from the surface of the surrounding tread rubber, and , The value of the ratio A / Wc of the tire rotation axis direction width A of the step-down portion to the ground contact width Wc in the ground contact state of the tread The 0.05 or more To be is there.
[0011]
here , The maximum load capacity of the above tire is the maximum load capacity (in bold) of the load capacity (kg) listed in the “Pneumatic-Load Capacity Table” for each tire type described in the following standards. Or the value calculated from the load capacity (kg) per axis, and the air pressure corresponding to the maximum load capacity is the air pressure (kPa or kgf / cm) listed in the “Air Pressure-Load Capacity Table” above. ² ) Or filling air pressure (bar) value.
Also, the above of Standards shall conform to industrial standards valid for the region where tires are produced or used. For example, in Japan, JATMA YEAR BOOK (1998 edition) of the Japan Automobile Tire Association, and in the United States, THE TIRE and RIM ASSOCIATION INC. YEAR BOOK 1998 According to STANDARDS MANUAL 1998 of The European Tire and Rim Technical Organization in Europe.
The ground contact width also follows the definition of “ground contact width” described in “2. Definition of Terms” in “General Information” of these standards, for example, JATMA YEAR BOOK (1998 edition). Fill tires with air pressure , The rim used for applying a load is an applicable rim for each tire type and tire size listed in the table of “Applied rim for tire” similarly described in the above-mentioned standard.
[0012]
In the pneumatic radial tire as above, It is preferable that a step amount between the stepped portion and the closest tread rubber surface in a no-load tire filled with air pressure corresponding to the maximum load capacity is in a range of 0.1 to 1.0 mm. Fits.
This level difference is the air pressure of Filling Time In the cross section of the plane including the rotation axis of the tire, the convexity toward the outer side in the tire radial direction is interpolated with an arc having the largest curvature radius of the curvature radius of the tread rubber surface contour curve closest to the stepped portion. The distance between a virtual curve having one radius of curvature and the surface contour of the stepped portion is defined.
[0013]
these The structure further developed has a tread circumferential groove in the central region of the tread rubber, and has a step-down portion connected to the groove on at least one side along the groove. thing It is.
[0014]
In order to achieve the above purpose, application The invention described in claim 1 includes a pair of bead portions, a pair of sidewall portions, and a toroid-like tread portion connected to both sidewall portions, and these portions are reinforced across bead cores embedded in the bead portions. One or more ply radial carcass, and a belt that reinforces the tread portion on the outer periphery of the radial carcass Ingredients In the pneumatic radial tire
Ground contact state of a tread portion in which a tire filled with air pressure corresponding to the maximum load capacity of the tire is pressed perpendicularly to a flat plate under a load load corresponding to 70% of the maximum load capacity so, The tread rubber of the tread portion is divided into three regions including a central region including the tire equatorial plane and 30% of the contact width Wc in the tire rotation axis direction and a shoulder region on both sides thereof, and at least a part of the central region The region includes at least one of a plurality of narrow grooves and sipes extending in the tire rotation axis direction. Ingredients And , At least one of the plurality of narrow grooves and sipes Ingredients The ratio B / Wc of the width B in the tire rotation axis direction to the contact width Wc is 0.05 or more. In addition, the tread portion has a tread pattern with a rotational direction designation, and under no load on the tire, at least one of the plurality of narrow grooves and sipes is a method of tread rubber surface passing through the cut edge. Inclined at an angle of 3 ° or more with respect to the plane including the line, and the inclination is the same as the tire rotation direction from the cut bottom toward the tread rubber surface. This is a pneumatic radial tire.
[0015]
here so, Fill the tire with the maximum load capacity, air pressure corresponding to the maximum load capacity, contact width and tire pressure. , All rims used to load loads shall comply with the standards described above.
In addition, at least one of the plurality of narrow grooves and sipes includes three kinds of cases, that is, only a plurality of narrow grooves, only a plurality of sipes, and a mixture of a plurality of narrow grooves and a plurality of sipes. The case exists, and so on.
00 16 ]
Also, above like As an implementation development regarding a plurality of inclined narrow grooves and sipes, the claims 2 The obtuse angle side edge along the division of the tread rubber land portion where at least one of the narrow groove and the sipe is divided is chamfered in a cross section by a plane orthogonal to at least one of the plurality of the narrow grooves and the sipe. A tire having a part is even more advantageous.
00 17 ]
Claim According to 1 and 2 Common to inventions And A further development of these is claimed. 3 The tread rubber has a tread circumferential groove in the central region of the tread rubber, and has at least one of the plurality of narrow grooves and sipes that are connected and opened to the groove on at least one side along the groove. thing It is.
00 18 ]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, this invention Examples of solutions to technical problems Figure 1 to Figure 10 Based on
FIG. One example Pneumatic radial tire Indicate It is a left half sectional view,
2 shows the tire tread portion shown in FIG. , It is a ground shape transfer diagram by footprint,
Figure 3 2 Of the tire tread along the line III-III Expansion It is a sectional view,
4 shows the tread shown in FIG. Enlarging to show a variation of It is a sectional view,
FIG. Enlargement showing other variations It is a sectional view,
6 shows a tread portion different from the tire tread portion shown in FIGS. , It is a ground shape transfer diagram by footprint,
7 is similar to FIG. of Of tire tread along the line VII-VII Expansion It is a sectional view,
8 shows the tread portion shown in FIG. Enlarging to show a variation of It is a sectional view,
FIG. Yet another It is a contact shape transfer diagram by the footprint of the tread part,
FIG. 10 is similar to FIG. of X − of tire tread along X-ray Expansion It is a sectional view,
FIG. Embodiment of the tire which concerns on this invention is shown, FIG. 10 is a partial cross-sectional view of the main part of a plane parallel to the tire equatorial plane of the tread portion having the ground contact shape shown in FIGS.
12 shows the main part shown in FIG. A variation, It is a partial cross section figure of the principal part.
00 19 ]
In FIG. 1, a pneumatic radial tire 1 (hereinafter referred to as a tire 1) includes a pair of bead portions 2 (only one side is shown), a pair of sidewall portions 3 (only one side is shown), and a pair of sidewall portions 3. A tread portion 4 that is continuous in a shape And each Bead core 5 embedded in the bead part 3 of One ply or more that reinforces each of the parts 2, 3, and 4 between each other, the illustrated example is a carcass 6 that is rubber-coated with a radial arrangement cord of two plies 6-1 and 6-2, and a tread portion on the outer periphery of the carcass 6 4 Belt 7 to strengthen Ingredients Further, a tread rubber 8 is provided on the outer peripheral side of the belt 7.
The illustrated example is a tire 1 for a passenger car. An organic fiber cord such as a polyester cord is applied to the carcass 6, and a belt 7 is applied to the belt 7. , With two steel cord cross layers , For the outermost layer, a cap ply that is a spiral winding of nylon cord is applied.
00 20 ]
The tire 1 is assembled to an applicable rim (not shown) specified by the standard, filled with air pressure corresponding to the maximum load capacity specified by the standard, and the surface of the assembly of the tire 1 and the applicable rim (not shown) is flat. The flat plate is pressed against the flat plate under a load of a load W corresponding to 70% of the maximum load capacity in a state of being stationary with respect to the flat plate.
00 21 ]
At that time, for example, a slow-drying paint is applied to the tread rubber surface 8t, and a paper having a relatively high tensile strength and a relatively thick paper such as Kent paper is used. , In addition, a so-called footprint is employed that can accurately reproduce the ground contact state of the tread rubber surface 8t as if it was printed by using means for fixing the paper to which the paint can be transferred onto a flat plate. The ground transfer shape shown in FIGS. 2, 6 and 9 is obtained by trimming the transfer portion of the footprint. First, description will be made with reference to FIGS. 2, 6 and 9.
00 22 ]
In the following description, the ground contact shape transfer diagram of the tread rubber surface 8t shown in FIG. The In other words, each of these figures is a perspective view of the contact surface of the tread portion 4 from directly above the tire 1, and the tread portion 4 in the contact state under the load of the load W is shown in FIG. As shown in FIG. 6, each has a straight tread circumferential central groove 11 on both sides near the tire equatorial plane E, and a straight tread circumferential side groove 12 directed to one on both sides thereof. 9, one straight tread circumferential central groove 13 on the tire equator plane E and one straight tread circumferential lateral groove 12 addressed to one like FIG. 2 and FIG. Have. All of the illustrated examples are straight grooves, but may be zigzag grooves or curved grooves.
00 23 ]
The tread portion 4 further extends in the shape of a letter “C” on both sides of the central grooves 11, 13. The An inclined groove 14 opening in the side groove 12 and a branch from the inclined groove 14 , Inclined groove 14 Extending in the same direction as The Lateral groove 12 And a plurality of inclined grooves 16 that open to the side groove 12 and open to the end of the tread portion 4 therefrom.
Slope The groove 16 , It inclines in the same direction as the inclined groove 14 and the inclined branch groove 15.
00 24 ]
As is clear from the above, the tire 1 of these examples has a tread pattern for designating the rotation direction, and the rotation direction in the tire 1 is indicated by an arrow D in FIGS. 2, 6, and 9.
2, 6, and 9 are ground contact shape transfer diagrams, in the load-loaded rolling of the tire 1, the lower side of FIGS. 2, 6, and 9 is the grounding step and the upper side is the kicking side.
00 25 ]
Here, the contact width Wc of the tread portion 4 defined by the JATMA standard is the maximum linear distance in the axial direction of the tire 1 on the contact surface with the flat plate, and this contact width Wc is shown in FIGS. Here, a region including the tire equatorial plane E and having a 30% width of the contact width Wc in the tire rotation axis (not shown) direction is defined as a central region Rc, its both side regions are defined as a shoulder region Rs, and the tread rubber 8 is divided into three regions. Divide into
In FIG. 1, a region RcU corresponding to the central region Rc is shown on the assumption that the tire 1 is assembled to an applicable rim (not shown) and filled with air pressure corresponding to the maximum load capacity described above. The last symbol U means a no-load state, and so on.
00 26 ]
First, referring to FIGS. 2 to 5, the tread rubber surface 8 t of the tire 1 filled with air pressure corresponding to the maximum load capacity in at least a partial region A (partial region in the example of FIG. 2) of the central region Rc. The stepped portion 9 is provided, and the ratio A / Wc of the stepped portion 9 to the ground width Wc is 0.05 or more. Needless to say, the upper limit of the value of the ratio A / Wc is 0.3.
00 27 ]
3 is provided over the entire region width AU sandwiched between two central grooves 11 disposed in the central region Rc as shown in FIG. 2 (the groove 11 on one side along the central groove 11). 4), the stepped portion 9 shown in FIG. 4 is provided on both sides of the central groove 13 illustrated in FIG. 9 instead of the two central grooves 11 (on both sides along the central groove 13). The width AU of the stepped-down portion 9 at this time is a width straddling the central groove 13. And the step-down part 9 shown in FIG. 5 is the example provided in the tread rubber 8 of the site | part which does not have a groove | channel.
00 28 ]
As shown in FIG. 2, these stepped portions 9 are grounded at both ends in the grounding length direction along the tire equatorial plane E shorter than the grounding length of the surface of the tread rubber 8 adjacent to the stepped portion 9. Have a length.
In other words, the stepped-down portion 9 always comes into contact with the road surface (flat plate) under a load W corresponding to 70% of the maximum load capacity of the tire 1, while the length of both end portions in the contact length direction is Since it is shorter than the contact length of the surface of the adjacent tread rubber 8, it always rubs and contacts with the road surface under the rolling load of the tire. This rubbing contact brings about a force opposite to the traveling direction (rolling direction) of the tire 1, that is, a braking force to the tire 1. In other words, the descending portion 9 becomes a braking force generation region.
00 29 ]
This is because if the stepped portion 9 exists in a part of the land portion excluding the grooves 11 to 16 of the tread rubber 8, the tire radius of the stepped portion 9 is smaller than the tire radius of the remaining land portion. Therefore, the rolling distance is shorter than that of the remaining land portion excluding the descending portion 5, that is, (rolling distance of the remaining land portion) − (rolling distance of the descending portion 9) = Since it has a property of ΔDi (plus value), and the rolling distance of the tire 1 is dominated by the remaining land portion, the stepped portion 9 is eventually dragged and rubbed against the road surface, which is opposite to the traveling direction. This is because the braking force in the direction is applied to the tire 1.
00 30 ]
In this respect, it is important that the step-down portion 9 has a portion that always comes into contact with the road surface under the load W applied to the pneumatic tire 1 described above. In this sense, the step-down portion 9 is a step-down land. The part is formed.
00 31 ]
Next, referring to FIGS. 6 to 8, a plurality of narrow grooves extending in the rotation axis direction of the tire 1 in at least a partial region (a partial region in the example of FIG. 6) of the central region Rc. , Multiple sipes or , One of a mixture of a plurality of narrow grooves and a plurality of sipes is disposed. Any of these multiple narrow grooves, multiple sipes, multiple narrow grooves and multiple sipes Ingredients Of the area , Rotation axis width B of tire 1 , The ratio B / Wc with respect to the ground contact width Wc is set to 0.05 or more. Needless to say, the upper limit of the ratio B / Wc is 0.3.
FIG. 6 shows an example of the narrow groove 10, and the narrow groove 10 will be described below as a representative.
00 32 ]
As shown in FIG. 6, the narrow groove 10 shown in FIG. 7 is provided over the entire region width BU sandwiched between the two central grooves 11 arranged in the central region Rc (the groove 11 on one side of each central groove 11). 8), and the narrow groove 10 having the width BU shown in FIG. 8 is an example provided in the tread rubber 8 in a portion where no groove exists. The narrow groove 10 shown in FIGS. 6-8 forms the land part 9a which divided the land part into the tread circumferential direction by the mutually adjacent narrow grooves 10. FIG.
00 33 ]
Next, referring to FIG. 9 and FIG. 10, the narrow groove 10 is arranged so as to be connected to one straight central groove 13 on the tire equator plane E and project to both sides of the groove 13. The region width B including the narrow groove 10 is a distance between both ends in the tire rotation axis direction as shown in FIG. Although the narrow grooves 10 in the illustrated example are arranged in the tire rotation axis direction, they can be arranged alternately. In any case, the dividing land portions 9 a formed by the narrow grooves 10 in the region width B are located on both sides of the central groove 13.
00 34 ]
By providing the narrow groove 10 in the region width B described above, the narrow groove 10 closes at the time of grounding under the load W load rolling of the tire 1 filled with the air pressure described above, so that the substantially cut-off portion 9a is substantially closed. Since the circumferential length is shortened and the rolling speed is reduced, the region width B acts as a braking force generation region, and causes the tire 1 to act on the braking force. However, in order to generate a larger braking force, it is effective to apply the following means to the narrow groove 10 based on FIGS.
00 35 ]
FIG. 11 is a partial cross-sectional view in the region width B of the tread portion 4 when no load is applied to the pneumatic tire 1 described above. In FIG. 11, the normal line of the tread rubber surface 8 t that passes through the cut edge of the narrow groove 10. The narrow groove 10 is inclined at an inclination angle α with respect to the surface including VL, and the inclination direction of the fine groove 10 is the same as the tire rotation direction D from the cut bottom 10b of the fine groove 10 toward the tread rubber surface 8t. At this time, the tire 1 having a tread pattern designating the rotation direction is suitable.
00 36 ]
FIG. 12 shows a dividing land portion 9a formed by the narrow groove 10 having the inclination angle α shown in FIG. of Each indicates that it has a chamfered portion Y (a portion surrounded by a circle) on the obtuse angle side edge along the division of the divided land portion 9a, and the chamfered portion Y in the illustrated example has an arc having a cross section of radius r. Is omitted, the case where the cross section is a straight line, the case of a compound curve composed of arcs of a plurality of curvature radii, and the case of a compound curve consisting of a curve and a straight line are applicable. This chamfered portion Y can be provided even when the inclination angle α of the narrow groove 10 is 0 °. In this case, the narrow groove of the cut-off dividing land portion 9a that contacts the ground later when the tire load W is rolled. A chamfered portion Y is provided at the 10 edge. As is clear from the above, the chamfered portion Y is provided in the tire 1 having a tread pattern for designating the rotation direction.
00 37 ]
FIG. 13 is an explanatory view showing the ground contact state of the tread portion 4 shown in FIG. 11 to the flat road surface S. In FIG. 13, the narrow groove 10 (two-dot chain line) in the state where the tire 1 is filled with no air pressure and loaded. ) In such a manner that the value of the inclination angle α increases as shown by the solid line due to the load W applied to the tire 1, in other words, the inclination of the dividing land portion 9a increases so as to increase. .
00 38 ]
However, also in this case, since the movement of the tread rubber surface 8t of each dividing land portion 9a on which the partial load ΔW (ΣΔW = W) acts is restricted by the frictional contact with the ground contact surface S, the falling deformation of the dividing land portion 18 does not occur. It is suppressed within the range of this constraint. This suppression is greater in the vicinity of the groove edge 10e of the narrow groove wall that forms an obtuse angle with respect to the ground contact surface S, and a shearing force Sb as a reaction force of this suppression is provided to the dividing land portion 9a, and the direction of the shearing force Sb is shown in FIG. The direction of rotation of the tire 1 is opposite to that indicated by an arrow in FIG. Eventually, the total shearing force ΣSb of each dividing land portion 9a becomes a braking force for the tire 1, and the tread rubber 8 within the region width B becomes a braking force generation region.
00 39 ]
FIG. 14 is an explanatory diagram showing the ground contact state of the tread portion 4 to the flat road surface S shown in FIG. 12. In FIG. 14, the dividing land portion 9 a (shown by a two-dot chain line) of the tread portion 4 is directed to the tire 1. Due to the contact pressure caused by the load W, the deformation as shown by the solid line occurs. However, the vulcanized rubber having a predetermined composition, here the tread rubber 8 has an incompressible characteristic, and therefore tends to expand on the ground contact surface S at the time of crushing deformation. This is particularly noticeable at the groove edge of the narrow groove 10a.
00 40 ]
However, since the movement of the tread rubber surface 8t of each divided land portion 9a on which the partial load ΔW (ΣΔW = W) acts is restricted by frictional contact with the ground contact surface S, expansion deformation is suppressed. As a result, the shearing force Scr in the opposite direction parallel to the tire equator plane E and facing each other in the vicinity of the groove edges of the two narrow grooves 10 adjacent to each other acts on the dividing land portion 9a.
00 41 ]
However, when the tread portion 4 is in a grounded state, the chamfered portion Y has only a chamfered portion Y on the groove edge of one narrow groove wall surface forming the obtuse angle of the dividing land portion 9a, and the groove edge of the other narrow groove wall surface has an acute angle portion, The rubber crushing reaction force of the chamfered portion Y is reduced as compared with the rubber crushing reaction force of the acute angle portion, the balance of the shearing force Scr in the opposite direction is lost, and the shearing force Scr indicated by the broken arrow on the chamfered portion Y side is the acute angle portion. The shearing force Scr is further reduced compared to the shearing force Scr indicated by the solid line arrow on the side, whereby each dividing land portion 9a generates a shearing force in the direction opposite to the rotational direction D of the tire 1 as a whole. This shearing force is slightly reduced even when the inclination angle α of the narrow groove 10 is 0 °. This shearing force also acts on the tire 1 as a braking force. Eventually, the braking force generation region of the tread rubber 8 is within the region width B as the sum of this type of braking force and the braking force by attaching the inclination angle α to the narrow groove 10. Will be formed.
00 42 ]
As described above, the conventional tire 20 having a small flat rate, particularly the tire 20 having a flat rate of 60% or less, is used when traveling on an inclined road surface IS having an uphill slope as shown in FIGS. The tread rubber 23 is more strongly pressed against the inclined road surface Is as it becomes higher above the uphill slope of the inclined road surface Is due to the vertical load W applied to the tire 20, and even below the uphill slope, the tread rubber is even lifted. As a result, as described above, the lateral force Fy acts on the tire 20 traveling on the inclined road surface Is under the load W in the upward gradient direction. FIG. 20 shows a ground contact shape corresponding to the ground contact state of the tread portion tread surface 23t on the inclined road surface IS.
00 43 ]
FIG. 20 is an edge view of the contact portion when the tire 20 filled with the above-described air pressure is pressed against the flat plate at a camber angle of 10 ° under a load W load corresponding to 70% of the maximum load capacity.
The ground contact state of the horizontal flat road surface of the tire 20 under the same conditions as those of the ground contact portion edge diagram shown in FIG. 20 is shown in FIG. The symbol E shown in FIGS. 20 and 21 is an equator line corresponding to a line on the tire equator plane.
20 shows an overall trapezoidal shape as seen from the overall, and shows that only the tread portion tread 23t on one side is grounded from the tire equator line E, while the grounding portion shown in FIG. It can be seen that the border view has a generally oval shape with the tire equator line E as the central axis when viewed in overalls.
00 44 ]
The above-described ground contact state of the tread portion 4 is the same in the case of the tire 1, and therefore the lateral force Fy is also applied to the tire 1 traveling on the inclined road surface IS under the load W (see FIGS. 18 and 19). 15 is a diagram in which the sloped road surface IS traveling tire 1 is connected to the outermost edge of the footprint shown in FIG. , 6 and 9 of Referring to FIG. 16, which is a diagram linking the outermost borders of the footprints shown, the braking force Fxb generated in the tread rubber 8 with the region width A of the step-down portion 9 and the tread rubber with the region width B of the narrow groove 10 Each of the braking forces Fxb generated in FIG. 8 acts, and these braking forces Fxb pass through the center of gravity (centroid) of the figures shown in FIGS. The tire 1 is significantly different from the conventional tire 20 in that the restoring moment Mz is generated.
00 45 ]
The restoring moment Mz works to cancel the lateral force Fy, and the vector amount of the lateral force Fy is reduced, is almost zero, or is slightly negative depending on the case. As a result, the tire 1 has a tread portion on the inclined road surface Is. Even if a part of the vehicle 4 rides on, the tire 1 will not behave against the driver's intention so as to run up the sloped road surface Is, and as a result, the straight running stability of the road surface in which a concave portion such as a saddle road surface is formed. Is significantly improved.
00 46 ]
The conditions of the air pressure and the load W for determining the range of the central region Rc are set as conditions close to the use conditions in the actual vehicle, and the width of the central region Rc is set to 30% of the ground contact width Wc. When the central region Rc exceeds 30% of the ground contact width Wc, when the tire rolls on the inclined surface, referring to FIGS. 15 and 16, the central region Rc also exhibits a single ground contact state, resulting in the central region Rc. This is based on the reason that the applied point of the braking force Fxb has a distance on the ascending slope side with respect to the tire equator line E, and the restoring moment Mz is reduced. The ratio A / Wc and the ratio B / Wc are set to 0.05 or more for the contact width Wc of the region widths A and B, respectively. If the ratio is less than 0.05, sufficient braking force Fxb cannot be obtained. Because. Of course, the upper limit of each of the ratio A / Wc value and the ratio B / Wc value is 0.3.
00 47 ]
Further, the step amount δ (see FIGS. 3 to 5) between the stepped portion 9 and the closest tread rubber surface 8t is practically within the range of 0.1 to 1.0 mm, and the step amount δ is 0. If it is less than 1 mm, sufficient braking force Fxb cannot be obtained, and if it exceeds 1.0 mm, sufficient grounding of the stepped-down portion 9 cannot be obtained, and further grounding does not occur. The step amount δ is measured with reference to FIGS. 3 to 5, the radius of curvature R of the contour curve of the tread rubber surface 8 t closest to the step-down portion 9. ₁ , R ₂ A virtual curve (shown by a two-dot chain line in the figure) having a curvature radius R that protrudes outward in the radial direction of the tire 1 and a surface contour of the stepped portion, interpolated with an arc having the largest curvature radius Depending on the distance between the lines.
00 48 ]
Further, the radius of curvature r of the chamfered portion Y and the maximum cutting height into the narrow groove 10 are in the range of 0.5 to 3 mm. Because if it is less than 0.5 mm, the above-mentioned effect cannot be obtained in practice, and if it exceeds 3 mm, the ground contact area of the dividing land portion 9a is excessively reduced, and the effect is excessively reduced.
00 49 ]
The braking force Fxb can be generated even when the inclination angle α of the narrow groove 10 with respect to the plane including the normal line VL is 0 °, and the restoring moment Mz due to the braking force Fxb can be applied to the tire 1, but a greater control is required. In order to obtain the power Fxb and the restoring moment Mz, it is effective to set the inclination angle α of the narrow groove 10 to 3 ° or more. The larger the value of the inclination angle α, the better the result can be obtained. On the other hand, if the value is too large, there will be a problem with the ability to pull out in the vulcanization molding process at the time of tire production, so the upper limit should be limited to 30 °. .
00 50 ]
Further, the stepped portion 9 and the narrow groove 10 can be provided at a plurality of positions separated from each other in the rotational axis direction of the tire 1. In this case, as shown in FIGS. 4, 9, and 10, the tread circumferential groove 13 is provided. It is good to provide via. This is because a shearing force in the driving direction is generated on the tread rubber surface 8t sandwiched between the plurality of stepped-down portions 9 or the narrow grooves 10, and this reduces the braking force Fxb.
The braking force Fxb source areas A and B , In the case of the tire 1 in which the outer side or the inner side is arbitrary in the mounting posture on the vehicle, it is preferable to equally distribute the tires on both sides of the tire equator plane E (shown in FIGS. 1 to 10). In the case of 1, it is advantageous to deviate from the tire equatorial plane E within the range of the central region Rc, and to increase the distance from the center of gravity of the grounded figure of the tread portion 4 on the inclined road surface Is as much as possible.
00 51 ]
In summary, the braking force Fxb generation source region is formed in the tread rubber 8 in at least a partial region A and B of the central region Rc of the tread portion 4 to roll up the slope road surface Is of the ascending slope. The tire 1 can be applied with a restoring moment Mz for reducing the lateral force Fy, and thus can stably travel on the slope slope road surface Is, and is excellent in straight traveling stability on the concave surface. Is that you can get
00 52 ]
【Example】
A radial ply tire for passenger cars, the size of which is 235 / 45ZR17, and the structure is a carcass 6 that is rubber-coated with a 2-ply radial arrangement polyester cord, a steel ply cross layer, and a nylon cord cap ply according to FIG. A belt 7 with a layer. The contact width Wc of the tread portion 4 is 187 mm, and the width of the central region Rc is 55 mm.
00 53 ]
Comparison The tire of the example has a tread pattern corresponding to the footprint shown in FIG. 2 and has an area width A = 20 mm of the stepped portion 9.
Example 1 6 has a tread pattern corresponding to the footprint shown in FIG. 6, has an area width B = 20 mm, has an inclined narrow groove 10 shown in FIG. 11, has a groove width of 1.0 mm, and an inclination angle α. = 10 °
Example 2 6 has a tread pattern corresponding to the footprint shown in FIG. 6, has an area width B = 20 mm, has an inclined narrow groove 10 shown in FIG. 12, has a groove width of 1.0 mm, and an inclination angle α. = 10 °, the cross section of the chamfer Y is r = 2.0 mm,
Example 3 9 includes a tread pattern corresponding to the footprint shown in FIG. 9, and includes a central groove 13 and a narrow groove 10 shown in FIG. 10. The central groove 13 has a width of 11.6 mm, and the narrow grooves 10 on both sides thereof. The length = 10 mm × 2 and the groove width of the narrow groove 10 = 1.0 mm.
00 54 ]
In all the above footprints, the tire 1 is assembled to the standard rim 8JJ of the applicable rims defined by the JATMA standard (1998 version), and the maximum load capacity described in the JATMA standard (1998 version) is 650 kg (mass). Is the ground contact shape of the tread portion 4 when a load of 450 kgf corresponding to 70% of the maximum load capacity of 650 kg (mass) is loaded, and the ground contact width Wc was obtained from this.
00 55 ]
Examples and comparative examples The tires of the above are all provided with a tread pattern corresponding to the footprint shown in FIG. 17 and having no area width A (stepped portion 9) and area width B (thin groove 10). Tires of Examples and Comparative Examples To suit Conventional example Prepare tires, examples, Comparative example and conventional example Table 1 shows the presence / absence of the stepped-down portion 9 including the specifications, the presence / absence of the narrow groove 10 including the specifications, the presence / absence of the chamfered portion Y including the specifications, and the corresponding footprint drawing numbers.
00 56 ]
[Table 1]

00 57 ]
Examples 1-3, comparative examples and conventional examples These tires were used as test tires, and the following two tests were performed under the following test conditions using the rim and air pressure.
(1) Measurement of camber thrust Fc: Using a flat belt type indoor testing machine, the belt speed is 60 km / h, and each test tire is equivalent to 70% of the maximum load capacity of 650 kg at a camber angle of 5 °. Press with a load of 450 kgf to measure the camber thrust Fc did. The measurement results were represented by an index with a comparative example of 100. The smaller the value, the better.
(2) Straight running stability test with actual vehicle: 100km of dry asphalt test road surface with individual test tires mounted on all the wheels of a domestic passenger car 2500cc class FR car and two passengers on the front seat to form a saddle The degree of wandering phenomenon when driving at a speed of / h, that is, straight running stability, was evaluated to a maximum of 10 points by the test driver feeling. The higher the score, the better.
Table of test results for the above two items 1 under Shown in
00 58 ]
From the test results shown in Table 1, Examples 1 to 3 Tires Is Both Conventional Compared to the tires of the examples, the amount of Camber thrust Fc generated was significantly reduced, and it was found that the straight running stability in the dry saddle road running test with an actual vehicle was remarkably excellent. 3 If the tires are compared in detail, the inclination effect of the narrow groove 10 is greater and the effect of the chamfered portion Y of the dividing land portion 9a is further increased in reducing the camber thrust Fc and improving the straight running stability. It can be seen that the effect of providing the central groove 13 in B is the best.
00 59 ]
【The invention's effect】
this application Claims 1 to 1 3 According to the invention described in (1), the occurrence of wandering on the road surface in which concave portions having slopes with an upward slope are formed on both sides, as represented by a kite, is suppressed, and as a result, the vehicle travels straight at high speed. It is possible to provide a pneumatic radial tire which is excellent in stability, particularly called a high performance radial tire having a flatness ratio of 60% or less.
[Brief description of the drawings]
FIG. 1 This invention Examples of solutions to technical problems related to It is a left half sectional view of a tire.
2 is a view of the tread portion shown in FIG. , It is a grounding shape transfer diagram by footprint.
FIG. 3 2 Of the tread along the line III-III Expansion It is sectional drawing.
FIG. 4 shows in FIG. Enlargement showing a variation of the tread It is sectional drawing.
[Figure 5] Enlargement showing another variation of the tread It is sectional drawing.
6 is a tread portion different from the tread portion shown in FIGS. , It is a grounding shape transfer diagram by footprint.
FIG. 6 of Of the tread along the line VII-VII Expansion It is sectional drawing.
FIG. 8 shows in FIG. Enlargement showing a variation of the tread It is sectional drawing.
FIG. 9 Other It is a grounding shape transcription | transfer figure by the footprint of the tread part.
FIG. 10 of X − of the tread along the X-ray Expansion It is sectional drawing.
FIG. 11 An embodiment of a tire according to the present invention is shown, FIG. 10 is a partial cross-sectional view of a main part of a plane parallel to the tire equatorial plane of the tread portion having the ground contact shape shown in FIGS. 6 and 9.
12 is a modification of the main part shown in FIG. An example, It is a partial cross section figure of the principal part.
13 is an explanatory diagram of a ground contact state of the tread portion shown in FIG. 11 with a flat road surface.
14 is an explanatory diagram of a ground contact state of the tread portion shown in FIG. 12 with a flat road surface.
15 is an outermost border diagram of the footprint shown in FIG. 2 of an inclined road running tire. FIG.
FIG. 16 is an illustration of a tire traveling on an inclined road surface. 6 The figure 9 It is a footprint outermost border diagram shown in FIG.
FIG. 17 is a grounding shape transfer diagram by a footprint of a tread portion of a conventional tire.
FIG. 18 is a front view or a rear view of a tire traveling on an inclined road surface.
19 is a view of the tire shown in FIG. Partial enlargement It is sectional drawing.
20 is an edge view of a grounding portion of a footprint of a tread portion in which the tire shown in FIGS. 18 and 19 is pressed against a flat plate at a camber angle of 10 °. FIG.
21 is a border view of the grounding portion of the footprint of the tread portion obtained by pressing the tire shown in FIG. 20 perpendicularly to the flat plate.
[Explanation of symbols]
1 Pneumatic radial tire
2 Bead section
3 Side wall
4 Tread
4t tread
5 Bead core
6 Carcass
6-1, 6-2 Carcass ply
7 Belt
8 Tread rubber
8t tread rubber surface
9 Step down part
9a Landing section
10 narrow groove
10b Cut bottom of narrow groove
11, 13 Tread circumferential center groove
12 Tread circumferential groove
14, 16 Inclined groove
15 Inclined branch
E tire equator
Wc Grounding width
Rc central region
Rs shoulder region
D Tire rotation direction
δ Level of stepped part
Y chamfer
VL perpendicular
α Inclination angle with respect to perpendicular VL of narrow groove
I _S Ramp surface
S Flat plate surface
Fc Camber Thrust
Fy lateral force
Scr, Sb Shear force
Braking force on Fxb tires
Z Tire radial axis through the center of gravity of the figure
Mz Restoring moment

Claims (3)

A pair of bead portions and a pair of sidewall portions, a toroidal tread portion connected to both sidewall portions, and a radial carcass of one or more plies that reinforces each portion between bead cores embedded in the bead portions; and in the pneumatic radial tire obtain ingredients and a belt reinforcing the tread portion at the outer periphery of the radial carcass,
In the ground contact state of the tread portion in which the tire filled with air pressure corresponding to the maximum load capacity of the tire is pressed perpendicularly to the flat plate under a load load corresponding to 70% of the maximum load capacity,
The tread rubber of the tread portion is divided into three regions including a central region including the tire equatorial plane and 30% of the contact width (Wc) in the tire rotation axis direction, and a shoulder region on both sides thereof. some regions, ingredients example at least one of the plurality of narrow grooves and sipes extending in the rotation axis direction of the tire,
And Ri der value 0.05 or a ratio (B / Wc) with respect to the contact width (Wc) of the plurality of narrow grooves and sipes at least one of the ingredients obtaining area of the tire axial direction width (B),
The tread portion has a tread pattern designating the rotation direction, and under no load on the tire, at least one of the plurality of narrow grooves and sipes is a surface including a normal line of the tread rubber surface passing through the cut edge. 3 ° is inclined at an angle greater than, the pneumatic radial tire ing as the same direction as the rotation direction of the tire toward the tread rubber surface and the inclination from the respective notch bottom against. In cross-section by the plurality of narrow grooves and a plane perpendicular to at least one of the sipe, claim 1, obtuse side edge along converting said interruption of the tread rubber land portions, at least one of disrupt the fine grooves and sipes has a chamfered portion Pneumatic radial tire described in 2. Ingredients to give a tread circumferential groove in the central region of the tread rubber, as set forth in claim 1 or 2 having at least one of fine grooves and sipes of the plurality of connecting openings into the groove at at least one side along the groove Pneumatic radial tire.

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